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Vaccine 28 (2010) 35403547
Contents lists available at ScienceDirect
Vaccine
j o u r n a l h o m e p a g e : w w w . e l s e v i e r . c o m / l o c a t e / v a c c i n e
Production and efficacy of an Aeromonas hydrophila recombinant S-layer proteinvaccine for fish
Saravanane Poobalane a,, Kim D. Thompson a, Lszl Ard b, Noel Verjan c, Hyun-Ja Han c,Galina Jeney b, Ikuo Hirono c, Takashi Aoki c, Alexandra Adams a
a Institute of Aquaculture, University of Stirling, Stirling, FK9 4LA, UKb Research Institute for Fisheries, Aquaculture and Irrigation, Anna liget 8, H-5540 Szarvas, Hungaryc Laboratory of Genome Science, Graduate School of Marine Science and Technology, Tokyo University of Marine Science and Technology,
Konan 4-5-7, Minato, Tokyo 108-8477, Japan
a r t i c l e i n f o
Article history:
Received 25 November 2009
Received in revised form 6 March 2010
Accepted 8 March 2010
Available online 20 March 2010
Keywords:
Aeromonas hydrophila
Recombinant S-layer protein vaccine
Efficacy testing
Common carp
a b s t r a c t
A recombinant protein for the S-layer protein of Aeromonas hydrophila was produced and its ability to
protect common carp Cyprinus carpio L. against six virulent isolates of A. hydrophila was assessed. A
group of 120 carp(3040 g) were vaccinated intra-peritoneally with 0.1ml of adjuvanted vaccine (30gprotein per fish). Another group of 120 carp were injected with 0.1 ml of PBS-adjuvant mixture to serve
as controls. Twenty fish from each group were challenged with each one of six virulent isolates of A.
hydrophila 35 days post-vaccination. The fish were maintained in 12 separate tanks before terminating
the experiment at 16 days post-challenge. The relative percentage survival (RPS) for the six isolates of
A. hydrophila ranged from 56 to 87%. The difference in survival rate of fish challenged with four of the
isolates was statistically significant in vaccinated fish compared to control fish, when analysed using a
Chi-square test. The results of the study suggest that the recombinant S-layer protein of A. hydrophila
could be usefulas a vaccine antigento protect fish againstdifferent isolates of this pathogenic bacterium.
2010 Elsevier Ltd. All rights reserved.
1. Introduction
Aeromonas hydrophila is an important fish pathogen in aqua-
culture systems, and millions of dollars are estimated to be lost
per annum due to the diseases caused by this bacterium [1]. The
pathogen is responsible for causing a number of different diseases
including motile Aeromonas septicaemia [2]. The symptoms of A.
hydrophila infections include swelling of tissues, dropsy, red sores,
necrosis, ulceration and haemorrhagic septicaemia [3,4], and the
pathogen canaffect a variety of fishspeciesincluding commoncarp
[3], cat fish [5], tilapia [6], eel [7] and goldfish [8].
The use of vaccines in the aquaculture industry hasbeen impor-tant in reducing economic losses which occur as a result of disease
[9,10]and in thereduction in use of antibiotics[11]. Anumberofdif-
ferent types of vaccines have been developed against A. hydrophila
for use in fish, such as whole cell (WC) [12,13], outer membrane
protein (OMP) [14], extracellular products (ECPs), lipopolysaccha-
ride (LPS) preparations [15] and also biofilms [16]. Although these
different preparations have provided varying degrees of protec-
Corresponding author. Tel.: +44 1786467994; fax: +44 1786472133.
E-mail address: [email protected] (S. Poobalane).
tion in fish, there is still no commercial vaccine available for A.
hydrophila [1]. This could be due to an inability of these vaccines
to cross-protect against different isolates ofA. hydrophila. This bac-
terium is very heterogeneous in nature (both biochemically and
serologically), and this has been one of the greatest obstacles in
developing an effective vaccine against A. hydrophila [17]. It might
be possible to overcome this problem if a common antigen(s) could
be identified among different isolates of A. hydrophila that could
serve as a vaccine candidate(s) [13].
