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OPTIMIZED SYNTHESIS ROUTES AND BIOLOGICAL APPLICATION
OF N-PEPTIDE-6-AMINO-D-LUCIFERIN CONJUGATES
PhD Thesis
Anita Kármen Kovács
Supervisors
Prof. Dr. Gábor Tóth
Department of Medical Chemistry
Dr. László G. Puskás
Avidin Ltd
Department of Medical Chemistry
University of Szeged
2019
TABLE OF CONTENTS
ABBREVIATIONS AND SYMBOLS i
PUBLICATIONS iv
1. INTRODUCTION AND AIMS 1
2. LITERATURE BACKGROUND 3
2.1 6-amino-2-cyanobenzothiazole synthesis 4
2.1.1 6-amino-2-cyanobenzothiazole synthesis with
6-amino-2-chlorobenzothiazole as immediate precursor 5
2.1.2 6-amino-2-cyanobenzothiazole synthesis with
2-cyano-6-nitrobenzothiazole as immediate precursor 8
2.2 N-peptide-aLuc conjugate synthesis 16
2.2.1 N-peptide-aLuc conjugate synthesis methods with carboxyl protected
aLuc as starting material 16
2.2.1.1 Phospho-azo method with carboxyl protected aLuc as
starting material 16
2.2.1.2 Mixed anhydride method with carboxyl protected aLuc as
starting material 17
2.2.2 N-peptide-aLuc conjugate synthesis methods with
6-amino-2-cyanobenzothiazole as starting material 18
2.2.2.1 Phospho-azo method with 6-amino-2-cyanobenzothiazole
as starting material 18
2.2.2.2 Mixed anhydride methods with 6-amino-2-cyanobenzothiazole
as starting material 19
2.2.2.3 DCC coupling method with protected amino acid
6-amino-2-cyanobenzothiazole as starting material 22
3. RESULTS AND DISCUSSION 23
3.1 6-amino-2-cyanobenzothiazole synthesis 23
3.1.1 2-chloro-6-nitrobenzothiazole synthesis 23
3.1.2 6-amino-2-chlorobenzothiazole synthesis 24
3.1.3 6-amino-2-cyanobenzothiazole synthesis 25
3.2 N-peptide-aLuc conjugate synthesis routes and biological applications 26
3.2.1 N-peptide aLuc conjugate synthesis with liquid/solid phase Fmoc strategy 26
3.2.1.1 N-Fmoc-Asp(OtBu)-6-amino-2-cyanobenzothiazole synthesis 26
3.2.1.2 N-Fmoc-Asp(OtBu)-aLuc synthesis 28
3.2.1.3 Attachment of N-Fmoc-Asp(OtBu)-aLuc to solid support 29
3.2.1.4 Building the peptide chain 29
3.2.1.5 Cleavage of the peptide from the resin 29
3.2.1.6 Limitations of the liquid/solid phase method 30
3.2.2 N-peptide aLuc conjugate synthesis with fragment condensation strategy 32
3.2.2.1 N-Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole synthesis 33
3.2.2.2 N-Fmoc-Gly-Pro-aLuc synthesis 33
3.2.2.3 Limitations of the fragment condensation method 34
3.2.3 Building block production for the Boc-strategy solid phase synthesis of
N-peptide-aLuc conjugates 34
3.2.3.1 Unsuccessful attempts 34
3.2.3.1.1 Unsuccessful Boc-anhydride attempt to produce N-Boc-aLuc 34
3.2.3.1.2 Unsuccessful Boc-anhydride attempt to produce
N-Boc-6-amino-2-cyanobenzothiazole 35
3.2.3.1.3 Unsuccessful triphosgene attempt to produce
N-Boc-6-amino-2-cyanobenzothiazole 36
3.2.3.2 Successful synthesis route 37
3.2.3.2.1 N-Boc-6-amino-2-cyanobenzothiazole synthesis 37
3.2.3.2.2 N-Boc-aLuc synthesis 38
3.2.4 Biological testing 39
3.2.4.1 Biological testing of Z-Asp-Glu-Val-Asp-aLuc 39
3.2.4.1.1 Biochemical and cellular testing 39
3.2.4.1.2 In vivo testing 40
3.2.4.2 Biological testing of N-Fmoc-Gly-Pro-aLuc 41
4. SUMMARY 43
5. REFERENCES 46
6. ACKNOWLEDGEMENTS 52
APPENDIX
I. TABLES 53
I.1 Literary overview of 6-amino-2-cyanobenzothiazole synthesis routes 53
I.2. Methods for the synthesis of 6-amino-2-cyanobenzothiazole 54
I.3 Comparison of starting materials 58
I.4 Comparison of solvents during chlorine-cyanide exchange 59
I.5 Comparison of the optimal and the non-optimal order of reduction
and cyanidation 60
II. FIGURES 61
II.1. 1H-NMR spectrum of 2-chloro-6-nitrobenzothiazole 61
II.2. TSQ mass spectrum of 2-chloro-6-nitrobenzothiazole 62
II.3. RP-HPLC profile of the crude 2-chloro-6-nitrobenzothiazole 63
II.4 1H-NMR spectrum of 6-amino-2-chlorobenzothiazole 64
II.5 13C-NMR spectrum of 6-amino-2-chlorobenzothiazole 65
II.6 ESI mass spectrum of 6-amino-2-chlorobenzothiazole 66
II.7 RP-HPLC profile of 6-amino-2-chlorobenzothiazole 67
II.8 1H-NMR of 6-amino-2-cyanobenzothiazole 68
II.9 13C-NMR spectrum of 6-amino-2-cyanobenzothiazole 69
II.10 ESI mass spectrum of 6-amino-2-cyanobenzothiazole 70
II.11 RP-HPLC profile of 6-amino-2-cyanobenzothiazole 71
II.12 TOF mass spectrum of N-Fmoc-Asp(OtBu)-6-amio-2-cyanobenzothiazole 72
II.13 RP-HPLC of the purified N-Fmoc-Asp(OtBu)-6-amino-2-cyanobenzothiazole 73
II.14 TOF mass spectrum of N-Fmoc-Asp(OtBu)-aLuc 74
II.15 RP-HPLC profile of the N-Fmoc-Asp(OtBu)-aLuc 75
II.16. 1H-NMR spectrum of the N-Z-Asp-Glu-Val-Asp-aLuc 76
II.17 13C-NMR spectrum of the N-Z-Asp-Glu-Val-Asp-aLuc 79
II.18 ESI mass spectrum of the N-Z-Asp-Glu-Val-Asp-aLuc 81
II.19 RP-HPLC profile of the purified N-Z-Asp-Glu-Val-Asp-aLuc 82
II.20 RP-HPLC profile of the resulting material at the determination of load 83
II.21 ESI mass spectrum of N-Fmoc-Pro-6-aminodehydroluciferin 84
II.22 RP-HPLC profile of the N-Z-Gly-Pro-aminodehydroluciferin 85
II.23 ESI mass spectrum of the N-Z-Gly-Pro-6-aminodehydroluciferin 86
II.24 1H-NMR spectrum of N-Z-Gly-Pro-6-aminodehydroluciferin 87
II.25 ESI mass spectrum of the N-Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole 88
II.26 RP-HPLC profile of the N-Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole 89
II.27 1H-NMR of the N-Fmoc-Gly-Pro-aLuc 90
II.28 13C-NMR of the N-Fmoc-Gly-Pro-aLuc 91
II.29 ESI mass spectrum of the N-Fmoc-Gly-Pro-aLuc 92
II.30 RP-HPLC profile of the N-Fmoc-Gly-Pro-aLuc 93
II.31 ESI mass spectrum of the N-Boc-6-amino-2-cyanobenzothiazole 94
II.32 RP-HPLC profile of the N-Boc-6-amino-2-cyanobenzothiazole 95
II.33 1H-NMR spectrum of the N-Boc-aLuc 96
II.34 13C-NMR spectrum of the N-Boc-aLuc 97
II.35 ESI mass spectrum of the N-Boc-aLuc 98
II.36 Chiral HPLC profile of enantiomeric mixture of the N-Boc-6-amino-luciferin 99
II.37 Chiral HPLC profile of the untreated N-Boc-aLuc 100
II.38 The standard error of the mean (SEM) values of Figure 7A 101
II.39 Ac-915 induces the activation of caspase-3 in U87 cells (A) 102
III. MATERIALS AND METHODS 103
III.1 Materials 103
III.2 Chemical Methods 103
III.2.1 2-chloro-6-nitrobenzothiazole synthesis 103
III.2.2 6-amino-2-chlorobenzothiazole synthesis 104
III.2.3 6-amino-2-cyanobenzothiazole synthesis 104
III.2.4 N-Fmoc-Asp(OtBu)-6-amino-2-cyanobenzothiazole synthesis 105
III.2.5 N-Fmoc-Asp(OtBu)-aLuc synthesis 106
III.2.6 Attachment of N-Fmoc-Asp(OtBu)-aLuc to solid support 106
III.2.7 N-Z-Asp-Glu-Val-Asp-aLuc synthesis 107
III.2.7.1 Fmoc deprotection 107
III.2.7.2 SPPS peptide coupling 107
III.2.7.3 Cleavage of peptide from the resin 108
III.2.7.4 Purification of crude peptide 108
III.2.8 N-Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole synthesis 108
III.2.9 N-Fmoc-Gly-Pro-aLuc synthesis 109
III.2.10 Purification of crude N-Fmoc-Gly-Pro-aLuc 110
III.2.11 N-Boc-6-amino-2-cyanobenzothiazole synthesis 110
III.2.12 N-Boc-aLuc synthesis 111
III.2.13 Purification of N-Boc-aLuc 111
III.3. Analytical methods 112
IV. BIOLOGICAL INVESTIGATION 114
IV.1 N-Z-Asp-Glu-Val-Asp-aLuc biochemical assay 114
IV.2 N-Z-Asp-Glu-Val-Asp-aLuc cellular assay 114
IV.3 N-Fmoc-Gly-Pro-aLuc assay 115
IV.4 N-Z-Asp-Glu-Val-Asp-aLuc in vivo assay 115
IV.5 Statistics 116
V. RELATED ARTICLES
ABBREVIATIONS AND SYMBOLS
AcN acetonitrile
AcOH acetic acid
Ala alanine
aLuc 6-amino-D-luciferin
anh anhydrous
aq aquous
Asp aspartic acid
APCI atmospheric pressure chemical ionization
API atmospheric pressure ionization
Boc tert-butyloxycarbonyl
(Boc)2O di-tert-butyl dicarbonate
BSA bovine serum albumin
cc concentrated
CHAPS 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate
COMU 1-cyano-2-ethoxy-2-oxoethylidenaminooxy)dimethylamino-
morpholino-carbenium hexafluorophosphate
cps counts per seconds
DABCO 1,4-diazabicyclo[2.2.2]octane
DCC dicyclohexylcarbodiimide
DCM dichloromethane
Deoxo-Fluor Reagent bis(2-methoxyethyl)aminosulfur trifluoride
DIPEA N,N-diisopropylethylamine
i
DMAA N,N-dimethylacetamide
DMAP 4-dimethylaminopyridine
DMEM Dulbecco's modified eagle medium
DMEM-F12 Dulbecco's modified eagle medium nutrient mixture F-12
DMF N,N-dimethylformamide
DMSO dimethyl sulfoxide
DTT 1,4-dithiothreitol
EDTA disodium ethylenediaminetetraacetate dehydrate
equiv equivalent
EtOAc ethyl acetate
EtOH ethanol
FACS fluorescence activated cell sorter
FAP fibroblast activation protein alpha
FCS fetal calf serum
fmk fluoromethylketone
Fmoc 9-fluorenylmethoxycarbonyl
Glu glutamic acid
Gly glycine
HATU 1-[bis(dimethylamino)methylene]-1H-1,2,3-triazolo[4,5-
b]pyridinium 3-oxid hexafluorophosphate
HEPES 4-(2-hydroxyethyl)piperazine-1-ethanesulfonic acid
HMPA hexamethylphosphoric acid triamide
HOBt 1-hydroxybenzotriazole
IBCF chloroformic acid isobutylester
ii
i.p. intraperitoneally
Me2O acetone
MeOH methanol
mp melting point
PBS phosphate-buffered saline
POP/PREP prolyl oligopeptidase
Pro proline
RP-HPLC reversed-phase high-performance liquid chromatography
SEM standard error of the mean
sicc siccum
SPPS solid phase peptide synthesis
tBu tert butyl
TCFH chloro-N,N,N′,N′-tetramethylformamidinium hexafluorophosphate
TEA triethylamine
TFA trifluoroacetic acid
TFFH fluoro-N,N,N′,N′-tetramethylformamidinium hexafluorophosphate
THF tetrahydrofuran
TLC thin layer chromatography
Tris tris(hydroxymethyl)aminomethane
Val valine
Z benzyloxycarbonyl
iii
PUBLICATIONS
Papers related to the thesis
[1] Anita K. Kovács, Péter Hegyes, Gábor J. Szebeni, Lajos I. Nagy, László G. Puskás, Gábor K.
Tóth:
Synthesis of N-peptide-6-amino-D-luciferin conjugates
Front. Chem. 2018, 6 (120), 1-11., doi: 10.3389/fchem.2018.00120 IF: 4.155
[2] Anita K. Kovács, Péter Hegyes, Gábor J. Szebeni, Krisztián Bogár, László G. Puskás, Gábor
K. Tóth:
Synthesis of N-peptide-6-amino-D-luciferin conjugates with optimized fragment condensation
strategy
Int J Pept Res Ther 2018, (ahead of print), doi: 10.1007/s10989-018-9768-8 IF: 1.132
Other publications
[3] Anikó Angyal, András Demjén, Edit Wéber, Anita K. Kovács, János Wölfling, László G.
Puskás, Iván Kanizsai
Lewis acid-catalyzed diastereoselective synthesis of multisubstituted N-acylaziridine-2-
carboxamides from 2H-azirines via Joullié-Ugi three-component reaction
J. Org. Chem. 2018, 83 (7), 3570–3581., doi: 10.1021/acs.joc.7b03189 IF: 4.805
[4] Gyula Telegdy, Anita K. Kovács, Kinga Rákosi, Márta Zarándi, Gábor K. Tóth
Antiamnesic properties of analogs and mimetics of the tripeptide human urocortin 3
Amino Acids 2016,48 (9), 2261-2266., doi: 10.1007/s00726-016-2268-2 IF: 3.173
iv
Selected scientific lectures
Anita K. Kovács, Péter Hegyes, Gábor Szebeni, László G. Puskás, Gábor K. Tóth
Synthesis of peptide-6-amino-D-luciferin conjugates
18th International Symposium on Bioluminescence and Chemiluminescence
Uppsala, Sweden, June 23-28, 2014, oral presentation
Anita K. Kovács, Péter Hegyes, Gábor J. Szebeni, László G. Puskás, Gábor K. Tóth
Boc strategy for the synthesis of peptide-6-amino-D-luciferin conjugates
19th International Symposium on Bioluminescence and Chemiluminescence
Tsukuba, Japan, 29 May – 02 June, 2016, oral presentation
Anita K. Kovács, Péter Hegyes, Gábor J. Szebeni, László G. Puskás, Gábor K. Tóth
Synthesis methods of peptide-6-amino-D-luciferin conjugates for protease activity detection
8th Conference Chemistry towards Biology
Brno, Czech Republic, August 28 – September 01, 2016, oral presentation
Anita K. Kovács, Péter Hegyes, Gábor J. Szebeni, László G. Puskás, Gábor K. Tóth
Comparison of Fmoc-, Boc- and fragment condensation strategies in the synthesis of peptide-6-
amino-D-luciferin conjugates
34th European Peptide Symposium
Leipzig, Germany, September 04-09, 2016, poster presentation
Anita K. Kovács, Péter Hegyes, Gábor J. Szebeni, László G. Puskás, Gábor K. Tóth
Comparison of Fmoc-, Boc- and fragment condensation strategies in the synthesis of peptide-6-
amino-D-luciferin conjugates
12th Australian Peptide Conference
Noosa Heads, Victoria, Australia, October 15-20, 2016, poster presentation
v
- 1 -
1. Introduction and aims
1. INTRODUCTION AND AIMS
In the recent years, numerous in vivo and in vitro analytical methods, based on fluorescence and
bioluminescence, have been developed for various biological objectives, including
immunoassays, gene expression assays, bioimaging, investigation of infectious diseases etc.1-7
Plate based, high-throughput viability assays addressing the detection of protease activity is in the
focus of intensive research.8 The advantage of bioluminescent systems over fluorescent ones lies
in their superior sensitivity and easy handling.9-12
In the bioluminescent methods, diverse sets of luciferases and their substrates, luciferins have
been applied in different cellular and animal models.4-5 The most ubiquitous enzyme-substrate
system in bioimaging is the American firefly (Photinus pyralis) luciferin-luciferase system.13-14
Substituting the 6-position hydroxyl group of native luciferin with an amino group, the resulting
6-amino-D-luciferin (2-(6-aminobenzo[d]thiazol-2-yl)-4,5-dihydrothiazole-4-carboxylic acid,
hereinafter: aLuc, Figure 1) can form an amide bond with a peptide, while retaining the transport
and bioluminescent properties of the original substrate, resulting in a good substrate for different
important proteases, which can be used for the determination of the enzymatic activity.15
Figure 1 6-amino-D-luciferin
These substrates can be used for measuring protease enzyme activity in the following way: the
protease enzyme to be measured recognizes the peptide part of the conjugate with the suitable
peptide sequence, then cleaves the amide bond between the peptide and the aLuc, thus aLuc is
released, which, in the presence of luciferase enzyme, emits light (Figure 2).
- 2 -
1. Introduction and aims
Figure 2 The operation of the bioluminescent system
The activity of the given protease enzyme can be determined from the amount of emitted light, as
the emitted light is directly proportional to the activity of the enzyme.16
The N-linked peptide-aLuc conjugates discussed in the dissertation can be substrates for
proteases such as metalloproteases, chymotrypsin-like, trypsin-like and caspase-like proteases.17
Caspases are potential drug targets due to their role as key mediators of apoptotic cell death.
Among them, caspase-3 is a frequently activated death protease, catalyzing the specific cleavage
of many key cellular proteins, it is widely used as a sensitive monitor of apoptosis induction for
general cytotoxicity screening. Fibroblast activation protein and prolyl oligopeptidase are
enzymes that are proposed therapeutic targets for major human diseases, including
neurodegenerative diseases and psychiatric disorders, inflammation and cancer.
Unfortunately, the synthesis methods of these conjugates published so far are complicated; and
the very few commercially available conjugates are very expensive. The aim of this dissertation
is to introduce novel routes for the scalable and economical synthesis of N-peptide-aLuc
conjugates.
The preparative work focuses on preparing a precursor (6-amino-2-cyanobenzothiazole, 3), two
conjugates (Z-Asp-Glu-Val-Asp-aLuc, 6, Fmoc-Gly-Pro-aLuc, 8) and an intermediate (Boc-
aLuc, 10).
The publications on which this thesis is based are given in square brackets, while other literature
references are given as superscripts.
- 3 -
2. Literature background
2. LITERATURE BACKGROUND
Despite their growing significance, in the past decades only a handful of publications have dealt
with the synthesis of peptide-aLuc conjugates and their precursors.9, 15, 20-24, 29-31
The logical method for the synthesis of these conjugates would start with the synthesis of aLuc.
This target compound has an aminobenzothiazole skeleton (Figure 3).
Figure 3 6-amino-D-luciferin
To produce an aLuc, D-cysteine needs to be added to this aminobenzothiazole skeleton, for which
step there are two possible substituents at position 2: a COOH group or a CN group. This means
that the two possible immediate precursors are 6-amino-2-benzothiazole carboxylic acid (6-
aminobenzo[d]thiazole-2-carboxylic acid) and 6-amino-2-cyanobenzothiazole (6-
aminobenzo[d]thiazole-2-carbonitrile), (Figure 4).
Figure 4 Possible immediate precursors of aLuc
What makes 6-amino-2-benzothiazole carboxylic acid less appealing as precursor is the fact that
its use requires a very complicated and expensive method: the amino group has to be protected,
then thiol- and carboxyl-protected D-cysteine has to be added, which step is followed by the
removal of the D-cysteine-protecting groups and the ring formation.18,19
- 4 -
2. Literature background
Hence, most of the corresponding literature uses 6-amino-2-cyanobenzothiazole as immediate
precursor for the synthesis of aLuc. However, most of these publications are patents, and
unfortunately, they sometimes lack significant scientific data (e.g. concerning yields, protecting
groups).
2.1 6-amino-2-cyanobenzothiazole synthesis
So far very few methods have been published for the synthesis of the key molecule, 6-amino-2-
cyanobenzothiazole.15, 20-24 The key steps of all these methods are the nitration, the cyanidation and
the reduction; the methods differ in the starting material, the reagents, the solvents or the order of
transformations. However, taking a closer look at the different methods reveals that basically two
routes can be distinguished: one that uses 6-amino-2-chlorobenzothiazole as immediate precursor,
and one that uses 2-cyano-6-nitrobenzothiazole for that purpose (Figure 5, I.1).
Figure 5 Precursors of 6-amino-2-cyanobenzothiazole
- 5 -
2. Literature background
2.1.1 6-amino-2-cyanobenzothiazole synthesis with 6-amino-2-chlorobenzothiazole as
immediate precursor
One of the possible immediate precursors of 6-amino-2-cyanobenzothiazole, 6-amino-2-
chlorobenzothiazole (2-chlorobenzo[d]thiazol-6-amine), was first synthetized by Drozdov and
Stavrovskaya.25 They reproduced Hofmann’s synthesis route 26 to produce 2-chloro-6-
nitrobenzothiazole (2-chloro-6-nitrobenzo[d]thiazole): 2-chloro-benzothiazole (2-
chlorobenzo[d]thiazole) was dissolved in cc H2SO4, the mixture was cooled down, then HNO3 was
added 27 (Scheme 1).
Scheme 1 Synthesis of 2-chloro-6-nitrobenzothiazole (Hofmann)
The resulting 2-chloro-6-nitrobenzothiazole was dissolved in EtOH upon heating, and acetic acid
and iron filings were added to the solution. Then, in the course of the reaction, 50 mL of water was
added. The reaction mixture was heated with stirring in a boiling-water bath for 1 hour. At the end
of the reduction, to prevent premature crystallization, EtOH was added, and the liquid was filtered.
After the addition of water to the filtrate, 6-amino-2-chlorobenzothiazole was obtained (Scheme
2).
Scheme 2 Synthesis of 6-amino-2-chlorobenzothiazole (Drozdov and Stavrovskaya)
- 6 -
2. Literature background
Later Katz 28 applied certain modifications. The starting material, 2-chlorobenzothiazole, was first
nitrated with a mixture of KNO3 and cc H2SO4, keeping the temperature at 10-17 ºC (yield 80%).
The next step was the reduction of the nitro group. The material was added to the mixture of 95%
EtOH/AcOH/H2O/Fe powder, it was stirred at 80-85 ºC for 2 hours 45 minutes, thus preparing 6-
amino-2-chlorobenzothiazole (Scheme 3).
Scheme 3 Synthesis of6-amino-2-chlorobenzothiazole (Katz)
White et al 15 went on with the cyanidation of the substance: KCN was added to DMSO at 130-140
ºC, under continuous stirring overnight. Having cooled this mixture to 120 ºC, the 6-amino-2-
chlorobenzothiazole was added portionwise in an hour, then the mixture was stirred for 4.5 hours
at 120 ºC, thus producing the desired 6-amino-2-cyanobenzothiazole (Scheme 4).
Scheme 4 Synthesis of 6-amino-2-cyanobenzothiazole (White)
- 7 -
2. Literature background
Takakura et al 20 used the same method for the nitration step as Katz, although with lower yield
(49%), then modified Katz’s reduction step: he used the same solvents but changed the reagents.
2-chloro-6-nitrobenzothiazole was dissolved in EtOH, water and HCl, then SnCl2·2H2O was added,
and the solution was refluxed at 120 ºC. When TLC showed complete consumption of the starting
material, the mixture was basified with aqueous NaOH solution. At this step Takakura’s yield was
significantly lower than Katz’s (61%). The final cyanidation step was the same as White’s,
although with a slightly lower yield (49%). (Scheme 5)
Scheme 5 Synthesis of 6-amino-2-cyanobenzothiazole (Takakura)
- 8 -
2. Literature background
Hsu et al 21 used the Katz method, however, with longer reaction time and an extra reagent (FeCl3)
during the reduction, thus achieving a higher yield (88%) at this phase. The cyanidation step was
the replication of White’s method (Scheme 6)
Scheme 6 Synthesis of 6-amino-2-cyanobenzothiazole (Hsu)
2.1.2 6-amino-2-cyanobenzothiazole synthesis with 2-cyano-6-nitrobenzothiazole as immediate
precursor
The other possible immediate precursor of the target material is 2-cyano-6-nitrobenzothiazole (6-
nitrobenzo[d]thiazole-2-carbonitrile). Using this material, the last step in the synthesis of 6-amino-
2-cyanobenzothiazole is the reduction of the nitro group.
- 9 -
2. Literature background
Gryshuk et al. 22 worked out four different synthesis routes.
During their first attempt, 6-nitrobenzothiazole (6-nitrobenzo[d]thiazole) was used as starting
material. It was suspended in water, then cc H2SO4 was added dropwise. In a different flask H2O2
was added to a solution of ethylpyruvate. The resultant oxyhydroperoxide solution and a solution
of FeSO4 was mixed and then added to the 6-nitrobenzothiazole mixture at 0 ºC. The mixture was
stirred for 30 minutes, then basified with NaHCO3. The resulting ethyl 6-nitrobenzothiazole-2-
carboxylate (ethyl 6-nitrobenzo[d]thiazole-2-carboxylate) was amidated: it was dissolved in
MeOH, then purged with NH3. During cyanidation, the 6-nitrobenzothiazole-2-carboxamide (6-
nitrobenzo[d]thiazole-2-carboxamide) was dissolved in anh pyridine at room temperature. It was
cooled down to 0 ºC and POCl3 was added dropwise. The mixture was stirred at room temperature
for 2 hours. The resultant 2-cyano-6-nitrobenzothiazole was finally reduced. Having dissolved it
in EtOH, SnCl2 was added and the mixture was stirred at 60 ºC for two hours. It was cooled down
to room temperature and the pH of the mixture was adjusted to 7, using NaHCO3 (Scheme 7).