Proteomics combined with Western blotting (i.e. immunopro-
teomics) is a useful tool for identifying proteins of interest for
vaccine development [18]. Separationand characterisation of com-plex mixtures of proteins by two-dimensional sodium dodecyl
sulphate-polyacrylamide gel electrophoresis (2D SDS-PAGE) pro-
vides information about the expression of proteins by bacterial
pathogens [19]. Further analysis by Western blotting using serum
from infected fish, or from fish which have recovered from the dis-
ease, allows identification of antigens recognised by the immune
system of the infectedhost [19]. Together,these twotechniques can
help identify potential candidates for vaccine development [20].
Although it is possible to identify a variety of immunogenic anti-
gens on the bacterium using this method, the antigen must also be
protective against a wide range of A. hydrophila isolates in order
0264-410X/$ see front matter 2010 Elsevier Ltd. All rights reserved.
doi:10.1016/j.vaccine.2010.03.011
http://www.sciencedirect.com/science/journal/0264410Xhttp://www.elsevier.com/locate/vaccinemailto:[email protected]://localhost/var/www/apps/conversion/tmp/scratch_10/dx.doi.org/10.1016/j.vaccine.2010.03.011http://localhost/var/www/apps/conversion/tmp/scratch_10/dx.doi.org/10.1016/j.vaccine.2010.03.011mailto:[email protected]://www.elsevier.com/locate/vaccinehttp://www.sciencedirect.com/science/journal/0264410X7/30/2019 1-s2.0-S0264410X10003476-main
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S. Poobalane et al. / Vaccine28 (2010) 35403547 3541
to be considered as a suitable vaccine candidate [21]. It is possible
to evaluate the level of protection elicited by a target antigen by
vaccinating thefish with the antigen andthen subsequentlyexper-
imentally infecting the fish with live pathogen and establishing the
level of survival in vaccinated fish [22].
Another important factor in vaccine development is the abil-
ity to produce sufficient quantities of the protective proteins
for commercialisation of the vaccine. Researchers are now using
recombinant DNA technology to develop protein vaccines because
it provides a means of economically producing sufficient quanti-
ties of the immunoprotective antigen [23,24]. Such vaccines have
enormous potential in the aquaculture industry as they provide
an alternative approach to traditional formalin-killed WC vaccines,
which are not always efficacious, and they are safe compared to
live attenuated bacteria used in vaccines which can possibly revert
to becoming pathogenic [25]. Recombinant protein vaccines have
been reported to confer protection against a variety of human and
animal pathogens (Yersinia pestis [26], rabies virus [27], Plasmod-
ium falciparum [28]) including fish (Ichthyophthirius multifiliis [29],Piscirickettsia salmonis [23]).
We previously examined the differential expression of cellular
proteins (WC and OMP) and ECPs of six isolates (four virulent and
two avirulent) ofA. hydrophila, cultured either in vitro in tryptone
soy broth or in vivo in dialysis tubing implanted within the peri-toneal cavity of common carp [30]. Using 1D SDS-PAGE of WC,
OMP and ECP preparations and 2D SDS-PAGE of the WC prepara-
tion, unique and up-regulated proteins were observed in bacteria
grown in vivo. In a subsequent study, common carp were infected
withthesamesixisolatesofA. hydrophila inordertoobtainantibod-
ies elicited by the fish against proteins of various bacterial isolates
expressed in vivo during infection [31]. The immune-recognition
pattern of these antibodies against WC, OMP and ECP preparations
of the six isolates grown either in vitro or in vivo was compared
by the Western blot analysis. A common antigen found on all the
isolates at around 50 kDa, was identified as an S-layer protein by
MALDI TOFmass spectrometry. Theaim of thepresent study was to
produce the S-layer protein of A. hydrophila by recombinant tech-
nology to ensure sufficient quantity of the protein for a vaccinationtrial to assess the level of protection elicited by the recombinant
protein, and to verify if this recombinant protein was capable of
cross-protecting against different isolates ofA. hydrophila.
2. Materials and methods
2.1. Recombinant S-layer protein production
Recombinant S-layer protein of A. hydrophila was produced in
order to have sufficient protein for a vaccination trial.
2.1.1. Extraction of DNA from A. hydrophila
A. hydrophila isolate T4 was grown overnight according toPoobalane et al. [30] and centrifuged at 5000gfor 5min at 4 C.
The pellets were resuspended in 567l Tris ethylenediaminete-traacetic acid (EDTA) (TE) buffer (10 mM TrisCl and 1 mM EDTA,
pH 8), 30l of 10% (w/v) SDS and 3l of 20mgml1 proteinase K.The bacteria were thoroughly mixed and incubated for 1 h at 37 C
before adding 100l of 5 M NaCl. The pellets were mixed againand incubated for 10minat 65C after adding 80l cetyltrimethy-lammonium bromide (CTAB) in NaCl solution (10%, v/v, CTAB in
0.7 M NaCl). The DNA was extracted from the sample withan equal
volume of chloroform: isoamyl alcohol (24:1 ratio) (780 l). Thetube was inverted a couple of times and centrifuged at 5000gfor
5minat4 C. The aqueous phase was transferred to a new tube and
extractedwith phenol: chloroform: isoamyl alcohol (25:24:1ratio).
The contents of the tube was thoroughly mixed and centrifuged
at 5000gfor 10 min at 2022 C before transferring the aqueous
phase to a new tube. The DNA was precipitated with an equal vol-
umeof isopropanol.The contents of the tube were then thoroughly
mixed by inverting the tube a couple of times and centrifuged at
5000g for 10min at 4 C. The precipitate was washed with 70%
ethanol by centrifuging at 5000g for 10min at 4 C. The super-
natant was removed and the pellets were briefly dried at 2022 C
for 10 min. The pellets were resuspended in 100l TE buffer andstored at 20 C until used.
2.1.2. Polymerase chain reaction (PCR) of A. hydrophila S-layer
protein gene
Specific primers were designed to amplify the S-layer pro-
tein gene based on the DNA sequence data for the S-layer
protein of A. hydrophila published by Thomas and Trust [32].
Restriction sites NcoI and BglII were added to the forward (5
ccatgggagttaatctggacactggtgc 3) and reverse (3 gacttgtggtacttgcg-
taagtctaga 5) primers, respectively, to assist its cloning into the
expression vector pQE 60 (Qiagen, Tokyo, Japan). The PCR mixture,
composed of genomic DNA (3l containing 50 ng), the forwardand reverse primers (2l containing 200 pmol), dNTP (5l con-taining 200M), MgCl2 buffer (4l containing 1 mM), Taq DNApolymerase (0.5l) and TE buffer, was prepared for a 40l reac-
tion. The DNA was amplified with 32 cycles using the followingconditions: preheating to 95 C for 5 min, denaturation at 95 C for
30 s, annealing at 55 C for 30 s, elongation at 72 C for 1 min and a
final elongation step at 72 C for 5min.
2.1.3. Cloning of the S-layer protein gene
The PCR products were run on a 1% agarose gel for 30min
at 100V. The target bands were identified under ultraviolet
(UV) light, excised from the gel and cut into small pieces. The
DNA was extracted from the gel using a DNA purification kit
(GE Life Science, Buckinghamshire, UK). Digestion of the PCR
products and vector (pQE 60) were performed using restriction
enzymes NcoI and BglII. The digested PCR products and the vec-
tor were run on an agarose gel and purified as described above,
before ligating them together using ligation high, T4 DNA ligaseenzyme (Cosmo Bio, Tokyo, Japan). The pQE 60 vector, carrying
the amplified S-layer protein gene of A. hydrophila, was trans-
formed into Escherichia coli, M15 (Quiagen, Tokyo, Japan). The
bacteria were incubated in SOC medium (SigmaAldrich, Dorset,
UK) at 37 C for 1 h with vigorous shaking. The pellets were
centrifuged at 2000g for 3min and resuspended in 2 yeast
tryptone broth (2YTB). The cells were grown on Luria Bertani
(LB)agar plates containing ampicillin (100g ml1) andkanamycin(25g ml1).