Scheme 7 Synthesis of 6-amino-2-cyanobenzothiazole (Gryshuk 1)
- 10 -
2. Literature background
During their second attempt, ethyl benzothiazole-2-carboxylate (ethyl benzo[d]thiazole-2-
carboxylate) was used as starting material. First it was nitrated: it was suspended in cc H2SO4 at 0
ºC. KNO3 was added portionwise at 10 ºC in 30 minutes. After another 30 minutes stirring the
mixture was poured over ice/water and filtered. The resulting ethyl-6-nitrobenzothiazole-2-
carboxylate was amidated with the strategy described above: it was dissolved in MeOH, then
purged with NH3. The following steps also agreed with those of the previous method: cyanidation
- solution in anh pyridine at room temperature, cooling down to 0 ºC and POCl3 addition; reduction
- solution in EtOH, SnCl2 addition and pH adjustment with NaHCO3 (Scheme 8).
Scheme 8 Synthesis of 6-amino-2-cyanobenzothiazole (Gryshuk 2)
- 11 -
2. Literature background
At the third attempt, ethyl benzothiazole-2-carboxylate was used as starting material again and the
transformations were the same but in a different order: in this case the first step was amidation
(solution in MeOH and purgation with NH3), which was followed by nitration (suspension in cc
H2SO4 and addition of KNO3), cyanidation (solution in anh pyridine at room temperature, cooling
down to 0 ºC and POCl3 addition) and reduction (solution in EtOH, SnCl2 addition and pH
adjustment with NaHCO3) (Scheme 9).
Scheme 9 Synthesis of 6-amino-2-cyanobenzothiazole (Gryshuk 3)
- 12 -
2. Literature background
At the fourth attempt, the previous starting material, ethyl benzothiazole-2-carboxylate was used,
with another different order of transformations: amidation (solution in MeOH and purgation with
NH3), cyanidation (solution in anh pyridine at room temperature, cooling down to 0 ºC and POCl3
addition), nitration (suspension in cc H2SO4 and addition of KNO3) and reduction (solution in
EtOH, SnCl2 addition and pH adjustment with NaHCO3) (Scheme 10).
Scheme 10 Synthesis of 6-amino-2-cyanobenzothiazole (Gryshuk 4)
- 13 -
2. Literature background
McCutcheon et al. 23 developed two synthesis routes. The disadvantage of these methods is that
exotic and expensive starting materials and reagents are needed. In the first route, 4-nitroaniline
was treated with 4,5-dichloro-1,2,3-dithiazol-1-ium chloride in a mixture of AcN and THF (2:1).
Pyridine was added dropwise, then Na2S2O3, dissolved in water, was added. The mixture was
stirred for 3 hours at room temperature. The resulting (4-nitrophenyl)-carbonocyanidothioic amide
was suspended in anh DMF/DMSO (1:1) in the presence of CuI, TBAB, PdCl2, and stirred for 3
hours at 130 ºC. During the next step, reduction, the 2-cyano-6-nitrobenzothiazole was dissolved
in EtOH and NH4Cl was added. After 5 minutes stirring at room temperature, Zn powder was
added, and the reaction mixture was vigorously stirred for 30 minutes, obtaining the target material,
6-amino-2-cyanobenzothiazole (Scheme 11).
Scheme 11 Synthesis of 6-amino-2-cyanobenzothiazole (McCutcheon 1)
- 14 -
2. Literature background
During the second route, McCutcheon et al.23 used 6-nitrobenzothiazole as starting material,
similarly to Gryshuk et al in their first attempt.23 However, instead of the acylation of the 6-
nitrobenzothiazole, the thiazole ring was decomposed by suspending in N2H4·H2O and EtOH. The
mixture was stirred for 12 hours at room temperature, then cooled down. The resulting 2-amino-5-
nitrobenzenethiol was suspended in anh DCM. 4,5-dichloro-1,2,3-dithiazol-1-ium chloride added
to the suspension. The solution was refluxed in 12 hours. During the final step, reduction, the earlier
method was applied: the 2-cyano-6-nitrobenzothiazole was dissolved in MeOH and NH4Cl was
added. After 5 minutes stirring at room temperature, Zn powder was added, and the reaction
mixture was vigorously stirred for 30 minutes, obtaining the target material, 6-amino-2-
cyanobenzothiazole (Scheme 12).
Scheme 12 Scheme 11 Synthesis of 6-amino-2-cyanobenzothiazole (McCutcheon 2)
- 15 -
2. Literature background
During their first step, nitration, Hauser et al.24 used the Katz method 28 with significantly longer
reaction time, 18 hours. Instead of the reduction, however, their next step was the cyanidation of
2-chloro-6-nitrobenzothiazole. Aqueous solution of NaCN, then DABCO catalyst was added to 2-
chloro-6-nitrobenzothiazole dissolved in AcN; the mixture was stirred at room temperature for 24
hours. Aqueous FeCl3 solution was added in order to quench the excess cyanide. The nitro-group
of the resulting 2-cyano-6-nitrobenzothiazole was finally reduced with iron powder and acetic acid
at room temperature in 24 hours (Scheme 13).
Scheme 13 Scheme 11 Synthesis of 6-amino-2-cyanobenzothiazole (Hauser)
- 16 -
2. Literature background
2.2 N-peptide-aLuc conjugate synthesis
The synthesis routes were first published by Geiger and Miska 29, who developed four methods
(phospho-azo and mixed anhydride methods, both with both 6-amino-2-cyanobenzothiazole and
carboxyl protected aLuc as starting material) and produced 13 different conjugates (Unfortunately,
from the patent it is not clear which molecule was synthesized which way). Having examined these
and the methods published later, two main pathways can be observed, based on the starting
materials.
2.2.1 N-peptide-aLuc conjugate synthesis methods with carboxyl protected aLuc as starting
material
2.2.1.1 Phospho-azo method with carboxyl protected aLuc as starting material
A carboxyl-protected aLuc (protecting group not specified) was dissolved in anh pyridine at -10
ºC. PCl3, then protected amino acid or peptide was added to the solution. After 20-hour stirring,
the protecting groups of both the peptide moiety and the carboxyl group were removed, thus
obtaining the desired peptide-aLuc conjugate 29 (yield not given, Scheme 14).
Scheme 14 Phospho-azo method with carboxyl protected aLuc as starting material to produce
N-peptide-aLuc conjugates (Geiger and Miska)
- 17 -
2. Literature background
2.2.1.2 Mixed anhydride method with carboxyl protected aLuc as starting material
A protected peptide was dissolved in anh THF at -15 ºC. The addition of TEA and IBCF was
followed by the addition of the carboxyl-protected aLuc (protecting group not specified). After
overnight stirring, the protecting groups were removed, thus obtaining the desired peptide-aLuc
conjugate 29 (yield not given, Scheme 15).
Scheme 15 Mixed anhydride method with carboxyl protected aLuc as starting material to
produce N-peptide-aLuc conjugates (Geiger and Miska)
- 18 -
2. Literature background
2.2.2 N-peptide-aLuc conjugate synthesis methods with 6-amino-2-cyanobenzothiazole as
starting material
2.2.2.1 Phospho-azo method with 6-amino-2-cyanobenzothiazole as starting material
6-amino-2-cyanobenzothiazole was dissolved in anh pyridine at -10 ºC. PCl3, then protected
peptide was added to the solution. After 20-hour stirring, D-cysteine was added at pH 7.5, the
protecting groups were removed, thus obtaining the desired peptide-aLuc conjugate 29 (yield not
given, Scheme 16).
Scheme 16 Phospho-azo method with 6-amino-2-cyanobenzothiazole as starting material to
produce N-peptide-aLuc conjugates (Geiger and Miska)
- 19 -
2. Literature background
2.2.2.2 Mixed anhydride methods with 6-amino-2-cyanobenzothiazole as starting material
A protected peptide was dissolved in anh THF at -15 ºC. The addition of TEA and IBCF was
followed by the addition of 6-amino-2-cyanobenzothiazole. After overnight stirring, D-cysteine
was added at pH 7.5, the protecting groups were removed, thus obtaining the desired peptide-aLuc
conjugate 29 (yield not given, Scheme 17).
Scheme 17 Mixed anhydride method with 6-amino-2-cyanobenzothiazole as starting material to
produce N-peptide-aLuc conjugates (Geiger and Miska)
- 20 -
2. Literature background
The method was modified in a 2003 Promega patent.30 A protected peptide was dissolved in anh
THF at -10 ºC. N-methylmorpholine and IBCF were added, which was followed by the addition of
6-amino-2-cyanobenzothiazole. After 2 days stirring, D-cysteine was added at pH lower than 7.
After overnight stirring, the protecting groups were removed (yield not given, Scheme 18).
Scheme 18 Mixed anhydride method with 6-amino-2-cyanobenzothiazole as starting material to
produce N-peptide-aLuc conjugates (2003 Promega patent)
- 21 -
2. Literature background
In a modified route by Gryshuk et al. in 2011 31, a protected amino acid was dissolved in anh THF
at 0 ºC. The addition of N-methylmorpholine and IBCF was followed by the addition of 6-amino-
2-cyanobenzothiazole. After overnight stirring, the protecting group was removed, and D-cysteine
was added at pH 8. Then a protected peptide was dissolved in anh THF. The addition of N-
methylmorpholine and IBCF was followed by the addition of the amino acid-6-amino-2-
cyanobenzothiazole conjugate. After 72 hours stirring, the protecting group was removed (yield
not given, Scheme 19).
Scheme 19 Mixed anhydride method with 6-amino-2-cyanobenzothiazole as starting material to
produce N-peptide-aLuc conjugates (2011 Gryshuk patent)
- 22 -
2. Literature background
2.2.2.3 DCC coupling method with protected amino acid 6-amino-2-cyanobenzothiazole as
starting material
In a different route 9, a protected amino acid-6-amino-2-cyanobenzothiazole conjugate (6-
Asp(OtBu)amino-2-cyanobenzothiazole) and a protected peptide (Z-Asp(OtBu)-Glu(OtBu)-Val-
COOH) was joined using DCC and HOBt. The resulting conjugate (Z-Asp(OtBu)-Glu(OtBu)-Val-
Asp(OtBu)amino-2-cyanobenzothiazole) was reacted with D-cysteine and the protecting groups
were removed, thus obtaining the desired peptide-aLuc conjugate (Z-Asp-Glu-Val-Asp-aLuc).
Although in the article it is not defined explicitly, it seems feasible that the synthesis route started
with 6-amino-2-cyanobenzothiazole (yield not given, Scheme 20).
Scheme 20 DCC coupling method with protected amino acid 6-amino-2-cyanobenzothiazole as
starting material (O’Brien)
- 23 -
3.Results and discussion
3. RESULTS AND DISCUSSION
3.1 6-amino-2-cyanobenzothiazole (3) synthesis [1]
Having examined the published methods 15, 20-24, it can be seen that they have disadvantages:
a, certain synthesis routes require too many reagents, some of which are expensive (I.2)
b, choosing a less optimal starting material may require extra transformations (I.3)
c, the use of an ill-chosen solvent leads to low yield during the chlorine-cyanide exchange (I.4)
d, a less optimal order of the transformations results in low yield (I.5)
e, if the cyano group is present during the nitro group reduction, there is a high risk of its
reduction into an aminomethyl group (I.5)
3.1.1 2-chloro-6-nitrobenzothiazole (1) synthesis
As starting material, cheap, commercially available 2-chlorobenzothiazole was used, which was
nitrated with a mixture of KNO3 and cc H2SO4, keeping the temperature first under 15ºC than at
room temperature 28 (Scheme 21).
Scheme 21 Synthesis of 2-chloro-6-nitrobenzothiazole (1)
The structure of the resulting 2-chloro-6-nitrobenzothiazole (1) was attested by 1H-NMR (II.1),
TSQ-MS (II.2) and RP-HPLC (II.3). Recipe: III.2.1
- 24 -
3.Results and discussion
3.1.2 6-amino-2-chlorobenzothiazole synthesis (2)
The next step was the reduction of the nitro group. First the mixture of EtOH/AcOH/Fe powder
was used 28. Although the reaction was successful, the resulting by-product (Fe(III) acetate) was
difficult to dispose of, so this method was dismissed. When trying the reduction with
SnCl2/AcOH/cc HCl, large amounts of by-product formed, in which the chlorine was split off or
substituted with a hydroxyl group, so this method also had to be dismissed. The third possibility
was the application of Na2S2O5, which also turned out to be unsatisfactory due to the reduction
giving a very low yield (10%). Using Zn/HCl led to the same results as with SnCl2.
Finally, applying EtOAc/H2O/NH4Cl/Fe powder system solved the problem and the reduction
was successful with a good yield (90%) (Scheme 22).
Scheme 22 Synthesis of 6-amino-2-chlorobenzothiazole (2)
Using a Soxhlet extractor turned out to be a solvent-sparing, thus environmentally-friendly
method and processing the obtained product was also simple: the solution had to be decanted in
order to get rid of the Fe powder and then extracted. The structure of the resulting 6-amino-2-
chlorobenzothiazole (2) was attested by 1H-NMR (II.4), 13C-NMR (II.5), ESI-MS (II.6), RP-
HPLC (II.7). Recipe: III.2.2
- 25 -
3.Results and discussion
3.1.3 6-amino-2-cyanobenzothiazole synthesis (3)
The next step - the chlorine/nitrile exchange in the 6-amino-2-chlorobenzothiazole (2) - is the key
in the production of the desired conjugates. Six different methods had to be tried, the common
features of which were the polar aprotic non-aqueous solvent, the high temperature and the long
reaction time: a) anh DMSO/KCN, 160°C, 10h b) anh DMSO/KCN/KI, 160°C, 10h c) anh
DMSO/18-crown-6/KCN, 120°C, 8h d) anh DMF/KCN, 140°C, 12h e) anh HMPA/KCN, 140°C,
10h f) anh DMAA/KCN/KI, 120°C, 8h.
The first five methods had to be dismissed due to the low yield (15-20%). When trying DMAA,
however, it turned out that KCN is dissolved best in this solvent, resulting in relatively high yield
(80%) (Scheme 23).
Scheme 23 Synthesis of 6-amino-2-cyanobenzothiazole (3)
This means that the success of the chlorine/nitrile exchange depends on the rate of KCN
dissolution. The structure of the resulting 6-amino-2-cyanobenzothiazole (3) was attested by 1H-
NMR (II.8), 13C-NMR (II.9), ESI-MS (II.10), RP-HPLC (II.11). Recipe: III.2.3
- 26 -
3.Results and discussion
3.2 N-peptide-aLuc conjugate synthesis [1]
Ideally, in the next step the amino group of the 6-amino-2-cyanobenzothiazole (3) is blocked with
a protecting group. However, the low nucleophilicity of the amino group makes its protection
problematic, resulting in very low yield (3%). Our goal was to find a more reliable method.
3.2.1 N-peptide aLuc conjugate synthesis with liquid/solid phase Fmoc strategy
The desired aLuc conjugate (N-Z-Asp-Glu-Val-Asp-aLuc, 6) was reached in a 5-step route (I.6):
a) attachment of the C-terminal amino acid of the target sequence b) cysteine addition c)
attachment to resin d) solid-phase peptide synthesis e) cleavage from resin
3.2.1.1 N-Fmoc-Asp(OtBu)-6-amino-2-cyanobenzothiazole synthesis (4)
An Fmoc-protected amino acid (Fmoc-Asp(OtBu)-OH) was coupled to the 6-amino-2-
cyanobenzothiazole (3). As, due to the deactivated amino group, the amide bond could not be
formed with the usual coupling reagent, DCC, a much more activating coupling agent was
necessary. Different agents were tested in different quantities: COMU,20, 32-33 HATU,34 Deoxo-
Fluor Reagent,34 TFFH 35 and TCFH,36 all with a ratio of 1:1.5 and 1:3. The best yield (97%) was
obtained with 1.5 equivalents of TCFH (Scheme 24, Table 1).
Scheme 24 Synthesis of N-Fmoc-Asp(OtBu)-6-amino-2-cyanobenzothiazole (4)
- 27 -
3.Results and discussion
Coupling agent Quantity Yield
COMU 1.5 equiv 0 %
COMU 3.0 equiv 0 %
HATU 1.5 equiv 7 %
HATU 3.0 equiv 8 %
Deoxo-fluor reagent 1.5 equiv 48 %
Deoxo-fluor reagent 3.0 equiv 38 %
TFFH 1.5 equiv 59 %
TFFH 3.0 equiv 51 %
TCFH 1.5 equiv 97 %
TCFH 3.0 equiv 72%
Table 1 Coupling agents and corresponding yields
Other than the quantity of the different coupling reagents, all other conditions (solvent, reaction
time, temperature etc.) were kept the same. Although it was not checked with chiral
chromatography at this point, it became obvious following the achiral chromatography after the
cysteine addition that there was no racemization, because if there had been, during either this or
the previous step, we would have seen diastereomers. As the achiral chromatography after the
cysteine addition was indispensable anyway, we could save the rather complicated chiral
chromatography one step earlier. The structure of the resulting Fmoc-Asp(OtBu)-6-amino-2-
cyanobenzothiazole (4) was attested by TOF-MS (II.12) and RP-HPLC (II.13). Recipe: III.2.4
- 28 -
3.Results and discussion
3.2.1.2 N-Fmoc-Asp(OtBu)-aLuc synthesis (5)
During the addition of D-cysteine 37 to the Fmoc-Asp(OtBu)-6-amino-2-cyanobenzothiazole (4),
the amino acid-heterocycle conjugate was dissolved in THF and MeOH, then D-cysteine
hydrochloride monohydrate was added. The resulting compound was dissolved in water, and then
the cysteine was released from its salt with NaHCO3. During the reaction (about 25 minutes) the
pH of the solution was kept between 7.3-7.4 by the addition of NaHCO3 aqueous solution,
monitoring the process with a pH-meter and the addition was carried out under argon atmosphere.
By this way, the desired amino acid-aLuc conjugate, Fmoc-Asp(OtBu)-aLuc (5) was obtained
(Scheme 25).
Scheme 25 Synthesis of N-Fmoc-Asp(OtBu)-aLuc (5)
The structure of the resulting conjugate (5) was attested by TOF-MS (II.14) and RP-HPLC
(II.14). Recipe: III.2.5
- 29 -
3.Results and discussion
3.2.1.3 Attachment of N-Fmoc-Asp(OtBu)-aLuc (5) to solid support
During the next step this conjugate was attached to resin. Two types of resins (Figure 6) were
tested: 2-chlorotrityl chloride and p-alkoxybenzyl alcohol (Wang resin). Loading was checked in
both cases: with 2-chlorotrityl chloride resin it was 30%, while with Wang resin it was 50%, so
we decided to use the latter.
Figure 6 The two tested resins
3.2.1.4 Building the peptide chain
Classical solid phase peptide synthesis was carried out: the peptide chain was built with Fmoc
strategy. However, the N-terminal amino acid was always Z-protected, as this protecting group
gives higher biological stability to the peptide (Scheme 26). Recipe: III.2.6
3.2.1.5 Cleavage of the peptide from the resin
The obtained peptide-aLuc conjugate was removed from the resin with the mixture of TFA/water
(95:5 v/v) (Scheme 26). Recipe: III.2.7
- 30 -
3.Results and discussion
Scheme 26 Solid phase synthesis of N-Z-Asp-Glu-Val-Asp-aLuc (8)
Finally, the resulting material, Z-Asp-Glu-Val-Asp-aLuc (6), was purified by preparative RP-
HPLC (Recipe: III.2.8) and then its structure was attested by 1H-NMR (II.16 part 1-3), 13C-NMR
(II.17 part 1-2) spectra, ESI-MS (II.18) and RP-HPLC (II.19).
3.2.1.6 Limitations of the liquid/solid phase method [2]
Following the same route, we attempted to produce another conjugate, N-Z-Gly-Pro-aLuc, which
could be used for the measurement of the activity of such protease enzymes like FAP and POP.
Attaching the protected amino acid-aLuc conjugate (in this case N-Fmoc-Pro-aLuc) to solid
support, the loading was 50%. In order to reach higher load, instead of 3 hours, the coupling
reaction mixture was shaken for 6 hours. The determination of load showed that no improvement
- 31 -
3.Results and discussion
was achieved in loading and, according to the resulting material’s RP-HPLC profile (II.20) and
the mass spectrum (II.21), 20% of the coupled material was dehydrogenated among the
conditions mentioned above. As we were planning to purify the final, completed product, the
synthetizing process was not abandoned. The product on the resin was Fmoc-deprotected, which
was followed by coupling Z-protected glycine to the proline, and the resulting conjugate was
cleaved from the resin.
The RP-HPLC profile of the product (II.22) showed a homogeneous material, but, according to
the mass spectrum (II.23), it was not the expected N-Z-Gly-Pro-aLuc, but a fully dehydrogenated
conjugate, N-Z-Gly-Pro-6-aminodehydroluciferin (N-Z-Gly-Pro-2-(6-aminobenzo[d]thiazol-2-
yl)thiazole-4-carboxylic acid). This was also attested by its 1H-NMR-spectrum (II.24), on which
the -proton of the 2-thiazoline ring was not detectable; however, an olefin proton was, as proof
of dehydrogenation. The driving force behind this dehydrogenation was the aromatization of the
2-thiazoline ring, which led to its transformation into a thiazole ring (Scheme 27).
Scheme 27 The failed synthesis route to N-Z-Gly-Pro-aLuc
- 32 -
3.Results and discussion
Since this reaction did not occur earlier either, it might have been the result of the longer
exposure to the basic conditions.
As dehydroluciferin is a very efficient inhibitor of luciferase 38,39 it is not suitable for the above-
mentioned measurement of enzymatic activity.
3.2.2 N-peptide aLuc conjugate synthesis with fragment condensation strategy [2]
Our goal was to find a method that is more reliable than the hybrid liquid/solid phase synthesis
method, a synthesis route that prevents the side reactions mentioned above. The problem was
solved with returning to the fragment-condensation method, which is used to avoid problems
occurring during stepwise solid phase synthesis.40 Having made modifications to achieve better
results than the standard method, the desired peptide-luciferin conjugate (N-Fmoc-Gly-Pro-aLuc)
was reached in a 2-step route:
a) attachment of the target peptide sequence (N-Fmoc-Gly-Pro-OH) to 6-amino-2-
cyanobenzothiazole (3) b) cysteine addition (Scheme 28, I.6):
Scheme 28 Synthesis of N-Fmoc-Gly-Pro-aLuc (8)
The optimized synthesis route of the key molecule (3), [1] and the modifications of the two steps
[2] make a significant improvement over the standard methods.9, 29-31
- 33 -
3.Results and discussion
3.2.2.1 N-Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole synthesis (7)
A suitably protected, commercially purchased peptide, N-Fmoc-Gly-Pro-OH, was coupled with
the key molecule, 6-amino-2-cyanobenzothiazole (3). (As during the synthesis only a dipeptide
was coupled to the 6-amino-2-cyanobenzothiazole (3), it was reasonable to purchase a ready
material, rather than synthesize and purify one. In case of longer peptides, solid phase peptide
synthesis can be used.) Due to the deactivated amino group of the 6-amino-2-cyanobenzothiazole
(3), the amide bond could not be formed with the usual coupling reagents; therefore, a more
powerful coupling agent 36 was necessary. Excellent conversion (97%) of the 6-amino-2-
cyanobenzothiazole (3) was obtained with 1.5 equivalents of TCFH. Obtained yield,
corresponding to the crude product: 68%. (Scheme 28, II.25, II.26). Recipe: III.2.9
With this process, we could avoid the extremely long coupling time of the standard mixed
anhydride method 30,31 and reached adequate yield (68%).
3.2.2.2 N-Fmoc-Gly-Pro-aLuc (8) synthesis
The peptide-heterocycle conjugate (N-Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole, 7) was
dissolved in MeOH, then D-cysteine hydrochloride monohydrate was added. The resulting
substance was dissolved in water and the cysteine was released from its salt with NaHCO3.
During the reaction (about 25 minutes) the pH of the solution was kept between 7.3-7.4 with the
addition of NaHCO3 aqueous solution, the process was continuously monitored with a pH-meter,
under argon atmosphere. The Fmoc-protection of the the N-terminal amino-group of the peptide
was kept up because it gave higher biological stability to the conjugate (Scheme 28). The
structure of the resulting conjugate was attested by 1H-NMR (II.27), 13C-NMR (II.28), ESI-MS
(II.29) spectra and RP-HPLC (II.30). Recipe: III.2.10
This method is also an improvement over the standard practice 9,29-31 as the window between pH
7.3-7.4 a) rules out the racemization of D-cysteine b) ensures the release of the cysteine from its
salt.
- 34 -
3.Results and discussion
3.2.2.3 Limitations of the fragment condensation method
Although our optimized fragment condensation method was successful [2], it had certain
limitations: a) when attaching longer peptides (ones that contain more than ten amino acids),
solubility problems may occur, which may make coupling difficult 40, b) when not glycine or
proline is chosen as the C-terminal amino acid, racemization might occur. 40
3.2.3 Building block production for the Boc-strategy solid phase synthesis of N-peptide-aLuc
conjugates
To avoid the aforementioned difficulties, an old-fashioned method, the Boc-strategy solid phase
peptide synthesis had to be tried to produce N-peptide-aLuc conjugates. The cornerstone of Boc-
strategy N-peptide-aLuc conjugate synthesis is the availability of Boc protected aLuc in large
quantities. Coupling a protected amino acid to the 6-amino-2-cyanobenzothiazole (3) would have
limited our possibilities. Our aim was to synthetize a general, all-purpose Boc protected aLuc to
which any peptide sequence can be attached. The desired substance was obtained in a 2-step
route.