2.1.4. Expression and purification of the recombinant S-layer
protein in E. coli
The positive clones containing the S-layer protein gene, were
inoculated into LB broth containing antibiotics (ampicillin andkanamycin), and incubated overnight at 37 C. The culture was
transferred into fresh LB broth (1:9 ratio, v/v) containing antibi-
otics and cultured at 37 C with vigorous shaking. The absorbance
of the culture was measured every hour at 600 nm until it reached
0.6, after which, the culture was induced to express the recombi-
nant protein by adding 1mM isopropyl--thiogalactoside (IPTG).After growing the bacteria for 4 h, the bacterial pellets were har-
vested at 4000gfor 30minat 4 C. The pellets were resuspended
in phosphate buffered saline (PBS: 0.02M phosphate and 0.15M
NaCl) and stored at 80 C.
The bacterial pellet was subjected to three rounds of freeze-
thawing before resuspendingin sterile PBS and sonicating 60 times
at 150 W for 20 s with 10 s intervals. After sonication, the soluble
(native protein) and insoluble materials (inclusion bodies) were
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3542 S. Poobalane et al. / Vaccine28 (2010) 35403547
separated by centrifugation at 4000g for 30min at 4 C. Inclu-
sion bodies were solubilised in denaturing solution (8 M urea, 0.1%
(w/v) SDS and 100 mM TrisHCl) with 10 mM imidazole. The pQE
60 vector used for cloning the S-layer protein gene has 6 repeated
sets of DNA coding for amino acid, histidine, which will also be
expressed by attaching with the protein encodes for the insert. The
histidine-tag was used to assist in separating the S-layer protein
from the other proteins of the E. coli. Nickel beads (Ni Sepharose 6
fast flow, Amersham Bioscience) were added to the inclusion bod-
ies to bind the histidine-tag present in theproteins. Thebeadswere
poured into a column (XK 16/20 empty lab scale column, Amer-
sham BioScience) and washed three times with 20mM wash buffer
(Imidazole 20 mM, NaH2PO4 50 mM and NaCl 300 mM) pH 8. The
proteins were elutedfrom thebeads with elution buffer (imidazole
250mM, NaH2 P04 50 mM and NaCl 300mM) pH 8.5. The beads
in the column were washed again before loading the soluble pro-
tein mixed with imidazole (10 mM), and the protein was eluted
after washing as described above. The eluted protein was concen-
trated using a Millipore membrane (10,000 MW cut-off, Amicon).
The concentration of the protein was measured using a Pierce pro-
tein determination kit (Pierce ScientificCo., Rockford, USA) after
dialysing the protein overnight in sterile PBS using seamless cellu-
lose tubing (12,000MW cut-off, Union Carbide Corporation, Tokyo,
Japan).The WC preparation of recombinant E. coli with and without
IPTG induction, and the recombinant S-layer protein preparation
were separated on a 12% SDS-PAGE and Western blot was then
performed according to Poobalane [31] with modifications using
an anti-histidine-tag antibody, which can bind to the histidine-
tag attached to the S-layer protein. Briefly, after electroblotting
the gels onto a nitrocellulose membrane (ATTO Co., Tokyo, Japan),
the membranes were blocked with casein, and incubated with an
anti-histidine-tag antibody (GE life science, Buckinghamshire, UK)
diluted 1:6000 in TBS for 1 h. Mouse anti-rabbit conjugated to IgG-
alkaline phosphatase (Promega, Madison WI, USA) was used at a
concentration of 1:7500 and incubated for 1 h. The reaction was
developed using 5-bromo-4-chloro-3-indolylphosphate/nitro blue
tetrazolium (BCIP-NBT) alkaline phosphatase substrate (1 tabletdissolved in 10 ml of double distilled water, SigmaAldrich Co, St.
Louis, MO, USA).