3.2.3.1 Unsuccessful attempts
3.2.3.1.1 Unsuccessful Boc-anhydride attempt to produce N-Boc-aLuc
At our first attempt we tried the reaction of aLuc and Boc anhydride (solvent: acetone/water 1:1,
base: Na2CO3, room temperature, overnight). Due to the low reactivity of the amino function,
however, the method proved to be unsuccessful (Scheme 29).
Scheme 29 Unsuccessful Boc-anhydride attempt to produce N-Boc-aLuc
- 35 -
3.Results and discussion
3.2.3.1.2 Unsuccessful Boc-anhydride attempt to produce N-Boc-6-amino-2-cyanobenzothiazole
The second attempt, reacting the precursor of aLuc, 6-amino-2-cyanobenzothiazole (3) with Boc
anhydride (solvent: acetonitrile/acetone/water 2:4:1, base: Na2CO3, room temperature,
overnight), also failed, the amino group was still not reactive enough. (Scheme 30).
Scheme 30 Unsuccessful Boc-anhydride attempt to produce N-Boc-6-amino-2-
cyanobenzothiazole
We did not want to use the method we used earlier, that is, coupling a protected amino acid to the
6-amino-2-cyanobenzothiazole (3), [1], because it would have limited our possibilities: our goal
was to synthetize a general, all-purpose Boc protected aLuc to which any peptide sequence can
be attached.
After a thorough examination of the methods in the literature 41-57, they had to be dismissed. For
our purposes, the disadvantage of these methods is that a) none of them is applied on substances
of such extremely low nucleophilicity as the one in our research – 6-amino-2-cyanobenzothiazole
(3); b) as our target substance serves as a building block, needed in great quantities for the
scalable solid phase Boc strategy of N-peptide-aLuc conjugates, these methods are highly
uneconomical.
- 36 -
3.Results and discussion
3.2.3.1.3 Unsuccessful triphosgene attempt to produce N-Boc-6-amino-2-cyanobenzothiazole
When trying to incorporate a Boc protecting group into amines of low nucleophilicity, using
phosgene or a phosgene equivalent proves to be the solution.58 In our first triphosgene attempt
tBuOH and triphosgene were reacted in EtOAc at -15 C° (producing chloroformic acid tert-butyl
ester as intermediate) under continuous stirring for 1 hour, then the mixture of 6-amino-2-
cyanobenzothiazole (3) and DIPEA, both dissolved in EtOAc, was added dropwise in 1.5 hours at
-15°C. The new mixture was stirred for another 60 minutes at -15°C, then it was neutralized with
28% aquous NaOH solution at 0°C. It was extracted both with EtOAc and water 3 times, then
dried over sicc Na2SO4. The resulting material did contain N-Boc-6-amino-2-cyanobenzothiazole
(9), but due to the low yield (10% corresponding to the crude product, Scheme 31), the method
had to be dismissed and another method from the same patent 58 had to be applied.
Scheme 31 Unsuccessful triphosgene attempt to produce N-Boc-6-amino-2-cyanobenzothiazole
- 37 -
3.Results and discussion
3.2.3.2 Successful synthesis route
3.2.3.2.1 N-Boc-6-amino-2-cyanobenzothiazole synthesis (9)
According to another method from the aforementioned patent,58 6-amino-2-cyanobenzothiazole
(3) was solved in EtOAc, then DIPEA was added. Triphosgene was added to this mixture
portionwise. The reaction system was stirred for 1 hour at 60°C (producing (2-
cyanobenzo[d]thiazol-6-yl)carbamic chloride as intermediate), then tBuOH was added. The new
mixture was stirred for another 1 hour at 60°C. Then the acidic solution was neutralized with
28% aquous NaOH solution at 0°C and extracted with EtOAc, water and saturated NaCl solution,
then dried over sicc Na2SO4 and evaporated. This time the yield of N-Boc-6-amino-2-
cyanobenzothiazole (9) was significantly better (74% corresponding to the crude product) (II.31,
II.32, Scheme 32), which might be the result of the fact that (2-cyanobenzo[d]thiazol-6-
yl)carbamic chloride is a much more stable intermediate than the intermediate chloroformic acid
tert-butyl ester. Recipe: III.11
Scheme 32 Synthesis of N-Boc-6-amino-2-cyanobenzothiazole (9)
- 38 -
3.Results and discussion
3.2.3.2.2 N-Boc-aLuc synthesis (10)
The resulting N-Boc-6-amino-2-cyanobenzothiazole (9) was dissolved in a mixture of MeOH and
THF, then aqueous solution of D-cysteine hydrochloride monohydrate was added, and the
mixture was stirred for 20 minutes at room temperature. The cysteine was released from its salt
with 5 m/m% NaHCO3 solution. During the reaction (about 75 minutes) the pH of the solution
was kept between 7.3-7.4 with the addition of 5 m/m% NaHCO3 solution, the process was
continuously monitored with a pH meter, under argon atmosphere (Scheme 33). The solution was
evaporated then taken up in water and extracted with methyl tert-butyl ether. Dropping the
aqueous phase on a mixture of ice and glacial acetic acid, a fine yellow precipitate, N-Boc-aLuc
free carboxylic acid (10) formed, which was then filtered, yield: 85%.
Scheme 33 Synthesis of N-Boc-aLuc (10)
The structure of the product was attested by 1H-NMR (II.33) and 13C-NMR (II.34) spectra and
mass spectrometry (II.35), its optical purity was attested with chiral chromatography (II.36,
II.37). Optical rotation was also measured. Recipe: III.2.12
- 39 -
3.Results and discussion
3.2.4 Biological testing
3.2.4.1 Biological testing of N-Z-Asp-Glu-Val-Asp-aLuc (6)
3.2.4.1.1 Biochemical and cellular testing
The biological relevance of our N-Z-Asp-Glu-Val-Asp-aLuc (6) substrate was confirmed in a
biochemical reaction using a serial dilution of recombinant caspase-3 from 227 mU/reaction to
22.7µU/reaction. It has been published that both caspase-3 and caspase-7 digest Asp-Glu-Val-
Asp sequence, but caspase-3 has six-time higher Asp-Glu-Val-Asp digestion activity 61, 62 (Figure
7A and 7B). In order to verify that our N-Z-Asp-Glu-Val-Asp-aLuc (6) is a real substrate for
caspase-3, not only the enzyme but also the N-Z-Asp-Glu-Val-Asp-aLuc (6) substrate was titrated
in a concentration range from 100 µM to 1 µM. The recorded luminescence was linearly
proportional with the increasing enzyme activity and increased amount of the N-Z-Asp-Glu-Val-
Asp-aLuc (6) substrate, showing maximum cps at 227 mU caspase-3 and 100 µM N-Z-Asp-Glu-
Val-Asp-aLuc (6) (Figure 7A, II.38, IV.1) Moreover, the luminescence signal was completely
abolished by the application of equimolar pan-caspase inhibitor Z-Val-Ala-Asp-fmk in the
reaction of 2.27 mU caspase-3 and 10 µM N-Z-Asp-Glu-Val-Asp-aLuc (6),63 (Figure 7B). We
also verified the applicability of our N-Z-Asp-Glu-Val-Asp-aLuc (6) substrate to detect cellular
apoptotic cell death caused by a drug candidate molecule. The curcumin analogue C150 induces
caspase-3 activation (II.39, IV.2) and apoptosis of A549 human non-small cell lung carcinoma
cells 64, 65 and we could detect the activation of caspase-3 by N-Z-Asp-Glu-Val-Asp-aLuc (6) via
bioluminescence (Figure 7C, IV.3, IV.4).
- 40 -
3.Results and discussion
Figure 7 Testing the N-Z-Asp-Glu-Val-Asp-aLuc (6) substrate in biochemical (A and B) and
cellular (C) systems. Control corresponds to untreated sample. The results are shown as
arithmetic mean values of three samples ± SEM
3.2.4.1.2 In vivo testing
To measure apoptosis directly in animals, an optical imaging experiment was performed in vivo,
administrating N-Z-Asp-Glu-Val-Asp-aLuc (6) to SCID mice (previously inoculated with the
stably expressing luciferase cell line U87-Luc) that had been treated with chemotherapeutics
previously. We used Ac-915, a lipid droplet binding thalidomide analogue inducing caspase-3
activation (II.40), and oxidative stress and apoptosis in different cancer cells. 66 Ac-915 enhanced
the bioluminescent signal already at 6 hours. Significantly fewer signals were detected from
control mouse having no Ac-915 treatment, but injected with only N-Z-Asp-Glu-Val-Asp-aLuc
(8) substrate, which represents the basal level of apoptosis. However, the limitation of the
widespread applicability of the luciferin conjugated peptides in vivo is that luciferase enzyme
activity is indispensable, therefore luciferase transgenic mouse or cells should be used in these
studies (IV.5)
- 41 -
3.Results and discussion
Figure 8 Demonstration of applicability of the N-Z-Asp-Glu-Val-Asp-aLuc (6) substrate in
mouse bearing cancer, previous treated with an apoptosis inducer Ac-915. Aminoluciferin was
used as positive control (right)
3.2.4.2 Biological testing of N-Fmoc-Gly-Pro-aLuc (8)
N-Fmoc-Gly-Pro-aLuc (8) was tested in bioluminescence-based enzyme activity assays. The
substrate specificity of N-Fmoc-Gly-Pro-aLuc (8) was measured with two human proteases that
are involved in cancer, POP/PREP (Figure 9A) and FAP (Figure 9B), and with a bacterial non-
specific endoproteinase Pro-C (Figure 9C). All three enzymes accepted the substrate and
liberated aminoluciferin as a product, resulting in increased luminescence signal. Luminescence
was proportional to protease activity and N-Fmoc-Gly-Pro-aLuc (8) concentration. Enzymatic
degradation was confirmed with protease inhibitor, which completely abolished bioluminescent
signal increase (Figure 9D-F). Our novel substrate, therefore, could be used in different
biochemical assays with different proteases (IV.6).
- 42 -
3.Results and discussion
Figure 9 (A) POP/PREP, (B) FAP and (C) Endoproteinase Pro-C protease activity on the
substrate N-Fmoc-Gly-Pro-aLuc (8). (D-F) The effect of protease inhibition. Each point
represents the average of 3 wells ± SD. Values are blank-subtracted (blank = no protease).
*p<0.05; ** p<0.01; ***p<0.001
- 43 -
5. Summary
5. SUMMARY
Efficient routes have been developed for the synthesis of N-peptide-aLuc conjugates. Two of the
routes are optimized versions of already published methods, while the third one is a completely
new method.
Precursor
As a starting step, all the three methods use a novel route for the synthesis of the precursor of the
desired final products, 6-amino-2-cyanobenzothiazole (3), which was obtained in a 3-step route:
a) nitration b) reduction c) chlorine-cyanide exchange
As starting material, cheap, commercially available 2-chlorobenzothiazole was used, which was
first nitrated. The resulting 2-chloro-6-nitrobenzothiazole (1) was reduced applying ethyl
acetate/water/ammonium chloride/iron powder system with a good yield. Using a Soxhlet extractor
turned out to be a solvent-sparing, thus environmentally-friendly method. Finally, the chlorine-
cyanide exchange was carried out in a polar aprotic non-aqueous solvent (DMAA), at high
temperature and with long reaction time.
Although the used transformations (nitration, reduction and cyanidation) are well-known in the
literature, our combination of these transformations, the equipment and the solvents make it
possible to prepare this material in larger quantities than the published strategies.
Mixed liquid/solid phase method
From the precursor, the desired N-peptide-aLuc conjugate (N-Z-Asp-Glu-Val-Asp-aLuc, 6) was
reached in a 5-step route:
a) attachment of the C-terminal amino acid of the target sequence b) cysteine addition
c) attachment to resin d) solid phase peptide synthesis e) cleavage from resin
An N-Fmoc-protected amino acid (N-Fmoc-Asp(OtBu)-OH) was coupled to the 6-amino-2-
cyanobenzothiazole (3). As, due to the deactivated amino group, the amide bond could not be
formed with the usual coupling reagents like DCC, a much more activating coupling agent was
necessary. Excellent yield (97%) was obtained with 1.5 equivalents of TCFH. After the addition
of D-cysteine, the desired amino acid-aLuc conjugate, N-Fmoc-Asp(OtBu)-aLuc (5) was obtained.
- 44 -
5. Summary
During the next step this conjugate was attached to Wang resin, then classical solid phase peptide
synthesis was carried out: the peptide chain was built with Fmoc strategy. The obtained N-peptide-
aLuc conjugate was removed from the resin with the mixture of TFA/water; and finally, the
resulting material was purified by preparative HPLC and successfully tested in vivo and
biochemical and cellular probes.
The advantage of the method over standard liquid phase methods lies in the fact that it requires
only one chromatographic purification step. However, the high risk of dehydrogenation poses
limitations to the method.
Fragment condensation method
The desired N-peptide-aLuc conjugate (N-Fmoc-Gly-Pro-aLuc, 8) was reached in a 2-step route:
a) attachment of the target peptide sequence to 6-amino-2-cyanobenzothiazole (3)
(b) cysteine addition
A suitably protected, commercially purchased peptide, N-Fmoc-Gly-Pro-OH, was coupled with the
key molecule, 6-amino-2-cyanobenzothiazole (3). Due to the deactivated amino group of the 6-
amino-2-cyanobenzothiazole (3), the amide bond could not be formed with the usual coupling
reagents; therefore, a more powerful coupling agent, TCFH, was necessary.
D-cysteine hydrochloride monohydrate was added to the peptide-heterocycle conjugate (N-Fmoc-
Gly-Pro-6-amino-2-cyanobenzothiazole, 7). During the reaction, the pH of the solution was kept
between 7.3-7.4. The resulting material was purified by preparative HPLC and successfully tested
in bioluminescence-based enzyme activity assays.
The novelty of the method lies in the fact that the modifications of the two steps make a significant
improvement over the standard method: the extremely long coupling time of the standard mixed
anhydride method can be avoided, furthermore, the window between pH 7.3-7.4 rules out the
racemization of the D-cysteine and ensures the release of the cysteine from its salt. The
disadvantage of the method is that when attaching longer peptides (ones that contain more than ten
amino acids), solubility problems may occur, which may make coupling difficult. Also, ill-chosen
C-terminal amino acid might lead to racemization. These are typical problems with the fragment
condensation methods in general.
- 45 -
5. Summary
Immediate precursor for Boc strategy solid phase method
We have successfully produced the building block of the Boc-strategy solid phase method, N-Boc-
aLuc.
N-Boc-aLuc was obtained in a 2-step route:
a) introduction of Boc protecting group to 6-amino-2-cyanobenzothiazole (3)
b) cysteine addition
Triphosgene was added to 6-amino-2-cyanobenzothiazole (3), producing (2-cyanobenzo[d]thiazol-
6-yl)carbamic chloride as intermediate, then tert-butanol was added. D-cysteine hydrochloride
monohydrate was added to the resulting N-Boc-6-amino-2-cyanobenzothiazole (9). The pH of the
solution was kept between 7.3-7.4. The resulting material, N-Boc-aLuc was purified by preparative
HPLC.
This building block can be attached to Boc-compatible resin, then the desired peptide sequence can
be built and cleaved from the resin.
- 46 -
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- 52 -
5. Acknowledgements
5. ACKNOWLEDGEMENTS
I am grateful to my supervisors, Professor Gábor K. Tóth, Head of the Department of Medical
Chemistry for providing me with the opportunity to perform my work at the department and Dr
László G. Puskás for his scientific guidance.
I would like to give my special thanks to Dr Péter Hegyes for his love and support during my
PhD years.
I am greatly indebted to Dr Gábor J. Szebeni and Dr Lajos I. Nagy for their contribution in
biological research, and also Dr Anasztázia Hetényi and Dr Krisztián Bogár for their
invaluable work in NMR spectroscopy.
The completion of my dissertation would not have been possible without the help of Professor
Alexey Trofimov and Mr Tibor Borbás.
Finally, I would like to thank my colleagues at the department for their help, encouragement and
friendship throughout the years.
APPENDIX
- 53 -
I.Tables
I.TABLES
Table I.1 Literary overview of 6-amino-2-cyanobenzothiazole synthesis routes
Hauser Takakura Hsu
4-nitroaniline 6-nitrobenzothiazole ethyl benzothiazole 2-carboxylate 2-chlorobenzothiazole
McCutcheon / 1 McCutcheon / 2 Gryshuk / 1 Gryshuk / 2 Gryshuk / 3 Gryshuk / 4
2-chloro-6-nitrobenzothiazole
2-cyano-6-nitrobenzothiazole 6-amino-2-chlorobenzothiazole
6-amino-2-cyanobenzothiazole
(4-nitrophenyl)-
carbonocyanido-
thioic amide
2-amion-5-
nitrobenzenethiol
6-nitrobenzothiazole-
2-carboxylate
ethyl-6-
nitrobenzothiazole-2-
carboxylate
benzothiazole-2-carboxamide
2-cyanobenzothiazole6-nitrobenzothiazole-2-carboxamide
- 54 -
I.Tables
Table I.2.1 Methods for the synthesis of 6-amino-2-cyanobenzothiazole
Author Starting material Transformation Yield (%)
Overall yield
Reagent Solvent Reaction time Temperature (°C)
Disadvantages Comments
Takakura et al. 2011
2-chlorobenzothiazole nitration 49
16
H2SO4, KNO3 H2SO4 1h 30m 0-15 -
2-chloro-6-nitrobenzothiazole
reduction 61 SnCl2, HCl,
NaOH EtOH, H2O ? 120
A significant amount of by-product (2-hydroxy-6-aminobenzothiazole and 6-aminobenzothiazole) formed. The high temperature cannot be understood
6-amino-2-chlorobenzothiazole
cyanidation 54 KCN DMSO overnight 135
DMSO is not the best solvent for this step, as with distillation it cannot be regained from the aqueous solution.
Gryshuk et al. 1 2013
6-nitrobenzothiazole acylation 61
8
H2SO4, H2O2, FeSO4,
NaHCO3 H2O more than 30m rt, 0
The step itself is good, but the starting material is ill-chosen.
The starting material is not optimal, consequently the method is too complicated, the desired end-product is reached in four steps, instead of the others’ three.
6-nitrobenzothiazole-2-carboxylate
amidation 80 NH3 MeOH 20m rt -
6-nitrobenzothiazole-2-carboxamide
cyanidation 24 POCl3, H2O,
pyridine EtOAc 2h 20m 0, rt -
2-cyano-6-nitrobenzothiazole
reduction 65 SnCl2,
NaHCO3 EtOH, H2O 2h rt, 60
If the cyano group is present during the NO2 reduction, there is a high risk of its reduction into an aminomethyl group.
- 55 -
I.Tables
Table I.2.2 Methods for the synthesis of 6-amino-2-cyanobenzothiazole
Author Starting material Transformation Yield (%)
Overall yield
Reagent Solvent Reaction time Temperature (°C)
Disadvantages Comments
Gryshuk et al. 2 2013
ethyl benzothiazole-2-carboxylate
nitration 10
5
H2SO4, HNO3
H2O more than 1h 0-15
The ill-chosen starting material can be nitrated with very low yield, also, there is a high risk of hydrolysis under the aqueous-acidic conditions.
The desired end-product is reached in four steps, instead of the others’ three.
ethyl-6-nitrobenzothiazole-2-carboxylate
amidation 80 NH3 MeOH 20m rt -
6-nitrobenzothiazole-2-carboxamide
cyanidation 24 POCl3, H2O,
pyridine EtOAc 2h 20m 0, rt -
2-cyano-6-nitrobenzothiazole
reduction 65 SnCl2,
NaHCO3 EtOH, H2O 2h rt, 60
If the cyano group is present during the NO2 reduction, there is a high risk of its reduction into an aminomethyl group
Gryshuk et al. 3 2013
ethyl benzothiazole-2-carboxylate
amidation ?
(<5)
NH3 MeOH 15-30m rt -
In step 1 there is 100% conversion rate, but due to the lack of purification, no known yield.
benzothiazole-2-carboxamide
nitration 30 H2SO4, HNO3
H2O overnight 0-15 There is a risk of hydrolysis of the amide under the aqueous-acidic conditions.
6-nitrobenzothiazole-2-carboxamide
cyanidation 24 POCl3, H2O,
pyridine EtOAc 2h 20m 0, rt -
2-cyano-6-nitrobenzothiazole
reduction 65 SnCl2,
NaHCO3 EtOH, H2O 2h rt, 60
If the cyano group is present during the NO2 reduction, there is a high risk of its reduction into an aminomethyl group.
- 56 -
I.Tables
Table I.2.3 Methods for the synthesis of 6-amino-2-cyanobenzothiazole
Author Starting material Transformation Yield (%)
Overall yield
Reagent Solvent Reaction time Temperature (°C)
Disadvantages Comments
Gryshuk et al. 4 2013
ethyl benzothiazole-2-carboxylate
amidation ?
(<62)
NH3 MeOH 15-30m rt - In step 1, 100% conversion, but due to the lack of purification, no known yield, In step 3, yield was not determined, therefore the overall yield cannot be determined.
benzothiazole-2-carboxamide
cyanidation 95 POCl3, H2O,
pyridine EtOAc 2h 20m 0, rt -
2-cyanobenzothiazole
nitration ? H2SO4, HNO3 H2O 6h 0 -
2-cyano-6-nitrobenzothiazole
reduction 65 SnCl2, NaHCO3 EtOH, H2O 2h rt, 60
If the cyano group is present during the NO2 reduction, there is a high risk of its reduction into an aminomethyl group
McCutcheon et al. 1 2015
4-nitroaniline thiocyanidation 80
56
pyridine, sodium thiosulphate, 4,5-
dichloro-1,2,3-dithiazol-1-ium
chloride
H2O, acetonitrile,
THF 1h 30m rt
Complicated method, fewer reagents would be more reasonable. 4,5-dichloro-1,2,3-dithiazol-1-ium chloride is very expensive.
Extremely complicated route.
(4-nitrophenyl)-carbonocyanidothioic amide
cyanidation 74 CuI, Bu4N+ •Br-, Catalyst: PdCl2
DMF, DMSO
4h 130 Extremely complicated method, special catalysts are required.
6-nitro-2-cyanobenzothiazole
reduction 95 Zn, NH4Cl MeOH 35m rt
If the cyano group is present during the NO2 reduction, there is a high risk of its reduction into an aminomethyl group.
McCutcheon et al. 2 2015
6-nitrobenzothiazole
decomposition of the thiazole
ring
62
37
N2H4
EtOH, DCM
12h
rt, reflux
-
2-amino-5-nitrobenzenethiol
cyanidation
62
4,5-dichloro-1,2,3-dithiazol-1-
ium chloride
DCM
12 h
reflux
4,5-dichloro-1,2,3-dithiazol-1-ium chloride is very expensive.
6-nitro-2-cyanobenzothiazole
reduction
95
NH4Cl, Zn
MeOH
35m
rt
If the cyano group is present during the NO2 reduction, there is a high risk of its reduction into an aminomethyl group.
- 57 -
I.Tables
Table I.2.4 Methods for the synthesis of 6-amino-2-cyanobenzothiazole
Author Starting material Transformation Yield (%)
Overall yield
Reagent Solvent Reaction time
Temperature (°C)
Disadvantages Comments
Hsu et al. 2016
2-chlorobenzothiazole nitration 67
27
H2SO4, KNO3 H2SO4 4h 0-15 -
Too much by-product and waste.
2-chloro-6-nitrobenzothiazole
reduction 88 Fe, FeCl3 EtOH,
acetic acid 24h 80
The resulting by-product (Fe(III)-acetate) is difficult to separate from the desired product.
6-amino-2-chlorobenzothiazole
cyanidation 45 KCN DMSO 24h 120
DMSO is not the best solvent for this step, as with distillation it cannot be regained from the aqueous solution.
Hauser et al. 2016
2-chlorobenzothiazole nitration 82
44
H2SO4, KNO3 H2SO4 18h 0-15 -
Too much by-product.
2-chloro-6-nitrobenzothiazole
cyanidation 75 NaCN, Dabco catalyst, FeCl3
H2O, acetonitrile
24h rt
Two byproducts (2-carbethoxy-6-nitrobenzothiazole and 2-ethoxy-nitrobenzothiazole) formed.
2-cyano-6-nitrobenzothiazole
reduction 71 Fe acetic acid 24h rt
If the cyano group is present during the NO2 reduction, also, there is a high risk of its reduction into an aminomethyl group. The resulting by-product (Fe(III)-acetate) is difficult to separate from the desired product.
Kovács et al 2018.
2-chlorobenzothiazole nitration 83 57 H2SO4, KNO3 H2SO4 5h 0-15 - -
2-chloro-6-nitrobenzothiazole
reduction
88
NH4Cl, H2O, Fe powder
EtOAc
8h
reflux
-
Using Soxhlet extractor, the EtOAc can be fully regained.
6-amino-2-chlorobenzothiazole
cyanidation
78
KCN
DMAA
12h
110
The reagent is toxic, but was reacted with KH2PO4 in order to get non-toxic KOCN.
The use of DMAA instead of other solvents results in significantly better yield during cyanidation.
- 58 -
I.Tables
Table I.3 Comparison of starting materials
Author Starting material Transformation Yield (%)
Reagent Solvent Reaction time Temperature
(°C) Disadvantages Comments
Takakura et al. 2011 2-chlorobenzothiazole
nitration 49 H2SO4, KNO3 H2SO4 1h 30m 0-15 _
Gryshuk et al. 1 2013
6- nitrobenzothiazole
acylation 61 H2SO4, H2O2,
FeSO4, NaHCO3 H2O more than 30m rt, 0
The step itself is good, but the starting material is ill-chosen, which makes the following step uneconomical.