2.2. Vaccination of common carp with recombinant S-layer
protein
2.2.1. Vaccination
The recombinant S-layer protein of A. hydrophila, prepared
above, was diluted in PBS and mixed with montanide adjuvant
(Intervet Schering-Plough Aquaculture, Saffron Walden, UK) at
a ratio of 30:70 (v/v) to give a final antigen concentration of
300g ml1. PBS was mixed with the adjuvant at the same ratioas the antigen to serve as a negative control. Mixing was car-
ried out by vortexing until the antigen was emulsified, and itwas then stored overnight at 4 C to ensure that the emulsion
was stable. Common carp, weighing 3040g, were obtained from
the indoor fish culture system of Research Institute for Fisheries,
Aquaculture and Irrigation, Hungary. The fish were maintained
in a fibreglass tank in an indoor aquarium at a water tempera-
ture of 2022 C. The tanks were supplied with water, which was
passed through a biological recirculatory system and ultraviolet
(UV) irradiation. The fish were anaesthetised according to Poobal-
ane et al. [30] before start vaccinating them. One hundred and
twenty common carp (3040 g) were vaccinated intra-peritoneally
(IP) with 0.1 ml of the vaccine preparation, and another 120 fish
were injected with the PBS-adjuvant mixture. The right-hand side
pectoral fins of control fish were clipped for identification. All the
fish were maintained for 35 days in 1 m
1 m (diameter
depth)
tanks before challenging them with six different isolates of A.
hydrophila.
2.2.2. Challenge studies
Six virulentisolatesofA. hydrophila (T4,98140,98141,Hh, B2/12
and Vds) were passaged twice through common carp (3040g)
to determine their lethal dose 50% (LD50) value in carp. Initially,
the concentration of the bacteria was adjusted to an OD of 1.0 at
610nm,equivalent to 1108 bacteria ml
1, before preparingthreedifferent doses of bacteria, at 2107, 5107 and 2.5107 ml1.
The fish were injected IP with 0.1ml of these suspensions and
placed in a separate glass tank for each strain. The concentration of
bacteria was adjusted accordingly and injected into a newgroup of
fish to obtain the LD50 value for all isolates.
Twenty vaccinated and 20 control fish were challenged IP with
each isolate after anaesthetising the fish according to Poobal-
ane et al. [30]. The concentrations of the bacteria used in the
challenge were 1 108, 2107, 2107, 5107, 7.5106 and
2107 bacteriaml1 for T4, 98140, 98141, Hh, B2/12 and Vds,
respectively. All 40 fish within each group were placed in sepa-
rate glass tanks (90cm length47 cm height40 cm depth) and
the water temperature was maintained at 2022 C. The dead
fish from the tanks were removed three times a day and a kid-ney swab taken was streaked onto TSA plates. At the end of
the trial, Day 16 post-challenge, 6 fish surviving the challenge
(3 vaccinated and 3 control fish for each bacterial strain) were
killed by overdosing with benzocaine (0.01% w/v). The appear-
ance of the internal organs of the killed fish was examined before
sampling their kidney. Gram staining and serum agglutination
using rabbit anti-A. hydrophila polyclonal antibodies diluted in PBS
1/100 (v/v) were used to confirm the presence of A. hydrophila
to ensure the mortalities were specific to the infection caused
by the bacteria. The relative percentage survival (RPS) was calcu-
lated to determine the efficacy of the vaccine using the following
formula [33].
RPS = 1 (% vaccinated mortality)
(% control mortality) 100
2.2.3. Statistical analysis
The results obtained were analysed statistically using Chi-
square test for survival, comparing the mortality of vaccinated fish
with the control group fish after challenging with bacteria.
3. Results
3.1. Production of the recombinant S-layer protein of A.
hydrophila isolate
The amplification of the gene encoding the S-layer protein fromA. hydrophila isolate T4 was successfully achieved, indicated by the
production of the1353bp PCRproducton a 1%agarose gelas shown
in Fig. 1 (lanes 2 and 3), while successful ligation of the digested S-
layerproteingeneintothe pQE60vectorwasconfirmed bythe band
obtained at around 4.8kb (Fig. 1 (lane 4)). Expression of an abun-
dant S-layer protein (45.5 kDa) was confirmed in the IPTG induced
E. coli, transformed with the pQE60 vector containing the S-layer
gene insert, by SDS-PAGE analysis (Fig. 2a). The protein also gave
a strong positive reaction in Western blot with the anti-histidine
antibody (Fig. 2b). A final yield of 15 mg of purified protein was
recovered from a 1 litre E. coli culture, and it was confirmed as S-
layer protein by SDS-PAGE analysis (Fig. 3a) and Western blotting
using serum produced against a WC preparation ofA. hydrophila T4
isolate (raised in common carp) (Fig. 3b).
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S. Poobalane et al. / Vaccine28 (2010) 35403547 3543
Fig. 1. Amplification of the S-layer gene of A. hydrophila isolate T4 shown on a 1%
agarose gel. Lanes: (1) standard markers; (2) S-layer protein gene; (3) purified S-
layer protein gene; (4) pQE60 vector carrying S-layer protein gene.
3.2. Efficacy of recombinant S-layer protein as a vaccine against
A. hydrophila in common carp
3.2.1. Standardisation of the challenge dose of A. hydrophila
All six strains ofA. hydrophila, T4, 98140, 98141, Hh, B2/12 and
Vds, were passaged two times through common carp and the bac-
teria were successfully recovered on each passage. During the first
passage, no mortalities occurred in any of the fish, while most fishdied when passaging bacteria were used with the exception of fish
passed with isolate T4. The LD50 values obtained for each strain are
presentedinTable1. ThehighestLD50 value obtainedwas for isolate
T4 with a dose of 1108 bacteriaml1, while the lowest dose was
Fig. 2. Expressionof S-layer protein ofA. hydrophila with E. coli WC protein. (a)12%SDS-PAGEstained withCoomassieblue and(b) Westernblot ofproteinusing ananti-
histidine-tag antibody. Lanes: (1) standard protein marker; (2) WC preparation of
recombinant E. coli without IPTG induction; (3) WC preparation of recombinant E.
coli with IPTG induction showing S-layer protein.
obtained with isolate B2/12 with a value of 7.5106 bacteriaml1.
An LD50 value of 2107 bacteriaml1 was obtained for isolates
98140, 98141and Vds, whilean LD50 valueof 5107 bacteriaml1
was obtained for Hh.
3.2.2. Vaccination of common carp with the recombinant S-layer
protein of A. hydrophila
The cumulative mortality that occurred in the control fish after
challenging with the different isolates ofA. hydrophila ranged from
40 to 75%, while the mortalities of vaccinated fish ranged between10 and 20% (Table 1). The mortalities ceased in the control groups
by Day 8 post-challenge, whereas no mortality was found after
Day 5 post-challenge in the vaccinated groups (Fig. 4). A higher
percentage of mortalities were recorded in control fish challenged
Fig. 3. Recombinant S-layer protein of A. hydrophila purified from E. coli. (a) 12% SDS-PAGE stained with Coomassie blue and (b) Western blot against anti-A. hydrophila T4
isolate antibody from carp. Lanes: (1) standard protein marker; (2) WC protein of A. hydrophila; (3 and 4) protein separated from insoluble fractions of recombinant E. coli;
(5 and 6) protein separated from soluble fractions of recombinant E. coli.
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3544 S. Poobalane et al. / Vaccine28 (2010) 35403547
Fig. 4. Cumulative percentagemortalityof carp vaccinated with recombinant S-layer protein and challengedwithA. hydrophila isolates.Different letters indicate a statistical
difference between vaccinated and unvaccinated fish.
with isolate T4 than in fish challenged with the other isolates of A.
hydrophila (Fig. 4a). The relative percentage survival (RPS) value of
fish challenged with isolate T4 was found to be the highest com-pared with the fish challenged with other A. hydrophila isolates,
while the lowest RPS value was obtained in fish challenged with
isolate B2/12 (Table 1). Statistically, survival after challenging with
isolates T4, 98140, 98141 and Hh was significantly higher in vac-
cinated fish compared to control fish, while levels of survival were
not statistically different between vaccinated and control fish chal-
lenged with isolates B2/12 and Vds (Table 1).
A. hydrophila was recovered from all kidney swabs taken from
dead fish over the course of the trial. In contrast, no A. hydrophila
was cultured from kidney swabs taken from fish surviving at the
endof experimentalchallenge exceptswabs of one fishin the vacci-
nated group challenged with isolate 98140, and another fish in the
control group challenged with isolate 98141, with a few colonies
obtained from both fish.