.
Gryshuk et al. 2 2013
ethyl benzothiazole-2-carboxylate
nitration 10 H2SO4, HNO3 H2O more than 1h 0-15
The ill-chosen starting material can be nitrated with very low yield, also, there is a high risk of hydrolysis under the aqueous-acidic conditions.
Gryshuk et al. 3 2013
ethyl benzothiazole-2-carboxylate
amidation ? NH3 MeOH 15-30m rt _
100% conversion, but due to the lack of purification, yield was not determined
Gryshuk et al. 4 2013
ethyl benzothiazole-2-carboxylate
amidation ? NH3 MeOH 15-30m rt _
100% conversion, but due to the lack of purification, yield was not determined
McCutcheon et al. 1 2015
4-Nitroaniline thiocyanidation 80
pyridine, sodium thiosulphate, 4,5-dichloro-
1,2,3-dithiazol-1-ium chloride
H2O, acetonitrile,
THF 1h 30m rt
Complicated method, fewer reagents would be more reasonable. 4,5-dichloro-1,2,3-dithiazol-1-ium chloride is very expensive.
McCutcheon et al. 2 2015
6- nitrobenzothiazole
decomposition of the thiazole
ring 62 N2H4 EtOH, DCM 12h rt, reflux _
Hsu et al. 2016
2-chlorobenzothiazole
nitration 67 H2SO4, KNO3 H2SO4 4h 0-15 _
Hauser et al. 2016 2-chlorobenzothiazole
nitration 82 H2SO4, KNO3 H2SO4 18h 0-15 _
- 59 -
I.Tables
Table I.4 Comparison of solvents during chlorine-cyanide exchange
Author Starting material Transformation Yield (%) Reagent Solvent Reaction time Temperature (°C) Disadvantages
Takakura et al. 2011
6-amino-2-chlorobenzothiazole
cyanidation 54 KCN DMSO overnight 135 DMSO is not the best solvent for this step, as with distillation it cannot be regained from the aqueous solution.
Hsu et al. 2016
6-amino-2-chlorobenzothiazole
cyanidation 45 KCN DMSO 24h 120 DMSO is not the best solvent for this step, as with distillation it cannot be regained from the aqueous solution.
Hauser et al. 2016
2-chloro-6-nitrobenzothiazole
cyanidation 75 NaCN, Dabco catalyst, FeCl3
H2O, acetonitrile 24h rt
Two byproducts (2-carbethoxy-6-nitrobenzothiazole and 2-ethoxy-nitrobenzothiazole) formed.
- 60 -
I.Tables
Table I.5 Comparison of the optimal and the non-optimal order of reduction and cyanidation
Author Starting material Transformation Yield (%)
Reagent Solvent Reaction time Temperature (°C) Disadvantages
Takakura et al. 2011
2-chloro-6-nitrobenzothiazole
reduction 61 SnCl2, HCl, NaOH EtOH, H2O ? 120
- 6-amino-2-chlorobenzothiazole
cyanidation 54 KCN DMSO overnight 135
Gryshuk et al. 1, 2 and 3
2013
6-nitrobenzothiazole-2-carboxamide
cyanidation 24 POCl3, H2O, pyridine EtOAc 2h 20m 0, rt If the cyano group is present during the NO2 reduction, there is a high risk of its reduction into an aminomethyl group.
2-cyano-6-nitrobenzothiazole
reduction 65 SnCl2, NaHCO3 EtOH, H2O 2h rt, 60
Gryshuk et al. 4 2013
benzothiazole-2-carboxamide
cyanidation 95 POCl3, H2O, pyridine EtOAc 2h 20m 0, rt If the cyano group is present during the NO2 reduction, there is a high risk of its reduction into an aminomethyl group.
2-cyanobenzothiazole nitration ? H2SO4, HNO3 H2O 6h 0
2-cyano-6-nitrobenzothiazole
reduction 65 SnCl2, NaHCO3 EtOH, H2O 2h rt, 60
McCutcheon et al. 1 2015
(4-nitrophenyl)-carbonocyanidothioic amide
cyanidation 74 CuI, Bu4N+ •Br-, Catalyst:
PdCl2 DMF, DMSO 4 h 130
If the cyano group is present during the NO2 reduction, there is a high risk of its reduction into an aminomethyl group.
6-nitro-2-cyanobenzothiazole
reduction 95 Zn, NH4Cl MeOH 35m rt
McCutcheon et al 2. 2015
2-amino-5-nitrobenzenethiol
cyanidation 62 4,5-dichloro-1,2,3-
dithiazol-1-ium chloride DCM 12 h reflux
If the cyano group is present during the NO2 reduction, there is a high risk of its reduction into an aminomethyl group.
6-nitro-2-cyanobenzothiazole
reduction 95 NH4Cl, Zn MeOH 35m rt
Hauser et al. 2016
2-chloro-6-nitrobenzothiazole
cyanidation 75 NaCN, Dabco catalyst,
FeCl3 H2O, acetonitrile 24h rt
If the cyano group is present during the NO2 reduction, also, there is a high risk of its reduction into an aminomethyl group. The resulting by-product (Fe(III)-acetate) is difficult to separate from the desired product..
2-cyano-6-nitrobenzothiazole
reduction 71 Fe acetic acid 24h rt
- 61 -
II. Figures
II. FIGURES
II.1. 1H-NMR spectrum of 2-chloro-6-nitrobenzothiazole (1)
(CDCl3, 500 MHz) 8.77 (s, 1H), 8.41 (d, J= 9.0 Hz, 1H), 8.10 (d, J= 9.0 Hz, 1H)
- 62 -
II. Figures
II.2. TSQ mass spectrum of 2-chloro-6-nitrobenzothiazole (1)
213.93= [M-H]-
- 63 -
II. Figures
II.3. RP-HPLC profile of the crude 2-chloro-6-nitrobenzothiazole (1)
70-100% B in 15 min + 1005 B in 5 min, tR1= 3.878 min: 2-chloro-5-nitrobenzothiazole,
tR2= 7.899 min: 2-chloro-6-nitrobenzothiazole
- 64 -
II. Figures
II.4 1H-NMR spectrum of 6-amino-2-chlorobenzothiazole (2)
([D6]DMSO, 600 MHz ) (d, J = 8.4 Hz, 1H), 7.04 (d, J = 2.4 Hz, 1H), 6.78 (dd, J1 = 1.8
Hz, J2 = 8.4 Hz, 1H), 5.53 (bs, 2H)
- 65 -
II. Figures
II.5 13C-NMR spectrum of 6-amino-2-chlorobenzothiazole (2)
([D6]DMSO, 150 MHz) 148.24, 145.51, 142.00, 137.86, 123.13, 115.51, 104.18
- 66 -
II. Figures
II.6 ESI mass spectrum of 6-amino-2-chlorobenzothiazole (2)
185.0= [M+H]+
- 67 -
II. Figures
II.7 RP-HPLC profile of 6-amino-2-chlorobenzothiazole (2)
5-80% B in 25 min + 3 min up to 100% B + 100% B in 5 min
tR= 11.527 min
- 68 -
II. Figures
II.8 1H-NMR of 6-amino-2-cyanobenzothiazole (3)
([D6]DMSO, 600 MHz ) (d, J = 9.0 Hz, 1H), 7.22 (d, J = 1.8 Hz, 1H), 7.01 (dd, J1 = 1.8 Hz,
J2 = 9.0 Hz, 1H), 4.40 (bs, 2H)
- 69 -
II. Figures
II.9 13C-NMR spectrum of 6-amino-2-cyanobenzothiazole (3)
([D6]DMSO, 150 MHz) 150.06, 144.10, 138.75, 128.86, 125.62, 118.19, 114.71, 103.54
- 70 -
II. Figures
II.10 ESI mass spectrum of 6-amino-2-cyanobenzothiazole (3)
176.0= [M+H]+
- 71 -
II. Figures
II.11 RP-HPLC profile of 6-amino-2-cyanobenzothiazole (3)
5-80% B in 25 min + 3 min up to 100% B + 5 min 100% B
tR= 16.692 min
- 72 -
II. Figures
II.12 TOF mass spectrum of N-Fmoc-Asp(OtBu)-6-amio-2-cyanobenzothiazole (4)
569.2070= [M+H]+
- 73 -
II. Figures
II.13 RP-HPLC of the purified N-Fmoc-Asp(OtBu)-6-amino-2-cyanobenzothiazole (4)
50-100% B in 25 min
tR= 10.591 min
- 74 -
II. Figures
II.14 TOF mass spectrum of N-Fmoc-Asp(OtBu)-aLuc (5)
673.1882= [M+H]+
- 75 -
II. Figures
II.15 RP-HPLC profile of the N-Fmoc-Asp(OtBu)-aLuc (5)
50-100% B in 25 min
tR= 21.046 min
- 76 -
II. Figures
II.16. part 1 1H-NMR spectrum of the N-Z-Asp-Glu-Val-Asp-aLuc (6)
([D6]DMSO, 600 MHz) 10.26 (bs, 1H), 8.61 (s, 1H), 8.42 (d, J = 7.2 Hz, 1H), 8.08 (d, J =
9.0 Hz, 2H), 7.81 (bs, 1H), 7.64 (dd, J1 = 9.0 Hz, J2 = 29.4 Hz, 2H), 7.34 (s, 5H), 5.42 (t, J =
8.4 Hz, 1H), 5.02 (s, 2H), 4.69 (d, J = 7.2 Hz, 1H), 4.34 (dd, J1 = 5.4 Hz, J2 = 29.4 Hz, 2H),
4.12 (bs, 1H), 3.77 (t, J = 10.8 Hz, 1H), 3.68 (dd, J1 = 8.4 Hz, J2 = 11.4 Hz, 1H), 2.77 (bs,
1H), 2.61-2.68 (m, 2H), 2.25-2.46 (m, 3H), 1.76-1.99 (m, 2H), 0.83-0.86 (m, 7H)
- 77 -
II. Figures
II.16 part 2 1H-NMR spectrum of the N-Z-Asp-Glu-Val-Asp-aLuc (6)
([D6]DMSO, 600 MHz) 10.26 (bs, 1H), 8.61 (s, 1H), 8.42 (d, J = 7.2 Hz, 1H), 8.08 (d, J =
9.0 Hz, 2H), 7.81 (bs, 1H), 7.64 (dd, J1 = 9.0 Hz, J2 = 29.4 Hz, 2H), 7.34 (s, 5H), 5.42 (t, J =
8.4 Hz, 1H), 5.02 (s, 2H), 4.69 (d, J = 7.2 Hz, 1H), 4.34 (dd, J1 = 5.4 Hz, J2 = 29.4 Hz, 2H),
4.12 (bs, 1H), 3.77 (t, J = 10.8 Hz, 1H), 3.68 (dd, J1 = 8.4 Hz, J2 = 11.4 Hz, 1H), 2.77 (bs,
1H), 2.61-2.68 (m, 2H), 2.25-2.46 (m, 3H), 1.76-1.99 (m, 2H), 0.83-0.86 (m, 7H)
- 78 -
II. Figures
II.16 part 3 1H-NMR spectrum of the N-Z-Asp-Glu-Val-Asp-aLuc (6)
([D6]DMSO, 600 MHz) 10.26 (bs, 1H), 8.61 (s, 1H), 8.42 (d, J = 7.2 Hz, 1H), 8.08 (d, J =
9.0 Hz, 2H), 7.81 (bs, 1H), 7.64 (dd, J1 = 9.0 Hz, J2 = 29.4 Hz, 2H), 7.34 (s, 5H), 5.42 (t, J =
8.4 Hz, 1H), 5.02 (s, 2H), 4.69 (d, J = 7.2 Hz, 1H), 4.34 (dd, J1 = 5.4 Hz, J2 = 29.4 Hz, 2H),
4.12 (bs, 1H), 3.77 (t, J = 10.8 Hz, 1H), 3.68 (dd, J1 = 8.4 Hz, J2 = 11.4 Hz, 1H), 2.77 (bs,
1H), 2.61-2.68 (m, 2H), 2.25-2.46 (m, 3H), 1.76-1.99 (m, 2H), 0.83-0.86 (m, 7H)
- 79 -
II. Figures
II.17 part 1 13C-NMR spectrum of the N-Z-Asp-Glu-Val-Asp-aLuc (6)
([D6]DMSO, 150 MHz) 174.54, 172.00, 171.61, 171.38, 170.24, 159.62, 156.32, 149.14,
138.66, 137.31, 136.71, 128.83, 128.28, 128.19, 124.65, 120.28, 112.04, 78.64, 66.01, 58.21,
52.53, 51.86, 51.24, 36.77, 36.31, 35.23, 30.98, 30.52, 27.59, 19.53
- 80 -
II. Figures
II.17 part 2 13C-NMR spectrum of the N-Z-Asp-Glu-Val-Asp-aLuc (6)
([D6]DMSO, 150 MHz) 174.54, 172.00, 171.61, 171.38, 170.24, 159.62, 156.32, 149.14,
138.66, 137.31, 136.71, 128.83, 128.28, 128.19, 124.65, 120.28, 112.04, 78.64, 66.01, 58.21,
52.53, 51.86, 51.24, 36.77, 36.31, 35.23, 30.98, 30.52, 27.59, 19.53
- 81 -
II. Figures
II.18 ESI mass spectrum of the N-Z-Asp-Glu-Val-Asp-aLuc (6)
872.3= [M+H]+
- 82 -
II. Figures
II.19 RP-HPLC profile of the purified N-Z-Asp-Glu-Val-Asp-aLuc (6)
5-80% B in 25 min + 3 min up to 100% B + 5min 100% B
tR= 18.555 min
- 83 -
II. Figures
II.20 RP-HPLC profile of the resulting material at the determination of load
50-100% B in 25 min + 100% B in 5 min
tR1= 12.234 min: Fmoc-Pro-OH, tR2= 14.779 min: N-Fmoc-Pro-aLuc
tR3=15.299 min: N-Fmoc-Pro-6-aminodehydroluciferin
- 84 -
II. Figures
II.21 ESI mass spectrum of N-Fmoc-Pro-6-aminodehydroluciferin
597.1= [M+H]+
- 85 -
II. Figures
II.22 RP-HPLC profile of the N-Z-Gly-Pro-aminodehydroluciferin
5-80% B in 25 min + 3 min up to 100% B + 100% B in 3 min
tR= 21.240 min
- 86 -
II. Figures
II.23 ESI mass spectrum of the N-Z-Gly-Pro-6-aminodehydroluciferin
566.1= [M+H]+, 1131.2= [2M+H]+, 1413.6= [5M+2H]+, 1697.6= [3M+H]+
- 87 -
II. Figures
II.24 1H-NMR spectrum of N-Z-Gly-Pro-6-aminodehydroluciferin
([D6]DMSO, 500 MHz) 13.39 (s, 1H), 8.70 (s, 1H), 8.61 (s, 1H), 8.06 (d, J = 8.90 Hz, 1H),
7.64 (d, J = 8.80 Hz, 1H), 7.38 -7.29 (m, 4H), 5.03 (s, 2H), 4.48 (dd, J1 = 2.80 Hz, J2 = 7.92
Hz, 2H), 3.88 (ddd, J1 = 6.33 Hz, J2 = 17.20 Hz, J3 = 47.52 Hz, 4H), 2.22-2.12 (m, 2H), 2.05-
1.99 (m, 2H), 1.98-1.89 (m, 2H)
- 88 -
II. Figures
II.25 ESI mass spectrum of the N-Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole (7)
552.0= [M+H]+
- 89 -
II. Figures
II.26 RP-HPLC profile of the N-Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole (7)
50-100% B in 25 min + 3 min up to 100% B +100% B in 5 min
tR1= 8.973 min: Fmoc-Gly-Pro-OH
tR2= 17.868 min: Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole
- 90 -
II. Figures
II.27 1H-NMR of the N-Fmoc-Gly-Pro-aLuc (8)
([D6]DMSO, 500 MHz) 10.39 (s, 1H), 8.59 (t, J = 15.85 Hz, 1H), 8.09 (d, J = 8.98 Hz, 1H),
7.88 (d, J = 7.43 Hz, 2H), 7.71 (d, J = 7.48 Hz, 2H), 7.66-7.60 (m, 1H), 7.48 (t, J = 5.65 Hz,
1H), 7.39 (q, J1 = 7.60 Hz, J2 = 15.29 Hz, 2H), 7.30 (q, J1 = 6.78 Hz, J2 = 13.76 Hz, 2H), 5.43
(t, J = 8.98 Hz, 1H), 4.47 (dd, J1 = 2.92 Hz, J2 = 5.21 Hz, 1H), 4.29-4.25 (m, 1H), 4.21 (q, J1
= 6.68 Hz, J2 = 14.87 Hz, 1H), 3.95-3.67 (m, 4H), 3.65-3.48 (m, 4H), 2.20-2.11 (m, 1H),
2.06-1.99 (m, 1H), 1.97-1.88 (m, 2H)
- 91 -
II. Figures
II.28 13C-NMR of the N-Fmoc-Gly-Pro-aLuc (8)
([D6]DMSO, 125 MHz) 171.15, 171.05, 167.43, 164.43, 159.04, 156.55, 148.58, 143.86,
140.70, 138.38, 136.28, 127.61, 127.08, 125.27, 124.20, 120.10, 119.64, 111.52, 78.11, 65.70,
60.47, 46.62, 45.92, 42.72, 34.78, 29.28, 24.52
- 92 -
II. Figures
II.29 ESI mass spectrum of the N-Fmoc-Gly-Pro-aLuc (8)
656.0= [M+H]+, 1311.5= [2M+H]+
- 93 -
II. Figures
II.30 RP-HPLC profile of the N-Fmoc-Gly-Pro-aLuc (8)
70-100% B in 15 min
tR= 12.608 min
- 94 -
II. Figures
II.31 ESI mass spectrum of the N-Boc-6-amino-2-cyanobenzothiazole (9)
276.1= [M+H]+
- 95 -
II. Figures
II.32 RP-HPLC profile of the N-Boc-6-amino-2-cyanobenzothiazole (9)
0-100% B in 30 min + 100% B in 5 min
tR= 29.708 min
- 96 -
II. Figures
II.33 1H-NMR spectrum of the N-Boc-aLuc (10)
([D6]DMSO, 500 MHz) d 9.83 (s, 1H), 8.41 (s, 1H), 8.03 (d, J =8.93 Hz, 1H), 7.53 (d, J =
8.99 Hz, 1H), 5.42 (t, J = 9.01 Hz, 1H), 3.73 (dt, J1 =10.52 Hz, J2 = 45.0 Hz, 2H), 1.50 (s, 9H)
- 97 -
II. Figures
II.34 13C-NMR spectrum of the N-Boc-aLuc (10)
([D6]DMSO, 125 MHz) d 171.19, 164.41, 158.32, 152.75, 147.89, 139.17, 136.53, 124.17,
118.87, 109.72, 79.73, 78.14, 34.73, 28.08
- 98 -
II. Figures
II.35 ESI mass spectrum of the N-Boc-aLuc (10)
380.0= [M+H]+
- 99 -
II. Figures
II.36 Chiral HPLC profile of enantiomeric mixture of the N-Boc-6-amino-luciferin
MeOH/AcOH/TEA (100/0.1/0.1 v/v/v), isocratic elution
tR1= 5.56 min: Boc-6-amino-L-luciferin
tR2= 8.52 min: Boc-6-amino-D-luciferin
- 100 -
II. Figures
II.37 Chiral HPLC profile of the untreated N-Boc-aLuc (10)
MeOH/AcOH/TEA (100/0.1/0.1 v/v/v), isocratic elution
tR= 8.01 min: N-Boc-aLuc
- 101 -
II. Figures
II.38 The standard error of the mean (SEM) values of Figure 7A
SEM was calculated by Microsoft Excel from triplicate values obtained as described in IV.
Biological Investigation.
(N-Z-DEVD-aLuc= N-Z-Asp-Glu-Val-Asp-aLuc, 8)
- 102 -
II. Figures
II.39 Ac-915 induces the activation of caspase-3 in U87 cells (A).
Representative FL1-FSC dot plots (B) arithmetic means of percentages ± SEM of cells with
active caspase-3 show data of cells treated with Ac-915 with the indicated concentrations
(μM) ont he graph for 72 hours. Active caspase-3 was analyzed by flow cytometry as
described in IV. Biological Investigation.
- 103 -
III. Materials and methods
III. MATERIALS AND METHODS
III.1 Materials
2-chlorobenzothiazole, HATU, TCFH, DCC, D-Cys∙HCl∙H2O and triphosgene were obtained from
AK Scientific Inc. (Union City, CA, USA). Z-Asp(OtBu)-OH and COMU were sourced from
Bachem (Bubendorf, Switzerland). N-Fmoc-amino acids were purchased from Orpegen
(Heidelberg, Germany) and Bachem (Bubendorf, Switzerland). N-Fmoc-Gly-Pro-OH was
purchased from Iris Biotech GmbH (Marktredwitz, Germany), Wang resin from Rapp Polymere
GmbH (Tuebingen, Germany), TFFH from Fluorochem Ltd (Hadfield, UK). The HOBt was
sourced from Carbosynth Ltd (Compton, UK), TFA gradient grade from VWR International
(Radnor, PA, USA). The following reagents were purchased from Sigma-Aldrich (St. Louis, MO,
USA): Deoxo-Fluor Reagent, PBS, trypsin, HEPES, CHAPS, DTT, EDTA, DMEM-F12,
penicillin, streptomycin, 0.1% saponin, Endoproteinase Pro-C, DTT and Bovine Serum Albumin.
Alexa Fluor® 488 was bought from Thermo Fisher Scientific (Waltham, MA, USA). C150 and
Ac-915 were synthesized by Avidin Ltd., (Szeged, Hungary).
III.2 Chemical Methods
III.2.1 2-chloro-6-nitrobenzothiazole synthesis (1)
438 mL cc H2SO4 was cooled to 10C in a 2-litre triple-neck round-bottomed flask. 100 g (0.59
mol) 2-chlorobenzothiazole was dripped to the H2SO4 over a period of 2 hours, meanwhile the
reaction mixture was stirred vigorously and the temperature was held under 15C. 66 g (0.66 mol)
powdered KNO3 was added to the reaction mixture in small quantities in 45 minutes, the
temperature was still kept under 15C. Then the reaction mixture was allowed to warm up to room
temperature, and stirring was continued at room temperature for 2 hours. It was poured into 4 litres
of ice and water. Yellow precipitation formed, which was filtered and washed until the pH of the
filtrate became neutral. The crystalline compound was dried at room temperature, followed by its
recrystallization from EtOAc in order to get rid of 2-chloro-5-nitrobenzothiazole as the single side
product. The resulting material was a pale yellow crystal, its weight was 104.90 g (0.49 mol), yield
83%, mp 191-192C (EtOAc), (lit. mp 190-191C 28). 1H-NMR (CDCl3, 500 MHz) 8.77 (s, 1H),
8.41 (d, J= 9.0 Hz, 1H), 8.10 (d, J= 9.0 Hz, 1H) (II.1). The spectral data matched that in the
- 104 -
III. Materials and methods
literature 59, m/z (TSQ): 213.93 [M-H]- (II.2), RP-HPLC: 70-100% B in 15 min + 100% B in 5 min,
tR= 7.899 min (II.3), TLC: n-hexane/dioxane = 2:1; Rf: 0.42.
III.2.2 6-amino-2-chlorobenzothiazole synthesis (2)
25 g (0.12 mol) 2-chloro-6-nitrobenzothiazole (1) packed in a paper cup and 500 mL EtOAc, 30 g
NH4Cl (0.56 mol), 200 mL water and 20 g reduced Fe powder in a 1-litre round-bottomed flask
was put in a Soxhlet apparatus and heated under reflux for eight hours while continuously stirring
the mixture. This way, the continuous dissolution of the starting material, which has low solubility
in EtOAc, was ensured, allowing for unmonitored and unmanaged operation while we could
efficiently recycle a small amount of EtOAc to dissolve a larger amount of 2-chloro-6nitro-
benzothiazole (1), thus making the procedure more economical. In order to get rid of the remaining
water/NH4Cl/Fe-powder as lower part, the upper part EtOAc layer was decanted, and this process
was repeated twice with 100 mL EtOAc, respectively. Decantation was employed instead of using
a separatory funnel because the lower aqueous phase too viscous. We had no iron waste as in our
method no chemical transformation of the iron occurred, the iron was 100% recyclable: the iron
powder was filtered off, and then washed on a Büchner funnel with distilled water. The combined
organic phase was dried over anh Na2SO4, filtered and evaporated on rotary evaporator. The
resulting material was a yellow crystal, its weight was 18.90 g (0.10 mol), yield 88%, mp 154-156
C (EtOAc) (lit.155-157C 28). 1H-NMR ([D6]DMSO, 600 MHz ) (d, J = 8.4 Hz, 1H), 7.04 (d, J
= 2.4 Hz, 1H), 6.78 (dd, J1 = 1.8 Hz, J2 = 8.4 Hz, 1H), 5.53 (bs, 2H) (II.4), 13C-NMR ([D6]DMSO,
150 MHz) 148.24, 145.51, 142.00, 137.86, 123.13, 115.51, 104.18 (II.5) The spectral data
matched that in the literature.60 m/z (ESI): 185.0 [M+H]+ (II.6), RP-HPLC: 5-80% B in 25 min + 3
min up to 100% B + 100% B in 5 min, tR= 11.527 min (II.7), TLC: n-hexane/dioxane = 2:1; Rf:
0.76.
III.2.3 6-amino-2-cyanobenzothiazole synthesis (3)
In order to get a suspension, 6.1 g (93.0 mMol) KCN was sonicated in 400 mL DMAA for 3 x 15
minutes. The suspension was heated in an oil-bath at 98-100C under argon atmosphere and then
6.86 g (37.15 mMol) 6-amino-2-chlorobenzothiazole (2), dissolved in 20 mL DMAA, was dripped
to this reaction mixture over a period of 50 minutes. This resulting mixture was heated in an oil-
bath at 110C and stirred continuously under argon atmosphere for 12 hours. After 12 hours stirring
- 105 -
III. Materials and methods
there was still starting material in the mixture. An increased conversion from the starting ratio of
2.5:1 for KCN/6-amino-2-chlorobenzothiazole (2) to the ratio of 3.4:1 was achieved by adding 2.20
g (33.80 mMol) of KCN. This was followed by 5 hours stirring under the conditions described
above, and after that procedure the remaining amount of 6-amino-2-chlorobenzothiazole (2) was
insignificant. The reaction mixture was poured on a mixture of 200 g ice, 400 mL 1M KH2PO4 and
300 mL diethyl ether. The organic phase was separated from the aqueous phase. The latter was
extracted with 2 x 250 mL diethyl ether, then with 2 x 200 mL EtOAc. The combined organic
phases were washed with 2 x 300 mL water and 1 x 300 mL brine, dried over anh Na2SO4 and
concentrated on rotary evaporator. The resulting material was a pale brown solid, its weight was
6.4g (crude). The material was recrystallized from acetone, and the impurities were removed by
adding activated charcoal to the solution. The weight of the desired purified material was 5.09 g
(29.10 mMol), yield 78%, mp 218-219°C (EtOAc) (lit. mp 216-218C 15). 1H -NMR ([D6]DMSO,
600 MHz ) (d, J = 9.0 Hz, 1H), 7.22 (d, J = 1.8 Hz, 1H), 7.01 (dd, J1 = 1.8 Hz, J2 = 9.0 Hz, 1H),
4.40 (bs, 2H) (II.8), 13C-NMR (150 MHz, ([D6]DMSO) 150.06, 144.10, 138.75, 128.86, 125.62,
118.19, 114.71, 103.54 (II.9) The spectral data matched that in the literature. 23 m/z (ESI) 176.0
[M+H]+ (II.10), RP-HPLC: 5-80% B in 25 min + 3 min up to 100% B + 5 in 100% B, tR= 16.692
min (II.11), TLC: n-hexane/dioxane = 2:1; Rf: 0.48. The remaining KCN was reacted with KH2PO4
in order to get non-toxic KOCN.
III.2.4 N-Fmoc-Asp(OtBu)-6-amino-2-cyanobenzothiazole synthesis (4)
6.30 g (15.30 mMol, 1.5 equiv) N-Fmoc-Asp(OtBu)-OH, which was previously dried in a vacuum
desiccator, and 4.30 g (15.30 mMol, 1.5 equiv) TCFH were solved in 35 mL anh DCM. The mixture
was stirred for 60 minutes at room temperature. First 3.06 mL (18.36 mMol, 1.8 equiv) DIPEA,
then 1.79 g (10.20 mMol, 1 equiv) 6-amino-2-cyanobenzothiazole (3), which was previously dried
in a vacuum desiccator, were added. Further 200 mL dry DCM was added to get complete
dissolution of the materials. After stirring the reaction mixture overnight at room temperature, it
was transferred into a separatory funnel and washed with water (2 x 30 mL), with saturated
NaHCO3-solution (2 x 30 mL), then with water again (2 x 30 mL), and finally with brine (2 x 30
mL). It was dried over anh Na2SO4, finally concentrated on rotary evaporator. The resulting crude
material was a yellowish-brown powder, its weight was 6.17 g. RP-HPLC analysis showed a yield
- 106 -
III. Materials and methods
of 73%. m/z (TOF) 569.2070 [M+H]+ (II.12), RP-HPLC (for the purified compound): 50-100% B
in 25 min, tR= 10.591 min (II.13), TLC: EtOH/toluene 50:7.5; Rf: 0.58.
III.2.5 N-Fmoc-Asp(OtBu)-aLuc synthesis (5)
2.96 g (5.20 mMol) N-Fmoc-Asp(OtBu)-6-amino-2-cyanobenzothiazole (4) was dissolved in the
mixture of 35 mL MeOH and 20 mL THF. 1.37 g (7.80 mMol) D-cysteine∙HCl∙H2O, dissolved in
10 mL distilled water, was added to the mixture at room temperature under argon atmosphere,
while stirring continuously under pH control (starting pH: 1.67). After 20 minutes stirring at room
temperature 16 mL 5% (m/m) NaHCO3 was added dropwise over a period of one hour to the
mixture in order to release cysteine from its salt while continuously checking pH. Reaching pH
2.5, a fine, yellow solid material, N-Fmoc-Asp(OtBu)-aLuc free carboxylic acid, started to
precipitate. At pH 6.1, this material started to dissolve, and at pH 7.36, it dissolved completely.
Here then N-Fmoc-Asp(OtBu)-aLuc formed Na-salt, which dissolved under the basic conditions.
After an additional 20 minutes stirring at room temperature the organic solvent was removed under
reduced pressure. Water and MeOH forms an azeotrope, and the two solvents were therefore
removed together through the distillation. Due to the decrease in the concentration of the water,
from the remaining aqueous solution a yellow solid material, N-Fmoc-Asp(OtBu)-aLuc Na-salt,
precipitated. This, however, was just an irrelevant event during the process, as our goal was the
removal of the MeOH. The aforementioned precipitate is water soluble, so then it was dissolved
again in 20 mL water and extracted with 1 x 15 mL EtOAc in order to get rid of possible impurities.
Having dropped this solution on a mixture of ice and AcOH (adjusted to pH 3), a fine yellow
precipitate formed, N-Fmoc-Asp(OtBu)-aLuc free carboxylic acid. It was allowed to settle for 10
minutes, filtered and washed with 3 x 10 mL water, then air-dried to constant weight, which was
2.83 g (4.20 mMol), yield 81%. m/z (TOF) 673.1882 [M+H]+ (II.14), RP-HPLC: 50-100% B in 25
min, tR= 21.046 min (II.15), TLC: toluene/EtOH 50:30 saturated with water, Rf: 0.58.
III.2.6 Attachment of N-Fmoc-Asp(OtBu)-aLuc to solid support
Solid phase peptide synthesis was performed manually by using a solid phase vessel attached to a
rotating apparatus. 0.127 g (0.10 mMol, 1 equiv) p-alkoxybenzyl alcohol resin was allowed to swell
in anh DCM for 20 minutes. After the removal of the DCM, 0.202 g (0.30 mMol, 3 equiv) N-Fmoc-
Asp(OtBu)-aLuc, 0.062 g (0.30 mMol, 3 equiv) DCC, 0.041 g (0.30 mMol, 3 equiv) HOBt and
- 107 -
III. Materials and methods
0.037 g (0.10 mMol, 1 equiv) DMAP, dissolved in 10 mL anh DCM, was added to the resin. The
coupling reaction was shaken for 3 hours at room temperature. After the removal of the coupling
mixture, the resin was rinsed with DCM (3 x 10 mL), MeOH (1 x 10 mL) and then with DCM (3
x 10 mL) again. The coupling reaction was repeated with the soln of 0.067 g (0.10 mMol, 1 equiv)
N-Fmoc-Asp(OtBu)-aLuc, 0.062 g (0.30 mMol, 3 equiv) DCC, 0.041 g (0.30 mMol, 3 equiv) HOBt
and 0.037 g (0.10 mMol, 1 equiv) DMAP in 5 mL anh DCM at room temperature for 2 hours. The
resin was drained and rinsed with DCM (3 x 10 mL), MeOH (1 x 10 mL), DCM (3 x 10 mL), then
dried to constant weight.
Determination of load: 5 mg of dried loaded resin was treated with a mixture of TFA/water (500
L, with the ratio of 95:5) for 1 hour at room temperature. This was followed by the addition of
500 L water to the cocktail, which was then filtered off. 10 L from the filtrate was injected to
analytical RP-HPLC and the area of the N-Fmoc-Asp-aLuc on the resulted chromatogram was
compared with the area of 10 uL N-Fmoc-Asp-aLuc stock solution with the concentration of 1
mg/mL. The resulting load was 47.8%.
III.2.7 N-Z-Asp-Glu-Val-Asp-aLuc (6) synthesis
III.2.7.1 Fmoc deprotection
Fmoc deprotection was carried out by suspending the resin in 20% (v/v) piperidine/DMF (5 mL)
and agitating the vessel at room temperature for 2 x 10 minutes. The suspension was then filtered
and the resin was washed with DMF (3 x 5 mL), MeOH (3 x 5 mL), DMF (3 x 5 mL).
III.2.7.2 SPPS peptide coupling
N-Fmoc-Val-OH (3 equiv), DCC (3 equiv) and HOBt (3 equiv) dissolved in DMF were added to
the previously swollen and Fmoc-deprotected loaded resin (1 equiv). The resulting suspension was
agitated at room temperature for 2 hours and the resin was then rinsed with DMF (3 x 5 mL),
MeOH (3 x 5 mL), DMF (3 x 5 mL).
The same procedure was carried out with N-Fmoc-Glu(OtBu)-OH (3 equiv) and N-Z-Asp(OtBu)-
OH, (3 equiv). The presence or absence of the N-free amino group was monitored using the Kaiser
test.
- 108 -
III. Materials and methods
III.2.7.3 Cleavage of peptide from the resin
The peptide-resin was treated with a solution of TFA/water (95:5 v/v) for 2 hours at room
temperature. After the removal of the cleaving mixture, the resin was rinsed with AcN (3 x 10 mL),
MeOH (1 x 10 mL) and with AcN (3 x 10 mL) again. The resulting material is a yellow liquid,
which was lyophilized afterwards. RP-HPLC for the crude compound: 5-80% B in 25 min + 3 min
up to 100% B + 5 min in 100% B, tR= 18.483 min.
III.2.7.4 Purification of crude peptide
26 mg crude peptide was dissolved in AcOH/water (1.5 mL, with the ratio of 1:1), then filtered,
using a 0.45m nylon filter. Gradient elution was used, 0-60% eluent B in 60 minutes at a 3 mL
min-1 flow rate with detection at 220 nm. Pure fractions were collected and lyophilized to give a
pale yellow material, the weight of which was 11.4 mg (0.013 mMol).1H-NMR (600 MHz,
[D6]DMSO) 10.26 (bs, 1H), 8.61 (s, 1H), 8.42 (d, J = 7.2 Hz, 1H), 8.08 (d, J = 9.0 Hz, 2H), 7.81
(bs, 1H), 7.64 (dd, J1 = 9.0 Hz, J2 = 29.4 Hz, 2H), 7.34 (s, 5H), 5.42 (t, J = 8.4 Hz, 1H), 5.02 (s,
2H), 4.69 (d, J = 7.2 Hz, 1H), 4.34 (dd, J1 = 5.4 Hz, J2 = 29.4 Hz, 2H), 4.12 (bs, 1H), 3.77 (t, J =
10.8 Hz, 1H), 3.68 (dd, J1 = 8.4 Hz, J2 = 11.4 Hz, 1H), 2.77 (bs, 1H), 2.61-2.68 (m, 2H), 2.25-2.46
(m, 3H), 1.76-1.99 (m, 2H), 0.83-0.86 (m, 7H) (II.16 part 1, 2, 3), 13C-NMR (150 MHz,
[D6]DMSO) 174.54, 172.00, 171.61, 171.38, 170.24, 159.62, 156.32, 149.14, 138.66, 137.31,
136.71, 128.83, 128.28, 128.19, 124.65, 120.28, 112.04, 78.64, 66.01, 58.21, 52.53, 51.86, 51.24,
36.77, 36.31, 35.23, 30.98, 30.52, 27.59, 19.53 (II.17 part 1, 2), m/z (ESI) 872.3 [M+H]+ (II.18),
RP-HPLC: 5-80% B in 25 min + 3 min up to 100% B + 5 min in 100% B, tR= 18.555 min (II.19).
III.2.8 N-Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole synthesis (7)
2.03 g (5.145 mMol, 1.5 equiv) anh N-Fmoc-Gly-Pro-OH and 1.44 g (5.145 mMol, 1.5 equiv) anh
TCFH were solved in 7 mL anh DCM. The mixture was stirred for 60 minutes at room temperature.
First 1 mL (6.174 mmol, 1.8 equiv) DIPEA, then 0.600 g (3.43 mMol, 1 equiv) anh 6-amino-2-
cyanobenzothiazole (3) was added. After stirring the reaction mixture overnight at room
temperature (according to HPLC analysis the conversion was 97%), it was washed with water (2 x
7 mL), with saturated NaHCO3-solution (2 x 7 mL), then with water again (2 x 7 mL), and finally
with saturated NaCl-solution (2 x 7 mL). It was dried over sicc Na2SO4, finally concentrated in
vacuo. The resulting crude material was a pale yellow powder, its weight was 1.28 g, yield
- 109 -
III. Materials and methods
corresponding to the crude product: 68%. m/z (ESI) 552.0 [M+H]+ (II.25). RP-HPLC (for the
purified compound): 50-100% B in 25 min + 3 min up to 100% B +100% B in 5 min, tR1= 8.973
min: N-Fmoc-Gly-Pro-OH, tR2= 17.868 min: N-Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole (7),
(II.26).
III.2.9 N-Fmoc-Gly-Pro-aLuc synthesis (8)
5.512 g (0.010 mol, 1 equiv.) N-Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole (7) was dissolved
in 25 mL MeOH. 2.634 g (0.015 mol, 1.5 equiv.) D-cysteine∙HCl∙H2O, solved in 19 mL distilled
water, was added to the solution at room temperature, under argon atmosphere, then the mixture
was stirred continuously under pH control (starting pH: 2.27).
After 20 minutes’ stirring at room temperature, 30 mL, 5% (m/m) NaHCO3 was added dropwise
over a period of one hour to the mixture in order to release cysteine from its salt, while checking
pH continuously. Reaching pH 2.6, a fine, yellow solid material, N-Fmoc-Gly-Pro-aLuc free
carboxylic acid, started to precipitate. At pH 6.3, this material started to dissolve, and at pH 7.40,
it dissolved completely. Here the N-Fmoc-Gly-Pro-aLuc formed Na-salt, which dissolved under
these conditions.
After another 20 minutes’ stirring at room temperature, the organic solvent was evaporated. From
the remaining aqueous solution, a pale yellow solid material, N-Fmoc-Gly-Pro-aLuc Na-salt
precipitated partly. This aqueous mixture was extracted with 3 x 15 mL EtOAc, in order to get rid
of possible impurities. The combined organic layers were extracted with saturated NaCl solution.
Having dropped the resulting solution on a mixture of ice and cc HCl, a fine yellow precipitate, N-
Fmoc-Gly-Pro-aLuc free carboxylic acid, formed. It was allowed to settle for 10 minutes, filtered
and washed with 2 x 5 mL water, then air-dried to constant weight, which was 5.115 g (7.80 mMol),
yield corresponding to the crude product: 78%. 1H NMR (500 MHz, [D6]DMSO) δ 10.39 (s, 1H),
8.59 (t, J = 15.85 Hz, 1H), 8.09 (d, J = 8.98 Hz, 1H), 7.88 (d, J = 7.43 Hz, 2H), 7.71 (d, J = 7.48
Hz, 2H), 7.66-7.60 (m, 1H), 7.48 (t, J = 5.65 Hz, 1H), 7.39 (q, J1 = 7.60 Hz, J2 = 15.29 Hz, 2H),
7.30 (q, J1 = 6.78 Hz, J2 = 13.76 Hz, 2H), 5.43 (t, J = 8.98 Hz, 1H), 4.47 (dd, J1 = 2.92 Hz, J2 =
5.21 Hz, 1H), 4.29-4.25 (m, 1H), 4.21 (q, J1 = 6.68 Hz, J2 = 14.87 Hz, 1H), 3.95-3.67 (m, 4H),
3.65-3.48 (m, 4H), 2.20-2.11 (m, 1H), 2.06-1.99 (m, 1H), 1.97-1.88 (m, 2H) (II.27). 13C NMR (125
MHz, [D6]DMSO) δ 171.15, 171.05, 167.43, 164.43, 159.04, 156.55, 148.58, 143.86, 140.70,
138.38, 136.28, 127.61, 127.08, 125.27, 124.20, 120.10, 119.64, 111.52, 78.11, 65.70, 60.47,
- 110 -
III. Materials and methods
46.62, 45.92, 42.72, 34.78, 29.28, 24.52 (II.28). m/z (ESI) 656.0 [M+H]+ (II.29). RP-HPLC: 70-
100% B in 15 min, tR= 12.608 min (II.20). TLC: toluene/EtOH 50:30 saturated with water, Rf:
0.44.
III.2.10 Purification of crude N-Fmoc-Gly-Pro-aLuc (8)
160 mg crude peptide (45% desired material content, 72 mg) was dissolved in 1 mL DMF, then
filtered, using a 0.45m nylon filter. Gradient elution was used, 40-70% eluent B in 60 minutes at
a 4 mL min-1 flow rate with detection at 220 nm. Pure fractions were collected and lyophilized to
give a pale yellow material, the weight of which was 23 mg (0.035 mmol), yield corresponding to
the isolated pure product: 32%.
III.2.11 N-Boc-6-amino-2-cyanobenzothiazole synthesis (9)
0.81 g (4.62 mMol, 1 equiv) 6-amino-2-cyanobenzothiazole (3) was dissolved in 60 mL anh EtOAc
in a round-bottomed flask, then 2.45 mL (14.10 mMol, 3 equiv) DIPEA was added. 2.04 g (6.87
mMol, 1.5 equiv) triphosgene was added in small amounts, over a period of 30 minutes at room
temperature while vigorously stirring the solution. The mixture was stirred at 60 C for a period of
60 minutes. In the following step, the flask was put in cold water in order to cool down the solution
to room temperature. A pale-yellow intermediate, (2-cyanobenzo[d]thiazol-6-yl)carbamic chloride
precipitated. At room temperature 4.75 mL (50.10 mMol, 11 equiv) tBuOH was added to this
material, the mixture was heated again to 60 C in an oil bath, then stirred over a period of 1 hour.
During processing, the flask was first put in cold water in order to cool down the solution. In order
to neutralize the acidic solution, it was poured into a mixture of ice and 28 m/m% NaOH, then the
organic phase was separated from the aqueous phase. The latter was extracted with 3 x 30 mL
EtOAc. The combined organic phases were washed with 3 x 30 mL water and 1 x 30 mL saturated
NaCl, dried over sicc Na2SO4, filtered and concentrated on a rotary evaporator. The resulting
material was a pale brown solid, its weight was 0.995 g, yield corresponding to the crude product:
74%. m/z (ESI) 276.1 [M+H]+ (II.31). RP-HPLC: 0-100% B in 30 min + 100% B in 5 min, tR=
29.708 min (II.32). TLC: toluene/EtOH 50:7.5, Rf: 0.84.
- 111 -
III. Materials and methods
III.2.12 N-Boc-aLuc synthesis (10)
0.995 g crude N-Boc-6-amino-2-cyanobenzothiazole (9) was dissolved in the mixture of 20.5 mL
MeOH and 2.5 mL THF. 1.58 g (9.05 mmol) D-cysteine∙HCl∙H2O, dissolved in 10 mL distilled
water, was added to the mixture at room temperature under argon atmosphere, while stirring
continuously under pH control (starting pH: 0.66). After 20 minutes stirring at room temperature,
21.6 mL 5 m/m% NaHCO3 was added to the mixture dropwise over a period of 75 minutes in order
to release the cysteine from its salt, while continuously monitoring pH. Reaching pH 2.99, a fine,
yellow solid material, N-Boc-aLuc free carboxylic acid, started to precipitate. At pH 7.13, this
material started to dissolve, and at pH 7.24, it dissolved completely. Here the N-Boc-6-aLuc formed
Na-salt, which dissolved under the basic conditions. After an additional 10 minutes stirring at room
temperature the organic solvents was removed under reduced pressure. Due to the decrease in the
concentration of the water, from the remaining aqueous solution a yellow solid material, N-Boc-
aLuc Na-salt, precipitated. This, however, was an irrelevant event during the process, as our goal
was the removal of the organic solvents. The aforementioned precipitate is water soluble, so then
it was dissolved again in 20 mL water and extracted with 1 x 15 mL methyl tert-butyl ether in order
to get rid of possible impurities. Having dropped the aqueous phase on a mixture of ice and AcOH
(adjusted to pH 3.43), a fine yellow precipitate formed, N-Boc-aLuc free carboxylic acid. It was
allowed to settle for 10 minutes, filtered and washed with 3 x 10 mL water, then air-dried to
constant weight, which was 0.846 g, yield corresponding to the crude product: 85%. TLC:
toluene/ethanol 50:15 saturated with water, Rf: 0.15.
III.2.13 Purification of N-Boc-aLuc (10)
40 mg crude material (85% desired material content, 34 mg) was dissolved in 1 mL DMF, then
filtered, using a 0.45μm nylon filter. Gradient elution was used, 20-70% eluent B in 50 minutes at
a 3 mL min-1 flow rate with detection at 220 nm. Pure fractions were collected and lyophilized to
give a pale yellow material, the weight of which was 17 mg (0.045 mMol), yield corresponding to
the isolated pure product: 44%. 1H-NMR (500 MHz, [D6]DMSO) d 9.83 (s, 1H), 8.41 (s, 1H), 8.03
(d, J =8.93 Hz, 1H), 7.53 (d, J = 8.99 Hz, 1H), 5.42 (t, J = 9.01 Hz, 1H), 3.73 (dt, J1 =10.52 Hz, J2
= 45.0 Hz, 2H), 1.50 (s, 9H) (II.33). 13C-NMR (125 MHz, [D6]DMSO) d 171.19, 164.41, 158.32,
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III. Materials and methods
152.75, 147.89, 139.17, 136.53, 124.17, 118.87, 109.72, 79.73, 78.14, 34.73, 28.08 (II.34). m/z
(ESI) 380.0= [M+H]+ (II.35)
The product’s optical purity was proved with chiral chromatography the following way:
5 mL 1M Na2CO3 solution was added to the previously purified product (5 mg, 0.013 mMol) and
the mixture was stirred for 10 minutes at room temperature at pH 9 in order to get an enantiomeric
mixture. The resulting material was examined with chiral chromatography, which showed that the
L-enantiomer was eluted at 5.5 min, while the D-enantiomer was eluted at 8.5 min (II.36). Then the
untreated purified product was also chromatographed, in order to prove its optical purity. Having
found it optically pure (II.37). Its optical rotation was also measured: [𝛼]𝐷20 = +5 (c 0.250, EtOH).
III.3. Analytical methods
TLC was performed on silica gel plates 60 F254 from Merck (Darmstadt, Germany). Melting points
were determined using Büchi (Flawil, Switzerland) melting point apparatus Model B-545. pH
values were measured with a Hanna HI 8424 pH meter. Cellulose extraction thimbles were
purchased from Whatman (Maidstone, UK). Analytical reversed-phase high-performance liquid
chromatography was performed on an Agilent 1200 series separations module with diode array and
multiple wavelength detector (Waldbronn, Germany), with a Luna C18(2) 100Å column (10 µm,
250 x 4.6 mm) Phenomenex, (Torrance, CA, USA). The experiments were carried out at room
temperature with a flow rate maintained at 1.2 mL min-1 at 220 nm wavelength (mobile phases
solvent A: 0.1% TFA in Milli-Q water and solvent B: 0.1% TFA in AcN) using gradient elution.
Separation was achieved on a Shimadzu (Kyoto, Japan) semi-preparative system with a Jupiter
C18 300Å column (10 µm, 250 x 21.20 mm), also from Phenomenex (mobile phases solvent A:
0.1% TFA in Milli-Q water and solvent B: 0.1% TFA in AcN) using gradient elution. Chiral
chromatography was carried out on a Waters HPLC system consisting of an M-600 low-pressure
gradient pump, an M-996 photodiode-array detector and an Empower 2 data manager software
(Waters Chromatography, Milford, MA, USA) with a Chirobiotic T 250 x 4.6 mm ID column
(Astec, Whippany, USA) The experiments were carried out at room temperature with a flow rate
maintained at 0.8 mL min-1 at 250 nm wavelength. MeOH/AcOH/TEA (100/0.1/0.1 v/v/v) was
used as the mobile phase solvent in isocratic elution mode. Optical rotation was measured with a
Perkin-Elmer 341 polarimeter. Mass spectrometry data for the compound 1 were collected on a
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III. Materials and methods
Finnigan MAT TSQ 7000 (Waltham, MA, USA) instrument, operating with APCI in negative ion
mode, data for materials 2, 3, 6, 7, 8, 9, 10 were collected on Waters (Milford, MA, USA) SQ
Detector with electrospray ionization (ESI) in positive ion mode; data for compounds 4 and 5 were
recorded with Waters Q-TOF Premier Mass Spectrometer. 1H NMR and 13C NMR spectra were
recorded using a Bruker DR X 500 spectrometer at 600 MHz and 150 MHz, respectively in
[D6]DMSO. Chemical shifts were reported on the scale and J values were given in Hz.
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IV. Biological Investigation
IV. BIOLOGICAL INVESTIGATION
IV.1 N-Z-Asp-Glu-Val-Asp-aLuc (6) biochemical assay
Caspase-3 and the assay buffer were used from the caspase-3 inhibitor drug screening kit
(BioVision, Milpitas, CA, USA). Caspase-3 was used in ten-fold serial dilution starting from 227
mU to 22.7 μU/reaction. N-Z-Asp-Glu-Val-Asp-aLuc (6) substrate was applied in 100 μM to 1 μM
in 25 μL final reaction volume in a black plastic microtiter plate. The effect of the pan-caspase
inhibitor Z-Val-Ala-Asp-fmk was tested in equimolar ratio of N-Z-Asp-Glu-Val-Asp-aLuc (6) at
10 μM with 2.27 mU/reaction caspase-3. After 45 minutes incubation at 37°C we added 25 μL
luminescence detection reagent to each well. Luminescence was recorded as cps by a plate reader
within 5 minutes. Blank wells contained each component except caspase-3. Presented values were
blank-subtracted.