4. Discussion
A. hydrophila infections have been difficult to treat in aquacul-ture systems due to the resistance of this pathogen to a number
of different antibiotics [34]. Researchers have, therefore, examined
the effects of different types of A. hydrophila vaccine preparations,
to protect fish against diseases caused by this bacterium. How-
ever, the efficacy of these vaccines was not tested against a variety
of different A. hydrophila isolates, and it is therefore unknown if
they would cross-protect against other isolates of the bacterium
[1315]. Most of these vaccines do not appear to have been field-
tested for commercialisation, possibly due to the fact that the
quantity of vaccine required for a field trial is much greater, and
the licensing of vaccines is a long and complicated process.
In previous work, we used immunoproteomics to try to identify
a common antigen between several isolates of A. hydrophila that
could be used to cross-protect fish from infection caused by vari-
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S. Poobalane et al. / Vaccine28 (2010) 35403547 3545
Table
1
ThedetailsoftheA.hydrophilaisolatesusedandrelativepercentagesurvivalofcarpvaccinatedwithrecombinantS-layerproteinofA.hydrophilathenchallengedwiththebacterium.
A.hydrophila
isolates
Isolatedfrom
LD50value
(bacteriaml1)
Totalmortality(%)
Relativeperce
ntage
survival(%)
P-value
(Chi-squaretest)
Hostspecies
Country/date
Lesion/infection
Vaccinatedfish
Controlfish
T4
Rohu(Labeorohita)
Bangladesh(1994)
EUSlesion
1
108
10
75
87
0.000
Hh
Hedgehog(Erinaceuseuropaeu
s)
IOA
5
107
10
65
85
0.000
98140
Blackshark(Moruliuschrysoph
ekadion)
AyuthayaProvince,Thailand(1998)
Haemorrhagiclesion
2
107
10
50
80
0.006
98141
2
107
10
40
75
0.028
Vds
Catfish(Ictuluruspuctatus)
India
EUSlesion
2
107
15
40
62.5
0.077
B2/12
Bangladesh
7.5
106
20
45
56
0.091
Abbreviations:IOA,InstituteofAquaculture;EUS,
epizooticulcerativesyndrome.
ous strains of this pathogen [30,31]. Using bacteria cultured both
in vitro and in vivo, an immunogenic S-layer protein was identi-
fiedwhich was common to all virulent isolates ofA. hydrophila. I n a
small scale preliminary vaccination study, the protein was electro-
eluted from an SDS-PAGE gel and the level of protection elicited by
this protein examined using a low number of goldfish. The protein
was found to confer protection against the bacterium in the vac-
cinated goldfish as the RPS value was 66.7%. However, the process
for eluting the protein from the gel was time consuming, and very
small yields of the protein were obtained which were insufficient
forlarger scale vaccination studies. It was, therefore, decided to use
recombinant protein technology to produce sufficient quantities of
the S-layer protein to enable large-scale vaccine trials to be carried
outto examine theability of this protein to elicitprotectionagainst
a variety of different A. hydrophila isolates.
Recombinant protein vaccines have a number of advantages
over traditional bacterin vaccines, including being inexpensive to
produce and safer to use [25]. One of the other major advantages
is that this method of vaccine preparation avoids the presence of
unwanted antigens from the pathogen in the vaccine, which could
lead to suppression of the hosts immune system. For example,
some of the surface proteins of Renibacterium salmoninarum (i.e.
p22 and p57) have been found to suppress the immune system of
fish, and therefore, a WC preparation of this bacterium is not idealto use as a bacterin vaccine [35]. Recombinant protein vaccines, on
the other hand, can induce specific immunity against a particular
antigen which can protect the host from infection [36].
The reason for differences in thevirulence between differentiso-
lates ofA. hydrophila is due to a wide variation in the expression of
genes between various isolates,which in turn leads to differentlev-
els of expression of the virulence factors, such as those found in the
ECP or as surface proteins [37]. In this study, the lowest virulence
was seen with isolate T4 and thehighestwithisolateB2/12.The rate
of mortality was high with all six isolates in both vaccinated and
control fish within the first 2 days post-challenge, compared with
the level of mortality obtained over the rest of the trial (Fig. 4). The
sudden mortality that occurred in the first 2 days post-challenge
was most likely due to toxic shock [38]. This rate of mortality isunlikely to occur during a natural infection because the concen-
tration of the pathogen gradually increases during the infection,
whereas a large numberof bacteria areintroducedat thesame time
in the experimental infection. The recombinantS-layer protein vac-
cine may therefore have a greater ability to protect fish against
natural infections by A. hydrophila, when bacterial concentrations
are low.