IV.2 N-Z-Asp-Glu-Val-Asp-aLuc (6) cellular assay
A549 non-small cell lung carcinoma cells were purchased from the ATCC (Manassas, VA, USA)
and U87-Luc glioblastoma cell line from Perkin Elmer (Waltham, MA, USA). Complete protease
inhibitor cocktail was from Roche Basel, Switzerland.
A549 non-small cell lung carcinoma cells (2 x 106) were plated in 60 mm dishes (Corning, NY,
USA) in DMEM-F12 media (Gibco BRL, Gaithersburg, MD, USA).. After cell attachment (24h),
the cells were treated with curcumin analogue C150 (5 μM to 1.25 μM) in order to induce apoptosis
in 5 μL final volume.64 After 24h incubation supernatant was harvested and kept on ice. Cells were
washed with PBS and trypsinized (5 minutes, 37°C). Supernatant, washing PBS and media blocked
trypsin were mixed and centrifuged down (5 minutes, 4°C, 1800 g). Lysis buffer was diluted with
distilled water (five times concentrated lysis buffer: 250 mM HEPES, pH 7.4, 25 mM CHAPS, 25
mM DTT, and 50 μL 1x concentration lysis buffer was added to the pellet, resuspended and kept
on ice for 15 minutes. Samples were centrifuged down for 10 minutes (4°C, 11000 g). Supernatant
of the lysate was harvested and kept on ice for analysis. N-Z-Asp-Glu-Val-Asp-aLuc (6) was
dissolved in DMSO at 10 mM and used in 10 μM in the assay. Assay buffer was diluted in distilled
water (ten times concentrated assay buffer: 200 mM HEPES, pH 7.4, 1% (v/v) CHAPS, 50 mM
DTT, 20 mM EDTA, 95 μL 1x concentration assay buffer containing 10 μM N-Z-Asp-Glu-Val-
Asp-aLuc (6) was measured in 96-well tissue culture plate (Corning) and 5 μL lysate was assayed
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IV. Biological Investigation
in triplicates to detect luminescence proportional to caspase-3 activity. Z-Val-Ala-Asp-fmk from
Calbiochem (San Diego, CA, USA) was used as internal control for caspase-3 inhibition. Blank
contained 5 μL assay buffer instead of the lysate. After 4 hours reaction 50 μL reaction mixture
was measured into black plastic microtiter plate and 50 μL luminescent detection reagent was
added. Luminescence was recorded as cps by a plate reader within 5 minutes. Presented values
were blank-subtracted.
IV.3 N-Fmoc-Gly-Pro-aLuc (8) assay
N-Fmoc-Gly-Pro-aLuc (8) was tested in bioluminescence-based enzyme activity assays with three
enzymes. POP/PREP and recombinant human FAP alpha were obtained from R&D Systems
(Minneapolis, MN, USA) and a bacterial non-specific endoproteinase Pro-C was from Sigma
(Budapest, Hungary). Enzymes were used at equivalent protease activity in ten-fold serial dilution
starting from 32 fmol/min/reaction to 320 pmol/min/reaction. Assay buffer for POP/PREP and
Endoproteinase Pro-C contained 25 mMol tris(hydroxymethyl)aminomethane HCl-salt pH 7.4, 250
mMol NaCl, 2.5 mMol 1,4-dithiothreitol and the assay buffer for FAP contained 50 mMol Tris∙HCl
pH 7.4, 1 M NaCl, 1 mg/mL BSA. The N-Fmoc-Gly-Pro-aLuc (8) substrate was applied in 1 μmol
to 100 μmol in 25 μL final reaction volume in a black plastic microtiter plate (Tomtec). The effect
of protease inhibition was prepared by dissolving one tablet in 2 mL POP/PREP buffer and used
in 2.5-fold dilution in each reaction with 10 μmol N-Fmoc-Gly-Pro-aLuc (8) and 32
pmol/min/reaction protease activity. After 2 hours incubation at 37°C 25 μL Luminescence
Detection Reagent was added to each well. Luminescence was recorded as cps by a plate reader
(Perkin Elmer Wallac VICTOR 1420 (Waltham)) within 5 minutes. Blank wells contained each
component except POP/PREP or recombinant human FAP enzymes. Presented values were blank-
subtracted.
IV.4 N-Z-Asp-Glu-Val-Asp-aLuc (6) in vivo assay
Male SCID mice (6 weeks old, 22–24 g body weight) were housed in sterile cages at Avidin Ltd.
The mice were fed autoclaved food and sterile water ad libitum. For inoculation, the U87-Luc cells
were trypsinized, washed and resuspended in sterile PBS. The mice were injected subcutaneously
with this suspension (3 x 106 cells in 0.2 mL), in the dorsal region, unilaterally. All operative
procedures and animal care conformed strictly to the Hungarian Council on Animal Care
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IV. Biological Investigation
guidelines. Approval provided by Head of Food Chain Safety and Animal Health of the Csongrad
County Government Office. Document number: CSI/01/126/2013; valid until 8th of January 2018.
18 days after inoculation the mice were treated with Ac-915, a lipid droplet binding thalidomide
analogue inducing oxidative stress and apoptosis in glioblastoma cells.66 Ac-915 was dissolved in
DMSO:solutol 3:1 mixture, then diluted in PBS four times and injected i.p. at a 20 mg/kg dose
except negative control mice which were injected by PBS only. Six hours after drug administration,
to monitor apoptosis induction, the mice were injected i.p., with 50 mg/kg N-Z-Asp-Glu-Val-Asp-
aLuc (6) in PBS, followed by anesthetization in 2–3% isoflurane atmosphere. 30 min after the
injection of the substrate, the mice were imaged using a charge coupled device camera in the IVIS
100 imaging instrument.
IV.5 Statistics
Statistical significance was calculated with unpaired t-test (two-tailed, homoscedastic) between
untreated and one treated sample. Each point represents the average of 3 wells ± SEM. Values are
blank-subtracted (blank = no caspase). *p<0.05; ** p<0.01; ***p<0.001.
V. RELATED ARTICLES
I
ORIGINAL RESEARCHpublished: 19 April 2018
doi: 10.3389/fchem.2018.00120
Frontiers in Chemistry | www.frontiersin.org 1 April 2018 | Volume 6 | Article 120
Edited by:
Ramon Rios,
University of Southampton,
United Kingdom
Reviewed by:
Jun Wang,
University of Arizona, United States
Bruno Linclau,
University of Southampton,
United Kingdom
*Correspondence:
Anita K. Kovács
Gábor K. Tóth
Specialty section:
This article was submitted to
Organic Chemistry,
a section of the journal
Frontiers in Chemistry
Received: 22 November 2017
Accepted: 30 March 2018
Published: 19 April 2018
Citation:
Kovács AK, Hegyes P, Szebeni GJ,
Nagy LI, Puskás LG and Tóth GK
(2018) Synthesis of
N-peptide-6-amino-D-luciferin
Conjugates. Front. Chem. 6:120.
doi: 10.3389/fchem.2018.00120
Synthesis ofN-peptide-6-amino-D-luciferinConjugates
Anita K. Kovács 1,2*, Péter Hegyes 2, Gábor J. Szebeni 2,3, Lajos I. Nagy 2,
László G. Puskás 2,3 and Gábor K. Tóth 1*
1Department of Medical Chemistry, University of Szeged, Szeged, Hungary, 2 Avidin Ltd., Szeged, Hungary, 3Department of
Genetics, Biological Research Center, Hungarian Academy of Sciences, Szeged, Hungary
A general strategy for the synthesis of N-peptide-6-amino-D-luciferin conjugates has
been developed. The applicability of the strategy was demonstrated with the preparation
of a known substrate, N-Z-Asp-Glu-Val-Asp-6-amino-D-luciferin (N-Z-DEVD-aLuc).
N-Z-DEVD-aLuc was obtained via a hybrid liquid/solid phase synthesis method,
in which the appropriately protected C-terminal amino acid was coupled to
6-amino-2-cyanobenzothiazole and the resulting conjugate was reacted with D-cysteine
in order to get the protected amino acid-6-amino-D-luciferin conjugate, which was then
attached to resin. The resulting loaded resin was used for the solid-phase synthesis
of the desired N-peptide-6-amino-D-luciferin conjugate without difficulties, which was
then attested with NMR spectroscopy and LC-MS, and successfully tested in a
bioluminescent system.
Keywords: bioluminescence, aminoluciferin, conjugate, protease activity, solid-phase peptide synthesis
INTRODUCTION
In the recent years, numerous in vivo and in vitro analytical methods have been developed based onfluorescence and bioluminescence, including immunoassays, gene expression assays, bioimaging,investigation of infectious diseases etc., (Ioka et al., 2016; Kaskova et al., 2016); plate based,high-throughput viability assays addressing the detection of protease activity is in the focus ofintensive research (Kepp et al., 2011). Protease activity can be detected with both fluorescent andbioluminescent detection systems, but with the latter the detection threshold is orders of magnitudelower than that of the fluorescent technique (O’Brien et al., 2005; Hickson et al., 2010; Gilbert andBoutros, 2016).
In the bioluminescent methods, diverse sets of luciferases and their substrates, luciferins havebeen applied in different cellular and animal models (Ioka et al., 2016; Kaskova et al., 2016).Aminoluciferin (aLuc) is a luciferin with its 6-position hydroxyl group substituted with an aminogroup. This modification allows aLuc to form amide bond with a peptide, while retaining thetransport and bioluminescent properties of luciferin, resulting in a good substrate for differentimportant proteases, which can be used for the determination of the enzymatic activity mentionedabove (White et al., 1966).
N-linked peptide-6-amino-D-luciferins can be substrates for different proteases, includingmetalloproteases, chymotrypsin-like, trypsin-like, and caspase-like proteases (O’Brien et al., 2008)They can be used for measuring protease enzyme activity in the following way: the protease enzymeto be measured recognizes the peptide part of the conjugate with the suitable peptide sequence,then cleaves the amide bond between the peptide and the aLuc, thus aLuc is released, which, in the
Kovács et al. Synthesis of N-peptide-6-amino-D-luciferin Conjugates
presence of luciferase enzyme, emits light (Figure 1). The activityof the given protease enzyme can be determined from the amountof emitted light, as the emitted light is directly proportional to theactivity of the enzyme (Leippe et al., 2011).
In the ongoing research the authors have developed andoptimized amore efficientmethod for the synthesis ofN-peptide-6-amino-D-luciferin conjugates in general, with a simpler set-up under milder conditions. N-Z-DEVD-aLuc was chosen todemonstrate the applicability of the strategy because it is acommercially available but very expensive compound, whichis used to measure the activity of caspase-3, and consequentlythe efficiency of apoptosis-inducing drugs (Talanian et al., 1997;McStay et al., 2008).
Literary OverviewThe logical method for the synthesis of N-peptide-6-amino-D-luciferin conjugates would start with the synthesis of thekey molecule, 6-amino-2-cyanobenzothiazole. So far very fewmethods have been published for this step (Takakura et al., 2011;Gryshuk et al., 2013; McCutcheon et al., 2015; Hauser et al.,2016; Hsu et al., 2016; see Supplementary Table 1). The keysteps of all these methods are the nitration, the cyanidation andthe NO2 reduction; the methods differ in the starting material,the reagents, the solvents and the order of the transformations.Having examined these methods, it can be seen that they havedisadvantages:
a. A less optimal starting material may require an extratransformation during the synthesis (see SupplementaryTable 2).
b. Certain synthesis routes require too much reagents, someof which are expensive (see Comments in SupplementaryTable 1).
c. The use of an ill-chosen solvent leads to low yield during thechlorine-cyanide exchange (see Supplementary Table 3).
Abbreviations: AcN, acetonitrile; anh, anhydrous; APCI, atmosphericpressure chemical ionization; API, atmospheric pressure ionization;CHAPS, 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate;COMU, 1-cyano-2-ethoxy-2-oxoethylidenaminooxy)dimethylamino-morpholino-carbenium hexafluorophosphate; cps, counts per seconds; DCC,dicyclohexylcarbodiimide; DCM, dichloromethane; Deoxo-Fluor Reagent,bis(2-methoxyethyl)aminosulfur trifluoride; DIPEA, N,N-diisopropylethylamine;DMAA, N,N-dimethylacetamide; DMAP, 4-dimethylaminopyridine; DMEM,Dulbecco’s modified eagle medium; DMEM-F12, Dulbecco’s modified eaglemedium nutrient mixture F-12; DMF, N,N-dimethylformamide; DMSO, dimethylsulfoxide; DTT, 1,4-dithiothreitol; EDTA, disodium ethylenediaminetetraacetatedehydrate; EtOAc, ethyl acetate; FACS, fluorescence activated cell sorter;FCS, fetal calf serum; Fmoc, 9-fluorenylmethoxycarbonyl Fmoc; HATU, 1-[bis(dimethylamino)methylene]-1H-1,2,3-triazolo[4,5-b]pyridinium 3-oxidhexafluorophosphate; HEPES, 4-(2-hydroxyethyl)piperazine-1-ethanesulfonicacid; HMPA, hexamethylphosphoric acid triamide; HOBt 1-hydroxybenzotriazole;i.p., intraperitoneally; MeOH, methanol; mp, melting point; PBS, phosphate-buffered saline; RP-HPLC, reversed-phase high-performance liquidchromatography; SEM, standard error of the mean; SPPS, solid phasepeptide synthesis; TCFH, chloro-N,N,N′ ,N′-tetramethylformamidiniumhexafluorophosphate; TFA, trifluoroacetic acid; TFFH, fluoro-N,N,N′,N′-tetramethylformamidinium hexafluorophosphate; THF, tetrahydrofuran;TLC, thin layer chromatography; Z, benzyloxycarbonyl; Z-VAD-fmk,benzyloxycarbonyl-valyl-alanyl-aspartyl-[O-methyl]- fluoromethylketone.
d. A less optimal order of the transformations results in lowyield (by transformation and, consequently, overall). With theoptimal order, however, a transformation on one functionalgroup does not result in a side reaction on the other functionalgroup (see Supplementary Table 4).
Ideally, in the next step the amino group of the 6-amino-2-cyanobenzothiazole is blocked with a protecting group. However,the low nucleophilicity of the amino group makes its protectionproblematic, resulting in very low yield. Therefore, a differentsynthesis route is needed. One method has been published(Gryshuk et al., 2011; see Supplementary Table 5). Insteadof a protecting group, the amino group of the 6-amino-2-cyanobenzothiazole is blocked with the protected C-terminalamino acid of the target sequence, and then the protecting groupis removed from the C-terminal amino acid. In the followingstep, the remaining part of the target sequence is added and theside chain protecting groups of the peptide portion are removed;finally cysteine is added. However, the route has disadvantages:
a. The mixed anhydride method for the acylation is not optimal,because it is not economical.
b. Due to the basic conditions (pH 8) during the cysteineaddition, there is a risk of racemization.
c. The resulting materials are purified twice during the route,which is unnecessary.
d. Yields were not determined, therefore it is difficult to evaluatethe synthesis route.
MATERIALS AND METHODS
Materials2-chlorobenzothiazole, HATU, TCFH, DCC, and D-Cys·HCl·H2O were obtained from AK Scientific Inc. (UnionCity, CA, USA). Z-Asp(OtBu)-OH and COMU were sourcedfrom Bachem (Bubendorf, Switzerland). Fmoc-amino acids werepurchased from Orpegen (Heidelberg, Germany) and Bachem(Bubendorf, Switzerland); Wang resin from Rapp PolymereGmbH (Tuebingen, Germany), TFFH from Fluorochem Ltd.,(Hadfield, UK). The HOBt was sourced from CarbosynthLtd (Compton, UK), trifluoroacetic acid gradient grade fromVWR International (Radnor, PA, USA). The following reagentswere purchased from Sigma-Aldrich (St. Louis, MO, USA):Deoxo-Fluor Reagent, PBS, trypsin, HEPES, CHAPS, DTT,EDTA, DMEM-F12, penicillin, streptomycin, 0.1% saponin.Alexa Fluor R© 488 was bought from Thermo Fisher Scientific(Waltham, MA, USA). N-Z-DEVD-aLuc, C150 (Nagy et al.,2015; Hackler et al., 2016), and Ac-915 (Nagy et al., 2013) weresynthesized by Avidin Ltd., (Szeged, Hungary).
Thin layer chromatography was performed on silica gel plates60 F254 from Merck (Darmstadt, Germany). Melting pointswere determined using Büchi (Flawil, Switzerland) melting pointapparatus Model B-545. pH values were measured with a HannaHI 8424 pH meter. Cellulose extraction thimbles were purchasedfrom Whatman (Maidstone, UK). Analytical reversed-phasehigh-performance liquid chromatography was performed on anAgilent 1,200 series separations module with diode array andmultiple wavelength detector (Waldbronn, Germany), with a
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Kovács et al. Synthesis of N-peptide-6-amino-D-luciferin Conjugates
FIGURE 1 | The operation of the bioluminescent system.
Luna C18(2) 100 Å column (10µm, 250× 4.6mm) Phenomenex,(Torrance, CA, USA). The experiments were carried out at roomtemperature with a flow rate maintained at 1.2ml min−1 at220 nm wavelength (mobile phases solvent A: 0.1% TFA in Milli-Q water and solvent B: 0.1% TFA in AcN) using gradient elution.Separation was achieved on a Shimadzu (Kyoto, Japan) semi-preparative system with a Jupiter C18 300 Å column (10µm,250× 21.20mm), also from Phenomenex (mobile phases solventA: 0.1% TFA in Milli-Q water and solvent B: 0.1% TFA in AcN)using gradient elution. Mass spectrometry data for the 2-chloro-6-nitrobenzothiazole (1) were collected on a Finnigan MAT TSQ7,000 (Waltham, MA, USA) instrument, operating with APCIin negative ion mode, data for materials 2, 3, 8 were collectedon Waters (Milford, MA, USA) SQ Detector with API massspectrometer in positive ion mode; data for compounds 4 and5 were recorded with Waters Q-Tof Premier Mass Spectrometer.1H NMR and 13C NMR spectra were recorded using a BrukerDR × 500 spectrometer at 600 MHz and 150 MHz, respectivelyin [D6]DMSO. Chemical shifts were reported on the δ scale andJ values were given in Hz.
Caspase-3 and the assay buffer were used from the Caspase-3inhibitor drug screening kit from BioVision (Milpitas, CA, USA).Black plastic microtiter plates were purchased from Tomtec(Budapest, Hungary), Z-VAD-fmk from Calbiochem (SanDiego, CA, USA) and Merck Millipore, (Billerica, MA, USA),luminescence detection reagent from Promega (Madison, WI,USA). 9661S caspase-3 antibody from Cell Signaling Technology(Leiden, TheNetherlands). Luminescence was recorded as countsper seconds by a plate reader Perkin ElmerWallac VICTOR 1420(Waltham, MA, USA). A549 non-small cell lung carcinoma cellswere purchased from the ATCC (Manassas, VA, USA) and U87-Luc glioblastoma cell line from Perkin Elmer (Waltham, MA,USA). Tissue culture dishes (60mm dishes. 96-well plates) werepurchased from Corning (Corning, NY, USA). DMEM and FBSwere purchased fromGibco BRL (Gaithersburg, MD, USA). MaleSCID mice (6 weeks old, 22–24 g body weight) were supplied byInnovo Ltd. (Budapest, Hungary). We used IVIS 100 imaginginstrument from Xenogen, (Alameda, CA, USA). CellQuestTM
software was bought from Becton Dickinson (Franklin Lakes, NJ,USA), GraphPad Prism R© 5 from GraphPad Software (La Jolla,CA, USA).
The mouse studies were performed according to theInstitutional and National Animal Experimentation andEthics Guidelines in possession of an ethical clearance(XXIX./3610/2012), provided by the Head of Foodchain-safety and Animal Health of the Csongrad County GovernmentOffice. Document number: CSI/01/126/2013. Valid until 8th ofJanuary 2018.
MethodsPreparation of 2-chloro-6-nitrobenzothiazole (1)Four hundred and thirty eight milliliter cc H2SO4 was cooledto 10◦C in a 2-liter triple-neck round-bottomed flask. 100 g(0.59mol) 2-chlorobenzothiazole was dripped to the sulfuricacid over a period of 2 h, meanwhile the reaction mixturewas stirred vigorously and the temperature was held under15◦C. Sixty-Six grams (0.66mol) powdered KNO3 was addedto the reaction mixture in small quantities in 45min, thetemperature was still kept under 15◦C. Then the reactionmixturewas allowed to warm up to room temperature, and stirringwas continued at room temperature for 2 h. It was pouredinto 4 liters of ice and water. Yellow precipitation formed,which was filtered and washed until the pH of the filtratebecame neutral. The crystalline compound was dried at roomtemperature, followed by its recrystallization from ethyl acetatein order to get rid of 2-chloro-5-nitrobenzothiazole as the singleside product. The resulting material was a pale yellow crystal,its weight was 104.90 g (0.49mol), yield 83%, mp 191-192◦C(EtOAc), (lit. mp 190–191◦C, Katz, 1951). 1H-NMR (CDCl3,500 MHz) δ 8.77 (s, 1H), 8.41 (d, J = 9.0Hz, 1H), 8.10(d, J = 9.0Hz, 1H) (Supplementary Figure 1). The spectraldata matched that in the literature (Shinde et al., 2006) m/z(TSQ): 213.93 [M-H]− (Supplementary Figure 2), RP-HPLC:70–100% B in 15min + 100% B in 5min, tR = 7.899min(Supplementary Figure 3), TLC: n-hexane/dioxane = 2:1;Rf: 0.42.
Preparation of 6-amino-2-chlorobenzothiazole (2)Twenty-five gram (0.12mol) 2-chloro-6-nitrobenzothiazole (1)packed in a paper cup and 500ml ethyl acetate, 30 g NH4Cl(0.56mol), 200ml water, and 20 g reduced Fe powder in a1-liter round-bottomed flask was put in a Soxhlet apparatusand heated under reflux for 8 h while continuously stirring themixture. This way, the continuous dissolution of the startingmaterial, which has low solubility in ethyl acetate, was ensured,allowing for unmonitored and unmanaged operation while wecould efficiently recycle a small amount of ethyl acetate todissolve a larger amount of 2-chloro-6nitro-benzothiazole, thusmaking the procedure more economical. In order to get ridof the remaining water/NH4Cl/Fe-powder as lower part, theupper part ethyl acetate layer was decanted, and this processwas repeated twice with 100ml ethyl acetate, respectively.Decantation was employed instead of using a separatory funnelbecause the lower aqueous phase too viscous. We had noiron waste as in our method no chemical transformation ofthe iron occurred, the iron was 100% recyclable: the ironpowder was filtered off, and then washed on a Büchner
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Kovács et al. Synthesis of N-peptide-6-amino-D-luciferin Conjugates
funnel with distilled water. The combined organic phase wasdried over anhydrous Na2SO4, filtered and evaporated onrotary evaporator. The resulting material was a yellow crystal,its weight was 18.90 g (0.10mol), yield 88%, mp 154–156◦C(EtOAc) (lit.155–157◦C, Katz, 1951). 1H NMR ([D6]DMSO,600 MHz) δ (d, J = 8.4Hz, 1H), 7.04 (d, J = 2.4Hz,1H), 6.78 (dd, J1 = 1.8Hz, J2 = 8.4Hz, 1H), 5.53 (bs,2H) (Supplementary Figure 4), 13C NMR ([D6]DMSO, 150MHz) δ 148.24, 145.51, 142.00, 137.86, 123.13, 115.51, 104.18(Supplementary Figure 5). The spectral data matched that inthe literature (Reddy et al., 2010). m/z (ESI): 185.0 [M + H]+
(Supplementary Figure 6), RP-HPLC: 5–80% B in 25min +
3min up to 100% B + 100% B in 5min, tR = 11.527min(Supplementary Figure 7), TLC: n-hexane/dioxane = 2:1;Rf: 0.76.
Preparation of 6-amino-2-cyanobenzothiazole (3)In order to get a suspension, 6.1 g (93.0 mmol) KCN wassonicated in 400ml DMAA for 3 × 15min. The suspension washeated in an oil-bath at 98–100◦C under argon atmosphere andthen 6.86 g (37.15 mmol) 6-amino-2-chlorobenzothiazole (2),dissolved in 20ml DMAA, was dripped to this reaction mixtureover a period of 50min. This resulting mixture was heatedin an oil-bath at 110◦C and stirred continuously under argonatmosphere for 12 h. After 12 h stirring there was still startingmaterial in the mixture. An increased conversion from thestarting ratio of 2.5:1 for KCN/6-amino-2-chlorobenzothiazole(2) to the ratio of 3.4:1 was achieved by adding 2.20 g (33.80mmol) of KCN. This was followed by 5 h stirring underthe conditions described above, and after that procedure theremaining amount of 6-amino-2-chlorobenzothiazole (2) wasinsignificant. The reaction mixture was poured on a mixtureof 200 g ice, 400ml 1M KH2PO4 and 300ml ether. Theorganic phase was separated from the aqueous phase. Thelatter was extracted with 2 × 250ml ether, then with 2× 200ml ethyl acetate. The combined organic phases werewashed with 2 × 300ml water and 1 × 300ml brine,dried over anhydrous Na2SO4 and concentrated on rotaryevaporator. The resulting material was a pale brown solid,its weight was 6.4 g (crude). The material was recrystallizedfrom acetone, and the impurities were removed by addingactivated charcoal to the solution. The weight of the desiredpurified material was 5.09 g (29.10 mmol), yield 78%, mp 218–219◦C (EtOAc) (lit. mp 216–218◦C, White et al., 1966). 1HNMR ([D6]DMSO, 600 MHz) δ (d, J = 9.0Hz, 1H), 7.22(d, J = 1.8Hz, 1H), 7.01 (dd, J1 = 1.8Hz, J2 = 9.0Hz,1H), 4.40 (bs, 2H) (Supplementary Figure 8), 13C NMR(150 MHz, ([D6]DMSO) δ 150.06, 144.10, 138.75, 128.86,125.62, 118.19, 114.71, 103.54 (Supplementary Figure 9). Thespectral data matched that in the literature (McCutcheonet al., 2015). m/z (ESI) 176.0 [M + H]+ (SupplementaryFigure 10), RP-HPLC: 5–80% B in 25 + 3min up to100% B + 5 in 100% B, tR = 16.692min (SupplementaryFigure 11), TLC: n-hexane/dioxane= 2:1; Rf: 0.48. The remainingKCN was reacted with KH2PO4 in order to get non-toxicKOCN.
Preparation of
Fmoc-Asp(OtBu)-6-amino-2-cyanobenzothiazole (4)6.30 g (15.30 mmol, 1.5 equiv) Fmoc-Asp(OtBu)-OH, which waspreviously dried in a vacuum desiccator, and 4.30 g (15.30 mmol,1.5 equiv) TCFH were solved in 35ml dry DCM. The mixturewas stirred for 60min at room temperature. First 3.06ml (18.36mmol, 1.8 equiv) DIPEA, then 1.79 g (10.20 mmol, 1 equiv) 6-amino-2-cyanobenzothiazole, which was previously dried in avacuum desiccator, were added. Further 200ml dry DCM wasadded to get complete dissolution of the materials. After stirringthe reaction mixture overnight at room temperature, it wastransferred into a separatory funnel and washed with water (2× 30ml), with saturated NaHCO3-solution (2 × 30ml), thenwith water again (2 × 30ml), and finally with brine (2 × 30ml).It was dried over anhydrous Na2SO4, finally concentrated onrotary evaporator. The resulting crude material was a yellowish-brown powder, its weight was 6.17 g. RP-HPLC analysis showeda yield of 73%. m/z (TOF) 569.2070 [M + H]+ (SupplementaryFigure 12), RP-HPLC (for the purified compound): 50–100% Bin 25min, tR = 10.591min (Supplementary Figure 13), TLC:ethanol (EtOH)/toluene 50:7.5; Rf: 0.58.
Synthesis of Fmoc-Asp(OtBu)-6-amino-D-luciferin (5)2.96 g (5.20 mmol) Fmoc-Asp(OtBu-)-6-amino-2-cyanobenzothiazole was dissolved in the mixture of 35mlMeOH and 20ml THF. 1.37 g (7.80 mmol) D-cysteine·HCl·H2O,dissolved in 10ml distilled water, was added to the mixtureat room temperature under argon atmosphere, while stirringcontinuously under pH control (starting pH: 1.67). After 20minstirring at room temperature 16ml 5% (m/m) NaHCO3 wasadded dropwise over a period of 1 h to the mixture in orderto release cysteine from its salt while continuously checkingpH. Reaching pH 2.5, a fine, yellow solid material, Fmoc-Asp(OtBu)-6-amino-D-luciferin free carboxylic acid, started toprecipitate. At pH 6.1, this material started to dissolve, and atpH 7.36, it dissolved completely. Here the Fmoc-Asp(OtBu)-6-amino-D-luciferin formed Na-salt, which dissolved under thebasic conditions. After an additional 20min stirring at roomtemperature the organic solvent was removed under reducedpressure. Water and methanol forms an azeotrope, and thetwo solvents were therefore removed together through thedistillation. Due to the decrease in the concentration of the water,from the remaining aqueous solution a yellow solid material,Fmoc-Asp(OtBu)-6-amino-D-luciferin Na-salt, precipitated.This, however, was just an irrelevant event during the process, asour goal was the removal of the methanol. The aforementionedprecipitate is water soluble, so then it was dissolved againin 20ml water and extracted with 1 × 15ml ethyl acetate inorder to get rid of possible impurities. Having dropped thissolution on a mixture of ice and glacial acetic acid (adjusted topH 3), a fine yellow precipitate formed, Fmoc-Asp(OtBu)-6-amino-D-luciferin free carboxylic acid. It was allowed to settlefor 10min, filtered and washed with 3 × 10ml water, thenair-dried to constant weight, which was 2.83 g (4.20 mmol),yield 81%. m/z (TOF) 673.1882 [M + H]+ (SupplementaryFigure 14), RP-HPLC: 50–100% B in 25min, tR = 21.046min
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(Supplementary Figure 15), TLC: toluene/EtOH 50:30 saturatedwith water, Rf: 0.58.
Attachment of Fmoc-Asp(OtBu)-6-amino-D-luciferin
to Solid Support (6)Solid phase peptide synthesis was performed manually by usinga solid phase vessel attached to a rotating apparatus. 0.127 g(0.10 mmol, 1 equiv) p-alkoxybenzyl alcohol resin was allowedto swell in anh DCM for 20min. After the removal of theDCM, 0.202 g (0.30 mmol, 3 equiv) Fmoc-Asp(OtBu)-amino-D-luciferin, 0.062 g (0.30 mmol, 3 equiv) DCC, 0.041 g (0.30mmol, 3 equiv) HOBt, and 0.037 g (0.10 mmol, 1 equiv) DMAP,dissolved in 10ml anh DCM, was added to the resin. Thecoupling reaction was shaken for 3 h at room temperature. Afterthe removal of the coupling mixture, the resin was rinsed withDCM (3 × 10ml), MeOH (1 × 10ml) and then with DCM (3× 10ml) again. The coupling reaction was repeated with thesoln of 0.067 g (0.10 mmol, 1 equiv) Fmoc-Asp(OtBu)-amino-D-luciferin, 0.062 g (0.30 mmol, 3 equiv) DCC, 0.041 g (0.30 mmol,3 equiv) HOBt and 0.037 g (0.10 mmol, 1 equiv) DMAP in 5mlanh DCM at room temperature for 2 h. The resin was drainedand rinsed with DCM (3 × 10ml), MeOH (1 × 10ml), DCM (3× 10ml), then dried to constant weight.
Determination of load5mg of dried loaded resin was treated with a mixture ofTFA/water (500 µl, with the ratio of 95:5) for 1 h at roomtemperature. This was followed by the addition of 500 µl waterto the cocktail, which was then filtered off. 10 µl from thefiltrate was injected to analytical RP-HPLC and the area of theFmoc-Asp-6-amino-D-luciferin on the resulted chromatogramwas compared with the area of 10 ul Fmoc-Asp-6-amino-D-luciferin stock solution with the concentration of 1 mg/ml. Theresulting load was 47.8%.
Preparation of N-Z-DEVD-aLuc (8)
Fmoc deprotectionFmoc deprotection was carried out by suspending the resin in20% (v/v) piperidine/DMF (5ml) and agitating the vessel at roomtemperature for 2× 10min. The suspension was then filtered andthe resin was washed with DMF (3 × 5ml), MeOH (3 × 5ml),DMF (3× 5ml).
SPPS peptide coupling (7)Fmoc-Val-OH (3 equiv), DCC (3 equiv), and HOBt (3 equiv)dissolved in DMF were added to the previously swollenand Fmoc-deprotected loaded resin (1 equiv). The resultingsuspension was agitated at room temperature for 2 h and the resinwas then rinsed with DMF (3 × 5ml), MeOH (3 × 5ml), DMF(3× 5ml).
The same procedure was carried out with Fmoc-Glu(OtBu)-OH (3 equiv) and Z-Asp(OtBu)-OH, (3 equiv). The presence orabsence of the Nα-free amino group was monitored using theKaiser test.
Cleavage of peptide from the resinThe peptide-resin (7) was treated with a solution of TFA/water(95:5 v/v) for 2 h at room temperature. After the removal of the
cleaving mixture, the resin was rinsed with AcN (3 × 10ml),MeOH (1× 10ml) and with AcN (3× 10ml) again. The resultingmaterial is a yellow liquid, which was lyophilized afterwards. RP-HPLC for the crude compound: 5–80% B in 25min + 3min upto 100% B + 5min in 100% B, tR = 18.483min (SupplementaryFigure 16).
Purification of crude peptide26mg crude peptide was dissolved in acetic acid/water (1.5ml,with the ratio of 1:1), then filtered, using a 0.45µm nylonfilter. Gradient elution was used, 0–60% eluent B in 60min ata 3ml min−1 flow rate with detection at 220 nm. Pure fractionswere collected and lyophilized to give a pale yellow material,the weight of which was 11.4mg (0.013 mmol). 1H NMR (600MHz, [D6]DMSO) δ 10.26 (bs, 1H), 8.61 (s, 1H), 8.42 (d,J = 7.2Hz, 1H), 8.08 (d, J = 9.0Hz, 2H), 7.81 (bs, 1H), 7.64 (dd,J1 = 9.0Hz, J2 = 29.4Hz, 2H), 7.34 (s, 5H), 5.42 (t, J = 8.4Hz,1H), 5.02 (s, 2H), 4.69 (d, J = 7.2Hz, 1H), 4.34 (dd, J1 = 5.4Hz,J2 = 29.4Hz, 2H), 4.12 (bs, 1H), 3.77 (t, J = 10.8Hz, 1H), 3.68(dd, J1 = 8.4Hz, J2 = 11.4Hz, 1H), 2.77 (bs, 1H), 2.61–2.68(m, 2H), 2.25–2.46 (m, 3H), 1.76–1.99 (m, 2H), 0.83–0.86 (m,7H) (Supplementary Figure 17 part 1,2,3), 13C NMR (150 MHz,[D6]DMSO) δ 174.54, 172.00, 171.61, 171.38, 170.24, 159.62,156.32, 149.14, 138.66, 137.31, 136.71, 128.83, 128.28, 128.19,124.65, 120.28, 112.04, 78.64, 66.01, 58.21, 52.53, 51.86, 51.24,36.77, 36.31, 35.23, 30.98, 30.52, 27.59, 19.53 (SupplementaryFigure 18 part 1,2), m/z (ESI) 872.3 [M + H]+ (Figure 2), RP-HPLC: 5–80% B in 25min + 3min up to 100% B + 5min in100% B, tR = 18.555min (Figure 3).
N-Z-DEVD-aLuc Biochemical AssayCaspase-3 and the assay buffer were used from the caspase-3inhibitor drug screening kit. Caspase-3 was used in ten-fold serialdilution starting from 227 mU to 22.7 µU/reaction. N-Z-DEVD-aLuc substrate was applied in 100µM to 1µM in 25 µl finalreaction volume in a black plastic microtiter plate. The effect ofthe pan-caspase inhibitor Z-VAD-fmk was tested in equimolarratio of N-Z-DEVD-aLuc at 10µM with 2.27 mU/reactioncaspase-3. After 45min incubation at 37◦C we added 25 µlluminescence detection reagent to each well. Luminescence wasrecorded as cps by a plate reader within 5min. Blank wellscontained each component except caspase-3. Presented values areblank-subtracted.
Cell Lines and CultureA549 cells and U87-Luc glioblastoma cells were maintainedin DMEM-F12 and DMEM cell culture media, respectively.Both type of medium were supplemented with 10% (v/v)heat-inactivated FBS, 100 units/ml penicillin and 100 mg/mlstreptomycin at 37◦C in a humidified atmosphere containing5% CO2.
N-Z-DEVD-aLuc Cellular AssayA549 non-small cell lung carcinoma cells (2 × 106) were platedin 60mm dishes in DMEM-F12 media. After cell attachment(24 h), the cells were treated with curcumin analog C150 (5µM to1.25µM) in order to induce apoptosis in 5ml final volume (Nagyet al., 2015). After 24 h incubation supernatant was harvested and
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FIGURE 2 | Mass spectrum (ESI) of the purified N-Z-DEVD-aLuc (8) 872.3 = [M+H]+.
FIGURE 3 | RP-HPLC profile of the purified N-Z-DEVD-aLuc (8), 5–80% B in 25 + 3min up to 100% B + 5min in 100% B, tR = 18.555min.
kept on ice. Cells were washed with PBS and trypsinized (5min,37◦C). Supernatant, washing PBS and media blocked trypsinwere mixed and centrifuged down (5min, 4◦C, 1,800 g). Lysis
buffer was diluted with distilled water (five times concentratedlysis buffer: 250mM HEPES, pH 7.4, 25mM CHAPS, 25mMDTT, and 50 µl 1x concentration lysis buffer was added to the
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pellet, resuspended and kept on ice for 15min. Samples werecentrifuged down for 10min (4◦C, 11,000 g). Supernatant of thelysate was harvested and kept on ice for analysis. N-Z-DEVD-aLuc was dissolved in DMSO at 10mM and used in 10µM inthe assay. Assay buffer was diluted in distilled water (ten timesconcentrated assay buffer: 200mM HEPES, pH 7.4, 1% (V/V)CHAPS, 50mM DTT, 20mM EDTA, 95 µl 1x concentrationassay buffer containing 10µM N-Z-DEVD-aLuc was measuredin 96-well tissue culture plate and 5 µl lysate was assayedin triplicates to detect luminescence proportional to caspase-3activity. Blank contained 5 µl assay buffer instead of the lysate.After 4 h reaction 50µl reactionmixture wasmeasured into blackplastic microtiter plate and 50 µl luminescent detection reagentwas added. Luminescence was recorded as cps by a plate readerwithin 5min. Presented values are blank-subtracted.
In Vivo Animal ModelMale SCID mice (6 weeks old, 22–24 g body weight) were housedin sterile cages at Avidin Ltd. The mice were fed autoclaved foodand sterile water ad libitum. For inoculation, the U87-Luc cellswere trypsinized, washed and resuspended in sterile PBS. Themice were injected subcutaneously with this suspension (3× 106
cells in 0.2ml), in the dorsal region, unilaterally. All operativeprocedures and animal care conformed strictly to the HungarianCouncil on Animal Care guidelines. (Approval provided by Headof Foodchain-safety and Animal Health of the Csongrad CountyGovernment Office. Document number: CSI/01/126/2013; validuntil 8th of January 2018.) 18 days after inoculation the micewere treated with Ac-915, a lipid droplet binding thalidomideanalog inducing oxidative stress and apoptosis in glioblastomacells (Nagy et al., 2013). Ac-915 was dissolved in DMSO:solutol3:1 mixture, then diluted in PBS four times and injected i.p. at a20 mg/kg dose except negative control mice which were injected
by PBS only. Six hours after drug administration, to monitorapoptosis induction, the mice were injected i.p., with 50 mg/kgN-Z-DEVD-aLuc in PBS, followed by anesthetization in 2–3%isoflurane atmosphere. 30min after the injection of the substrate,the mice were imaged using a charge coupled device camera inthe IVIS 100 imaging instrument.
StatisticsStatistical significance was calculated with unpaired t-test (two-tailed, homoscedastic) between untreated and one treatedsample. Each point represents the average of 3 wells ± SEM.Values are blank-subtracted (blank = no caspase). ∗p < 0.05;∗∗p < 0.01; ∗∗∗p < 0.001.
RESULTS AND DISCUSSION
The desired peptide-luciferin conjugate (N-Z-DEVD-aLuc) wasreached in an 8-step route (Figure 4, Supplementary Table 6):
nitration → reduction → chlorine-cyanide exchange →
attachment of the C-terminal amino acid of the target sequence→ cysteine addition → attachment to resin → solid-phasepeptide synthesis→ cleavage from resin.
As starting material, cheap, commercially available 2-chlorobenzothiazole was used, which was first nitrated with amixture of potassium nitrate and concentrated sulphuric acid,keeping the temperature at 0◦C (Katz, 1951). The structureof the resulting 2-chloro-6-nitrobenzothiazole (1) was attestedby 1H-NMR spectrum. The next step was the reduction ofthe nitro-group. First the mixture of ethanol/glacial aceticacid/iron powder was used (Katz, 1951). Although the reactionwas successful, the resulting by-product (iron(III) acetate)was difficult to dispose of, so this method was dismissed.When trying the reduction with tin(II) chloride/glacial acetic
FIGURE 4 | The synthetic route to N-Z-DEVD-aLuc. Reagents and conditions: (a) ccH2SO4/KNO3, 0–15◦C, 5h (b) EtOAc, NH4Cl, H2O, Fe powder, reflux, 8h (c)
KCN, DMAA, 110◦C, 12h (d) Fmoc-Asp(OtBu)-OH, TCFH, dry DCM, DIPEA, overnight, rt (e) D-Cys Hcl H2O, THF, MeOH, H2O, 5 m/m% NaHCO3, 2h, rt (f)
p-alkoxybenzyl alcohol resin, dry DCM, DCC, HOBt, DMAP, 5 h 30min (g) Fmoc -/Z-protected amino acid. DCC. HOBt, DMF, 2 h, rt; 20% (v/v) piperidine for Fmoc
deprotection, 20min, rt (h) TFA/H2O 95:5 (v/v), 2 h, rt.
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acid/concentrated hydrogen chloride, large amounts of by-product formed, in which the chlorine was split off or substitutedwith a hydroxyl group, so this method also had to be dismissed.The third possibility was the application of sodium pyrosulphite,which also turned out to be unsatisfactory due to the reductiongiving a very low yield. Using zinc/hydrogen chloride led to thesame results as with tin(II) chloride.
Finally, applying ethyl acetate, water, ammonium chloride,and iron powder system solved the problem and the reductionwas successful with a good yield. Using a Soxhlet extractorturned out to be a solvent-sparing, thus environmentally-friendlymethod and processing the obtained product was also simple: thesolution had to be decanted in order to get rid of the iron powderand then extracted.
The next step—the chlorine/nitrile exchange in the 6-amino-2-chlorobenzothiazole (2)—is the key in the production of thedesired conjugates. Six different methods had to be tried, thecommon features of which were the polar aprotic non-aqueoussolvent, the high temperature and the long reaction time (a)anh DMSO/KCN, 160◦C, 10 h; (b) anh DMSO/KCN/KI, 160◦C,10 h; (c) anh DMSO/18-crown-6/KCN, 120◦C, 8 h; (d) anhDMF/KCN, 140◦C, 12 h; (e) anh HMPA/KCN, 140◦C, 10 h; (f)f) anh DMAA/KCN/KI, 120◦C, 8 h).
The first five methods had to be dismissed due to the lowyield (15–20%). When trying DMAA, however, it turned out thatKCN is dissolved best in this solvent, resulting in relatively highyield (75–80%) This means that the success of the chlorine/nitrileexchange depends on the rate of KCN dissolution.
An Fmoc-protected amino acid (Fmoc-Asp(OtBu)-OH) wascoupled to the 6-amino-2-cyanobenzothiazole (3). As, due tothe deactivated amino group, the amide bond could not beformed with the usual coupling reagent, DCC, a much moreactivating coupling agent was necessary. Different agents weretested in different quantities: COMU (El-Faham and Albericio,2010; Takakura et al., 2011; Chantell et al., 2012), HATU (El-Faham et al., 2010), Deoxo-Fluor Reagent (El-Faham et al., 2010),TFFH (Kangani et al., 2006), and TCFH (Carpino et al., 1996), allwith a ratio of 1:1.5 and 1:3. The best yield (97%) was obtainedwith 1.5 equivalents of TCFH (Table 1). Other than the quantityof the different coupling reagents, all other conditions (solvent,reaction time, temperature etc.) were kept the same. Although
TABLE 1 | Coupling agents and yields.
Coupling agent Quantity Yield (%)
COMU 1.5 equiv 0
COMU 3.0 equiv 0
HATU 1.5 equiv 7
HATU 3.0 equiv 8
Deoxo-fluor reagent 1.5 equiv 48
Deoxo-fluor reagent 3.0 equiv 38
TFFH 1.5 equiv 59
TFFH 3.0 equiv 51
TCFH 1.5 equiv 97
TCFH 3.0 equiv 72
it was not checked with chiral chromatography at this point,it became obvious following the achiral chromatography afterthe cysteine addition that there was no racemization, because ifthere had been, during either this or the previous step, we wouldhave seen diastereomers. As the achiral chromatography after thecysteine addition was indispensable anyway, we could save therather complicated chiral chromatography one step earlier.
During the addition of D-cysteine (Tulla-Puche et al.,2008) to the resulting conjugate (Fmoc-Asp(OtBu)-6-amino-2-cyanobenzothiazole, (4), the amino acid-heterocycle conjugatewas dissolved in THF andMeOH, then D-cysteine hydrochloridemonohydrate was added. The resulting compound was dissolvedin water, and then the cysteine was released from its salt withNaHCO3. During the reaction (about 25min) the pH of thesolution was kept between 7.3-7.4 by the addition of NaHCO3
aqueous solution, monitoring the process with a pH-meterand the addition was carried out under argon atmosphere. Bythis way, the desired amino acid-6-amino-D-luciferin conjugate,Fmoc-Asp(OtBu)-6-amino-D-luciferin (5) was obtained.
During the next step this conjugate was attached to resin (6).Two types of resins were tested: 2-chlorotrityl chloride and p-alkoxybenzyl alcohol (Wang resin). Loading was checked in bothcases: with 2-chlorotrityl chloride resin it was 30%, while withWang resin it was 50%, so we decided to use the latter.
Classical solid phase peptide synthesis was carried out: thepeptide chain was built with Fmoc strategy. However, the N-terminal amino acid was always Z-protected, as this protectinggroup gives higher biological stability to the peptide. Theobtained peptide-aLuc conjugate was removed from the resinwith the mixture of TFA/water (95:5 v/v); finally, the resultingmaterial was purified by preparative HPLC.
The material—N-Z-DEVD-aLuc (7)—was successfully testedin a bioluminescent system. It has been published that bothcaspase-3 and caspase-7 digest DEVD sequence, but caspase-3has six time higher DEVD digestion activity (Talanian et al., 1997;McStay et al., 2008) so we tested N-Z-DEVD-aLuc by the activityof caspase-3 in vitro (Figure 5) and caspase-3 in vivo (Figure 6).The purity of the peptide is demonstrated in SupplementaryFigure 19. The biological relevance of our N-Z-DEVD-aLucsubstrate was confirmed in a biochemical reaction using a serialdilution of recombinant caspase-3 from 227 mU/reaction to22.7 µU/reaction. In order to verify that our N-Z-DEVD-aLucis a real substrate for caspase-3, not only the enzyme but alsothe N-Z-DEVD-aLuc substrate was titrated in a concentrationrange from 100 to 1µM. The recorded luminescence waslinearly proportional with the growing enzyme activity andincreased amount of the N-Z-DEVD-aLuc substrate showingmaximum cps at 227 mU caspase-3 and 100µM N-Z-DEVD-aLuc (Figure 5A, Supplementary Figure 20) Moreover, theluminescence signal was completely abolished by the applicationof equimolar pan-caspase inhibitor Z-VAD-fmk in the reactionof 2.27 mU caspase-3 and 10µM N-Z-DEVD-aLuc (Ion et al.,2006; Figure 5B). We further verified the applicability of our N-Z-DEVD-aLuc substrate to detect cellular apoptotic cell deathcaused by a drug candidate molecule. The curcumin analog C150induces caspase-3 activation (Szebeni et al., 2017; SupplementaryFigure 21) and apoptosis of A549 human non-small cell lung
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FIGURE 5 | Luminescence is proportional to caspase activity and N-Z- DEVD-aLuc concentration. (A) Recombinant human caspase-3 (227 mU to 22.7 µU) and
N-Z-DEVD-aLuc (100 to 1µM) were titrated and assayed for 45min. (B) The effect of the pan-caspase inhibitor Z-VAD-fmk was tested in equimolar ratio of
N-Z-DEVD-aLuc at 10µM with 2.27 mU/reaction caspase-3. (C) Caspase-3 and -7 activation induced by the curcumin analog C150 (5–1.25µM) on A549 cells was
detected by N-Z-DEVD-aLuc, control corresponds to untreated sample. The results are shown as arithmetic mean values of three samples ± SEM. Anyhow, SEM
values are too small to be visible on the logarithmic scale of Figure 5A. ***p < 0.001.
carcinoma cells (Nagy et al., 2015; Hackler et al., 2016) and wecould detect the activation of caspase-3 by N-Z-DEVD-aLuc viabioluminescence (Figure 5C).
To measure apoptosis directly in animals, an opticalimaging experiment was performed in vivo, administrating N-Z-DEVD-aLuc to SCID mice (previously inoculated with thestably expressing luciferase cell line U87-Luc) that had beentreated with chemotherapeutics previously. We used Ac-915,a lipid droplet binding thalidomide analog inducing caspase-3activation (Supplementary Figure 22) and oxidative stress andapoptosis in different cancer cells (Nagy et al., 2013). Ac-915enhanced the bioluminescent signal already at 6 h. Significantlyfewer signals were detected from control mouse having noAc-915 treatment, but injected with only N-Z-DEVD-aLucsubstrate, which represents the basal level of apoptosis. However,the limitation of the widespread applicability of the luciferinconjugated peptides in vivo is that luciferase enzyme activityis indispensable, therefore luciferase transgenic mouse or cellsshould be used in these studies.
CONCLUSION
A general strategy for the synthesis of N-peptide-6-amino-D-luciferin conjugates has been developed. The strategy is based ona newly established sequence of different transformations:
nitration → reduction → chlorine-cyanide exchange →
attachment of the C-terminal amino acid of the target sequence(variable, depending on the protease to bemeasured)→ cysteine
FIGURE 6 | In vivo test of N-Z-DEVD-aLuc. N-Z-DEVD-aLuc (100 mg/kg, i.p.)
was administered to all SCID mice previously inoculated with U87-Luc
glioblastoma cells (middle). Apoptosis was induced by Ac-915 in all mice
except negative controls administered by PBS (left). Aminoluciferin was used
as positive control (right).
addition → attachment to resin → solid-phase peptidesynthesis (variable, depending on the protease to be measured)→ cleavage from resin.