The S-layer protein is a predominant cell surface protein seen
in the SDS-PAGE profiles of WC lysates and outer membrane frac-
tions ofA. hydrophila [39]. The presence of S-layer protein among
highly virulentstrains ofA. hydrophila has previously beenreported
by Thomas and Trust [32] and Dooley et al. [40]. Diseases caused
byA. hydrophila possessing S-layers are often associated with inva-
sive systemic infection [41]. Being on the outermost layer of thebacterium, the S-layer protein has more chance of rapidly interact-
ing with the host than other protein components of the bacterium
[32]. The S-layer binds to many host proteins such as fibronectin,
laminin and vitronectin [42], which could be one reason why the
S-layer protein appears to be more immunogenic than other pro-
teins in the bacterium. Kokka et al. [43] suggested that the S-layers
may provide protection for bacteria in their natural environment
or provide a selectiveadvantage in the ability of bacteriumto cause
infection. The protein was also found to confer resistance to serum
killing and protease digestion [42].
The study indicated that the S-layer protein antigen of A.
hydrophila is able to confer protection in common carp against a
range of different isolates of the bacterium, although the RPS val-
ues obtained for the carp did vary between the different challenge
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3546 S. Poobalane et al. / Vaccine28 (2010) 35403547
isolates. No mortalities occurred in any of the groups of fish after
Day 8 post-challenge and no colonies of A. hydrophila grew from
the kidney swabs taken from surviving fish at the end of experi-
ment except for two fish. This suggests that most of the surviving
fish in the control group had managed to clear the bacterium. It
is known that a healthy fish can produce an antibody response
against different components of the bacterium and clear it from
its circulatory system within 7 days post-infection, if the level of
infection caused by the pathogen is not sufficient to kill the fish
[44].
Other proteins ofA. hydrophila have been produced as recombi-
nant antigensfor usein vaccination studies. Forexample,Fanget al.
[1] foundsignificant protection against two isolates ofA. hydrophila
in bluegourami, Trichogaster trichopterus (75and87.5% RPS) immu-
nised with a recombinant 43kDa OMP, whilea recombinant 37kDa
OMP ofA. hydrophila has been shown to be immunogenic in rohu
carp [45]. Fish vaccinated with this recombinant OMP had a RPS
value of 57% after challenging the fish with a virulent isolate of
A. hydrophila [46]. However, cross-protection of these vaccines
against a range of A. hydrophila isolates has not been reported.
Amend [33] proposed that a RPS value of more than 60 with vac-
cinated and experimentally infected fish was necessary to ensure
protection from natural infection in field. The author also recom-
mendeda minimum mortalityof 60% inthe controlgroupusing tworeplicate groups of 25 fish for both the vaccinated and the control
groups. Though not all the criteria suggested by Amend were fol-
lowedin thepresentstudy, thelevel of protection obtainedwith the
recombinant protein against six different isolates of A. hydrophila,
suggests that it is able to protect against a range of different A.
hydrophila isolates despite thefact thattwo of the challenge isolates
resulted in low RPS values due to slightly increased mortalities in
vaccinated groups (15 and 20%).
In summary, the results of this study, and the smaller prelimi-
nary study with goldfish mentionedabove, suggest that the S-layer
protein ofA. hydrophila maybe an importantantigen for conferring
protection in common carp against a variety of virulent isolates of
this pathogenic bacterium. Efficacy testing of this vaccine is cur-
rently in progress in the aquarium and in the field to establish if itcan protect a variety of fish species against different isolates of this
bacterium.
Acknowledgements
Authors would like to thank Intervet Schering-Plough Aqua-
culture, Overseas Research Students Awards Scheme and the Paul
Foundation for funding this work.
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