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The cornerstone of N-peptide-6-amino-D-luciferin conjugatesynthesis is the availability of 6-amino-2-cyanobenzothiazole inlarge quantities. Although the used transformations (nitration,NO2 reduction and cyanidation) are well-known in the literature,our combination of these transformations, the equipment andthe solvents make it possible to prepare this material in largerquantities than the published strategies; the key of the methodis the chlorine-cyano group exchange, the success of whichdepends on the solvent. Using this larger quantity of 6-amino-2-cyanobenzothiazole, we preparedN-Z-DEVD-aLuc with Fmocsolid phase peptide synthesis. The material has already beensuccessfully used in in vivo optical imaging experiments.
The fact that in step 4 and 7 any amino acid can be usedmeans that our method provides a practical and scalable way forpreparation of other N-peptide-6-amino-D-luciferin conjugatesas well, which compounds have a crucial role in the developmentof plate based, high-throughput viability assays.
AUTHOR CONTRIBUTIONS
The project was conceived by LP, GT designed and coordinatedthe research. AK and PH chemically synthesized and analyzed the
materials, GS performed in vitro assays. LN performed in vivoexperiments. AK, GS, LP, and GT analyzed and compiled the dataand co-wrote the manuscript. The final manuscript was read andapproved by all the authors.
FUNDING
This research was supported by the GINOP-2.3.2-15-2016-00030 grant. GS was supported by János Bolyai ResearchScholarship of the Hungarian Academy of Sciences. (no. BO/00139/17/8).
ACKNOWLEDGMENTS
We would like to thank Anasztázia Hetényi for the NMRspectra.
SUPPLEMENTARY MATERIAL
The Supplementary Material for this article can be foundonline at: https://www.frontiersin.org/articles/10.3389/fchem.2018.00120/full#supplementary-material
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Conflict of Interest Statement: The authors declare that the research wasconducted in the absence of any commercial or financial relationships that couldbe construed as a potential conflict of interest.
The reviewer, BL, and handling Editor declared their shared affiliation.
Copyright © 2018 Kovács, Hegyes, Szebeni, Nagy, Puskás and Tóth. This is an open-
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provided the original author(s) and the copyright owner are credited and that the
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International Journal of Peptide Research and Therapeutics https://doi.org/10.1007/s10989-018-9768-8
Synthesis of N-Peptide-6-Amino-d-Luciferin Conjugates with Optimized Fragment Condensation Strategy
Anita K. Kovács1,2 · Péter Hegyes2 · Gábor J. Szebeni3 · Krisztián Bogár4 · László G. Puskás2,3 · Gábor K. Tóth1
Accepted: 19 September 2018 © Springer Nature B.V. 2018
AbstractThe synthesis of peptide-luciferin conjugates has a pivotal role in the development of bioluminescent detection systems that are based on the determination of protease enzyme activity. This work describes the optimized synthesis of an N-peptide-6-amino-d-luciferin conjugate (Fmoc-Gly-Pro-6-amino-d-luciferin) with a simple fragment condensation method in adequate yields. Fmoc-Gly-Pro-6-amino-d-luciferin was produced from a previously synthesized Fmoc-Gly-Pro-OH and also previ-ously synthesized 6-amino-2-cyanobenzothiazole with an optimized method, to which conjugate cysteine was added in an also improved way. The resulting conjugate was successfully used in a bioluminescent system, in vitro, demonstrating the applicability of the method.
Graphical Abstract
Keywords Bioluminescence · Protease activity · Aminoluciferin · Conjugate · Fragment condensation
Electronic supplementary material The online version of this article (https ://doi.org/10.1007/s1098 9-018-9768-8) contains supplementary material, which is available to authorized users.
* Anita K. Kovács [email protected]
* Gábor K. Tóth [email protected]
1 Department of Medical Chemistry, University of Szeged, Szeged 6720, Dóm tér 8., Hungary
2 Avidin Ltd, Szeged 6726, Alsó Kikötő sor 11/D., Hungary3 Biological Research Center, Hungarian Academy
of Sciences, Szeged 6726, Temesvári krt. 62., Hungary4 Institute of Pharmaceutical Analysis, University of Szeged,
Szeged 6720, Somogyi u. 4., Hungary
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Introduction
Bioluminescent detection systems, used for in vivo and in vitro analytical methods, have been in the spotlight of research in the past decades (Jiang et al. 2018; Xu et al. 2016; Sadikot and Timothy 2005; Chollet and Ribault 2012; Sato et al. 2004). The advantage of these sys-tems over fluorescent systems lies in their superior sen-sitivity and easy handling (De Saint-Hubert et al. 2012; Hu et al. 2012). The most ubiquitous enzyme-substrate system in bioimaging is the American firefly (Photinus pyralis) luciferin-luciferase system (Presiado et al. 2012; Zhang et al. 2012). Substituting this luciferin’s 6-position hydroxyl group with an amino group, the resulting ami-noluciferin (aLuc) can form amide bond with a peptide, while retaining the transport and bioluminescent proper-ties of the original substrate, resulting in a good substrate for different important proteases, which can be used for the determination of the enzymatic activity (White et al. 1966).
Earlier this year a general synthesis method for N-pep-tide-6-amino-d-luciferin conjugates, via a hybrid liquid/solid phase method, was published (Kovács et al. 2018). The applicability of the strategy was demonstrated with the preparation of a known substrate (O’Brian et al. 2005; Hickson et al. 2010), N-Z-Asp-Glu-Val-Asp-6-amino-d-lu-ciferin (N-Z-DEVD-aLuc, Z: benzyloxycarbonyl) used to measure the activity of caspase-3, and consequently the efficiency of apoptosis-inducing drugs. Our goal was to use the same strategy to produce N-Z-Gly-Pro-6-amino-d-luciferin (N-Z-GP-aLuc), which can be used to measure the activity of other protease enzymes, namely Fibroblast activation protein alpha (FAP) and Prolyl Oligopeptidase (POP/PREP), two prolyl-specific serine proteases, the lev-els of which are elevated in many cancers and may have roles in promoting angiogenesis and in immunotolerant tumour microenvironment (Christiansen et al. 2013).
Literary Background
Synthesis routes of peptide-6-amino-d-luciferin conju-gates have been published five times. The backgrounds were worked out by Geiger and Miska (1991), who developed four methods (phospho-azo and mixed anhy-dride methods, both with both 6-amino-2-cyanoben-zothiazole and carboxyl protected 6-amino-d-luciferin as starting material) and produced 13 different conju-gates. The mixed anhydride/6-amino-2-cyanobenzo-thiazole method was modified in a 2003 Promega pat-ent (O’Brian et al. 2003), and by Gryshuk et al. (2011). O’Brian et al. (2005) followed a different path, when
6-amino-2-cyanobenzothiazole was coupled with a pro-tected peptide with the help of DCC and HOBt. Kovács et al. (2018) synthetized a conjugate with a different, liq-uid/solid phase synthesis method with better yields than the other methods (unfortunately, in some cases yields and conversion rates were not determined in the literature and the cited patents, also, HPLC, MS and NMR analysis is incomplete or missing (Tables S1–S4)).
Unsuccessful Attempt
Our original plan was to synthesize N-Z-GP-aLuc, apply-ing the above-mentioned 2018 method (Kovács et al. 2018). First the key molecule, 6-amino-2-cyanobenzothiazole (1) was produced (Kovács et al. 2018) which was then coupled to Fmoc-Pro-OH (Fmoc: 9-fluorenylmethoxycarbonyl). The resulting protected amino acid-heterocycle conjugate (Fmoc-Pro-6-amino-2-cyanobenzothiazole, 2, Figs. S1, S2) was reacted with d-cysteine. The structure of the resulting Fmoc-Pro-6-amino-d-luciferin was attested with 1H-NMR (Fig. S3) and 13C-NMR Fig. S4), LC-MS analysis was also carried out (Figs. S5, S6). Then the protected amino acid-aminoluciferin conjugate was attached to p-alkoxybenzyl alcohol resin. However, attaching the protected amino acid-aminoluciferin conjugate to solid support, the loading was only 50%. This meant that we had a significant loss of the conjugate, even though some of it can be regained with dif-ferent purification methods and reused during further resin attachment. In order to reach higher load, instead of 3 h, the coupling reaction mixture was shaken for 6 h. The determi-nation of load showed that no improvement was achieved in loading and, according to the resulting material’s RP-HPLC profile (Fig. S7) and the mass spectrum (MS) (Fig. S8), 20% of the coupled material was dehydrogenated among the con-ditions mentioned above. As we were planning to purify the final, completed product, the synthetizing process was not abandoned. The product on the resin was Fmoc-deprotected, which was followed by coupling Z-protected glycine to the proline, and the resulting conjugate was cleaved from the resin (Kovács et al. 2018).
The RP-HPLC profile of the product (Fig. S9) showed a homogeneous material, but, according to the mass spectrum (Fig. S10), it was not the expected N-Z-GP-aLuc, but a fully dehydrogenated conjugate, N-Z-Gly-Pro-6-aminodehydrolu-ciferin. This was also attested by its 1H-NMR-spectrum (Fig. S11), on which the α-proton of the 2-thiazoline ring was not detectable; however, an olefin proton was, as proof of dehy-drogenation. The driving force behind this dehydrogenation was the aromatization of the 2-thiazoline ring, which led to its transformation into a thiazole ring (Fig. 1). Since this reaction did not occur earlier either, it might have been the result of the longer exposure to the basic conditions.
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As dehydroluciferin is a very efficient inhibitor of lucif-erase (Ciuffreda et al. 2013; Fontes et al. 1997), it is not suitable for the above-mentioned measurement of enzymatic activity.
Therefore, our goal was to find a method that is more reli-able than the hybrid liquid/solid phase synthesis method, a synthesis route that prevents the side reactions mentioned above. The problem was solved with returning to the frag-ment-condensation method, which is used to avoid problems occurring during stepwise solid phase synthesis (Nyfeler 1994). However, we had to make modifications to achieve better results than the standard method (O’Brian et al. 2005; Geiger and Miska 1991; O’Brian et al. 2003; Gryshuk et al. 2011).
Results and Discussion
The desired peptide-luciferin conjugate (N-Fmoc-GP-aLuc) was reached in a 2-step route:
(a) attachment of the target peptide sequence to 6-amino-2-cyanobenzothiazole → (b) cysteine addition (Fig. 2, Table S5):
The optimized synthesis route of the key molecule and the modifications of the two steps make a significant improvement over the standard method.
Fig. 1 The unsuccessful synthesis route to produce the desired N-Z-Gly-Pro-6-amino-d-luciferin
Fig. 2 The 2-step synthetic route to N-Fmoc-GP-aLuc (3). Reagents and conditions: a Fmoc-Gly-Pro-OH, TCFH, dry DCM, DIPEA, overnight, rt, yield 68% b d-Cys∙HCl∙H2O, MeOH, H2O, 5 m/m% NaHCO3, 2 h, rt, yield 78%
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Synthesis of 6‑Amino‑2‑Cyanobenzothiazole (1)
We started with the synthesis of the key molecule, 6-amino-2-cyanobenzothiazole (1) with an improved method (Kovács et al. 2018): commercially available 2-chlorobenzothiazole was nitrated with a mixture of cc H2SO4 and KNO3, at 0 °C (Katz 1951). The structure of the resulting 2-chloro-6-ni-trobenzothiazole was attested by 1H-NMR spectrum (83% yield corresponding to the isolated pure product). In the next step the nitro group was reduced with ethyl acetate/water/ammonium chloride/iron powder in a Soxhlet extractor with a good yield (88%, corresponding to the crude product). The chlorine/nitrile exchange in the 6-amino-2-chlorobenzothi-azole was carried out in N,N-dimethylacetamide (DMAA), a polar aprotic non-aqueous solvent, with KCN, at high temperature (110 °C) in 12 h, resulting in relatively high yield (78%, corresponding to the crude product). During procession the remaining KCN was reacted with KH2PO4, keeping pH above 7 to avoid the production of HCN, then first FeSO4 was added, forming K4[Fe(CN)6], then Fe(III) salt was added, forming insoluble Berlin blue, which can be filtered from the solution. The product was purified with recrystallization (Kovács et al. 2018).
Synthesis of Fmoc‑Gly‑Pro‑6‑Amino‑2‑Cyanobenzothiazole (2)
A suitably protected, commercially purchased peptide, Fmoc-Gly-Pro-OH, was coupled with the key molecule, 6-amino-2-cyanobenzothiazole (1). (As during the syn-thesis only a dipeptide was coupled to the 6-amino-2-cy-anobenzothiazole (1), it was reasonable to purchase a ready material, rather than synthesize and purify one. In case of longer peptides, solid phase peptide synthesis can be used.) Due to the deactivated amino group of the 6-amino-2-cy-anobenzothiazole (1), the amide bond could not be formed with the usual coupling reagents; therefore, a more powerful coupling agent (Carpino et al. 1996) was necessary. Excel-lent conversion (97%) of the 6-amino-2-cyanobenzothiazole was obtained with 1.5 equivalents of chloro-N,N,N′,N′-tetramethylformamidinium hexafluorophosphate (TCFH) (Kovács et al. 2018). Obtained yield, corresponding to the crude product: 68%. (Figs. S12, S13).
With this process, we could avoid the extremely long cou-pling time of the standard mixed anhydride method (O’Brian et al. 2003; Gryshuk et al. 2011) and reached adequate conversion/yield.
Synthesis of Fmoc‑Gly‑Pro‑6‑Amino‑d‑Luciferin (3)
The peptide-heterocycle conjugate (Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole, 2) was dissolved in methanol (MeOH), then d-cysteine hydrochloride monohydrate was
added. The resulting substance was dissolved in water and the cysteine was released from its salt with NaHCO3. During the reaction (about 25 min) the pH of the solution was kept between 7.3 and 7.4 with the addition of NaHCO3 aque-ous solution, the process was continuously monitored with a pH-meter, under argon atmosphere. The Fmoc-protection of the the N-terminal amino-group of the peptide was kept up because it gave higher biological stability to the conju-gate. The structure of the resulting conjugate was attested with 1H-NMR (Fig. S14), 13C-NMR (Fig. S15) and LC-MS (Figs. S16, S17).
This method is also an improvement over the standard practice (O’Brian et al. 2005; Geiger and Miska 1991; O’Brian et al. 2003; Gryshuk et al. 2011) as the window between pH 7.3–7.4 a, rules out racemization b, ensures the release of the cysteine from its salt.
Analysis of Fmoc‑Gly‑Pro‑6‑Amino‑d‑Luciferin (3) in Enzyme Activity Assays
The product (3) was tested in bioluminescent-based enzyme activity assays. The substrate specificity of N-Fmoc-GP-aLuc was measured with two human proteases that are involved in cancer, POP/PREP and FAP, and with a bacte-rial non-specific endoproteinase Pro-C. All three enzymes accepted the substrate and liberated aminoluciferin as a product resulting in increased luminescence signal (Fig. 3). Enzymatic degradation was confirmed with protease inhib-itor, which completely abolished bioluminescent signal increase. Our novel substrate, therefore, could be used in different biochemical assays.
Materials and Methods
Materials
TCFH and d-Cys·HCl·H2O were obtained from AK Scien-tific Inc. (Union City, CA, USA). Fmoc-Gly-Pro-OH was purchased from Iris Biotech GmbH (Marktredwitz, Ger-many). Trifluoroacetic acid (TFA) gradient grade came from VWR International (Radnor, PA, USA). POP/PREP and recombinant human FAP alpha were obtained from R&D Systems (Minneapolis, MN, USA). Endoproteinase Pro-C, DTT and Bovine Serum Albumin (BSA) were purchased from Sigma–Aldrich (St. Louis, MO, USA), black plastic microtiter plates were from Tomtec (Budapest, Hungary). Complete protease inhibitor cocktail was from Roche Basel, Switzerland and Luminescence Detection Reagent was from Promega (Madison, WI, USA).
TLC was performed on silica gel plates 60 F254 from Merck (Darmstadt, Germany). pH values were measured with a Hanna HI 8424 pH meter. Analytical reversed-phase
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high-performance liquid chromatography (RP-HPLC) was performed on an Agilent 1200 series separations module with diode array and multiple wavelength detector (Wald-bronn, Germany), with a Luna C18(2) 100 Å column (10 µm, 250 × 4.6 mm) Phenomenex, (Torrance, CA, USA). The experiments were carried out at room temperature (rt) with a flow rate maintained at 1.2 mL min−1 at 220 nm wave-length (mobile phases solvent A: 0.1% TFA in Milli-Q water and solvent B: 0.1% TFA in acetonitrile (AcN)) using gradi-ent elution. Separation was achieved on a Shimadzu (Kyoto, Japan) semi-preparative system with a Jupiter C18 300 Å column (10 µm, 250 × 21.20 mm), also from Phenomenex (mobile phases solvent A: 0.1% TFA in Milli-Q water and solvent B: 0.1% TFA in AcN) using gradient elution. Mass spectrometry data were collected on Waters (Milford, MA, USA) SQ Detector with atmospheric pressure ionization (API) mass spectrometer in positive ion mode; 1H NMR and 13C NMR spectra were recorded using a Bruker DR X 500 spectrometer at 600 MHz and 150 MHz, in deuterated dime-thyl sulfoxide ([D6]DMSO). Chemical shifts were reported on the δ scale and J values were given in Hz.
Methods
Synthesis of Fmoc-Gly-Pro-6-Amino-2-Cyanobenzothiazole (2)
2.03 g (5.145 mmol, 1.5 equiv) anhydrous (anh) Fmoc-Gly-Pro-OH and 1.44 g (5.145 mmol, 1.5 equiv) anh TCFH were solved in 7 mL anh dichloromethane (DCM). The
mixture was stirred for 60 min at room temperature. First 1 mL (6.174 mmol, 1.8 equiv) N,N-diisopropylethylamine (DIPEA), then 0.600 g (3.43 mmol, 1 equiv) anh 6-amino-2-cyanobenzothiazole (1) was added. After stirring the reaction mixture overnight at room temperature (according to HPLC analysis the conversion was 97%), it was washed with water (2 × 7 mL), with saturated NaHCO3-solution (2 × 7 mL), then with water again (2 × 7 mL), and finally with saturated NaCl-solution (2 × 7 mL). It was dried over sicc Na2SO4, finally concentrated in vacuo. The resulting crude material was a pale yellow powder, its weight was 1.28 g, yield corresponding to the crude product: 68%. m/z [M + H]+ calcd for C30H25N5O4S 551.62, found 552.0 (Fig. S12). RP-HPLC (for the purified compound): 50–100% B in 25 min + 3 min up to 100% B + 100% B in 5 min, tR1 = 8.973 min: Fmoc-Gly-Pro-OH, tR2 = 17.868 min: Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole (Fig. S13).
Synthesis of Fmoc-Gly-Pro-6-Amino-d-Luciferin (3)
5.512 g (0.010 mol, 1 equiv.) Fmoc-Gly-Pro-6-amino-2-cyanobenzothiazole (2) was dissolved in 25 mL MeOH. 2.634 g (0.015 mol, 1.5 equiv.) d-cysteine∙HCl∙H2O, solved in 19 mL distilled water, was added to the solution at room temperature, under argon atmosphere, then the mixture was stirred continuously under pH control (starting pH: 2.27).
After 20 min’ stirring at room temperature, 30 mL, 5% (m/m) NaHCO3 was added dropwise over a period of 1 h to the mixture in order to release cysteine from its salt, while checking pH continuously. Reaching pH 2.6, a fine, yellow
Fig. 3 Luminescence is proportional to protease activity and N-Fmoc-GP-aLuc concentration. Different amount of a POP/PREP, b FAP and c Endoproteinase Pro-C proteases were titrated and assayed with 1–100 µmol N-Fmoc-GP-aLuc for 2 h. (d–f) The effect of protease inhibition was tested using the Complete protease inhibi-
tor cocktail, in each reaction with 10 µmol N-Fmoc-GP-aLuc and 32 pmol/min/reaction protease activity. Each point represents the average of 3 wells ± SD. Values are blank-subtracted (blank = no pro-tease). *p < 0.05; **p < 0.01; ***p < 0.001
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solid material, Fmoc-Gly-Pro-6-amino-d-luciferin free car-boxylic acid, started to precipitate. At pH 6.3, this material started to dissolve, and at pH 7.40, it dissolved completely. Here the Fmoc-Gly-Pro-6-amino-d-luciferin formed Na-salt, which dissolved under these conditions.
After another 20 min’ stirring at room temperature, the organic solvent was evaporated. From the remaining aque-ous solution, a pale yellow solid material, Fmoc-Gly-Pro-6-amino-d-luciferin Na-salt precipitated partly. This aque-ous mixture was extracted with 3 × 15 mL ethyl acetate, in order to get rid of possible impurities. The combined organic layers were extracted with saturated NaCl solution. Hav-ing dropped the resulting solution on a mixture of ice and cc HCl, a fine yellow precipitate, Fmoc-Gly-Pro-6-amino-d-luciferin free carboxylic acid, formed. It was allowed to settle for 10 min, filtered and washed with 2 × 5 mL water, then air-dried to constant weight, which was 5.115 g (7.80 mmol), yield corresponding to the crude product: 78%. 1H NMR (500 MHz, [D6]DMSO) δ 10.39 (s, 1H), 8.59 (t, J = 15.85 Hz, 1H), 8.09 (d, J = 8.98 Hz, 1H), 7.88 (d, J = 7.43 Hz, 2H), 7.71 (d, J = 7.48 Hz, 2H), 7.66–7.60 (m, 1H), 7.48 (t, J = 5.65 Hz, 1H), 7.39 (q, J1 = 7.60 Hz, J2 = 15.29 Hz, 2H), 7.30 (q, J1 = 6.78 Hz, J2 = 13.76 Hz, 2H), 5.43 (t, J = 8.98 Hz, 1H), 4.47 (dd, J1 = 2.92 Hz, J2 = 5.21 Hz, 1H), 4.29–4.25 (m, 1H), 4.21 (q, J1 = 6.68 Hz, J2 = 14.87 Hz, 1H), 3.95–3.67 (m, 4H), 3.65–3.48 (m, 4H), 2.20–2.11 (m, 1H), 2.06–1.99 (m, 1H), 1.97–1.88 (m, 2H) (Fig. S14). 13C NMR (125 MHz, [D6]DMSO) δ 171.15, 171.05, 167.43, 164.43, 159.04, 156.55, 148.58, 143.86, 140.70, 138.38, 136.28, 127.61, 127.08, 125.27, 124.20, 120.10, 119.64, 111.52, 78.11, 65.70, 60.47, 46.62, 45.92, 42.72, 34.78, 29.28, 24.52 (Figure S15). m/z [M + H]+ calcd for C33H29N5O6S2 655.74 found 656.0 (Figure S16). RP-HPLC: 70–100% B in 15 min, tR= 12.608 min. TLC: tolu-ene/EtOH 50:30 saturated with water, Rf: 0.44.
Purification of Crude Fmoc-Gly-Pro-6-Amino-d-Luciferin (3)
160 mg crude peptide (45% desired material content, 72 mg) was dissolved in 1 mL N,N-dimethylformamide (DMF), then filtered, using a 0.45∝ m nylon filter. Gradient elution was used, 40–70% eluent B in 60 min at a 4 mL min−1 flow rate with detection at 220 nm. Pure fractions were collected and lyophilized to give a pale yellow material, the weight of which was 23 mg (0.035 mmol), yield corresponding to the isolated pure product: 32%.
Fmoc-Gly-Pro-aLuc Assay
The following proteases were used in the assay: recom-binant human POP/PREP, recombinant human FAP and Endoproteinase Pro-C at equivalent protease activ-ity in tenfold serial dilution starting from 32 fmol/min/
reaction to 320 pmol/min/reaction. Assay buffer for POP/PREP and Endoproteinase Pro-C contained 25 mmol tris(hydroxymethyl)aminomethane HCl-salt (Tris∙HCl) pH 7.4, 250 mmol NaCl, 2.5 mmol 1,4-dithiothreitol (DTT) and the assay buffer for FAP contained 50 mmol Tris∙HCl pH 7.4, 1 M NaCl, 1 mg/mL BSA. The N-Fmoc-GP-aLuc substrate was applied in 1 µmol to 100 µmol in 25 µL final reaction volume in a black plastic microtiter plate. The effect of protease inhibition (Complete protease inhibitor cocktail) was prepared by dissolving one tablet in 2 mL POP/PREP buffer and used in 2.5-fold dilution in each reaction with 10 µmol N-Fmoc-GP-aLuc and 32 pmol/min/reaction protease activity. After 2 h incubation at 37 °C 25 µL Luminescence Detection Reagent was added to each well. Luminescence was recorded within 5 min. The blank wells contained each component except proteases. Pre-sented values are blank-subtracted.
Statistics
Statistical significance was calculated by unpaired t-test (two-tailed, homoscedastic) between untreated and inhibi-tor containing samples.
Conclusion
We have developed an improved route for the synthesis of N-peptid-6-amino-d-luciferin conjugates. The method is more reliable than the standard practice as the preparation of one of the building blocks and two operations have been improved, which has led to better yields and significantly faster production time. The produced N-Fmoc-GP-aLuc was successfully used to measure FAP and POP/PREP enzyme activity in vitro.
This optimized method provides a practical and scalable way for the preparation of other N-peptide-6-amino-d-lucif-erin conjugates as well.
Author Contributions Conceptualization: László G. Puskás, Investiga-tion: Anita K. Kovács, Péter Hegyes, Gábor J. Szebeni, NMR analysis: Krisztián Bogár, Writing - original draft, review & editing: Anita K. Kovács, Supervision: Gábor K. Tóth.
Funding This work was partly supported by the following Grants: GINOP-2.3.2-15-2016-00030 and GINOP-2.3.2-15-2016-00001 from the National Research, Development and Innovation Office (NKFI), Hungary. Gábor J. Szebeni was supported by János Bolyai Research Scholarship of the Hungarian Academy of Sciences (BO/00139/17/8).
Compliance with Ethical Standards
Conflict of interest The authors declare no conflict of interest.
International Journal of Peptide Research and Therapeutics
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