Emission spectroscopy(Mainly fluorescence spectroscopy)
Reading: van Holde Chapter 11
Homework: due Wednesday, April 18
van Holde 11.2. 11.3, 11.4, 11.5, 11.6, 11.7;
Midterm 2: Friday, April 20
Overview:
1. What is fluorescence? (conceptual QM picture, fluorescence spectra,
quantum yield, lifetimes)
2. One powerful application: Fluorescence microscopy
3. Solvent effects
4. FRET (what is it?, Förster radius, quenching, applications of FRET)
5. Linear polarization of fluorescence, rotational motion (tumbling), Perrin plots
Ground state and excited states of the electrons in the outermost occupied shell of a molecule.
There are different types of excited states (higher energy level states), depending on spin and angular momentum; here we will just talk about triplet and singlet states.
Two (highest energy) electrons in ground state
Emission spectroscopyConceptual Quantum mechanical picture
Quick quiz: Why is quantum mechanics called quantum mechanics?
Ground state
1. singlet
2. singlet
1. triplet
Abs
orp
tion
~ 1
0-15 s
Inte
rnal
co
nver
sion
~
10-1
2 s
Intersystem
crossing
~ 10-8 s
Non
-rad
iativ
e ~
10-8 s
Flu
ores
cenc
e
(wai
t tim
e) ~
10-8
s
No
n-r
ad
iativ
e
~1
02
to 1
0-1
1 s
Ph
osp
ho
rce
nce
(wa
it tim
e)
~ 1
02
to 1
0-4 s
Absorbance, Fluorescence and Phosphorescence
Different paths by which excited electrons can return to ground
state – only one path results in fluorescence. Molecules will
fluoresce if the emission process has a lifetime that is shorter
than the conversion to the triplet state or non-radiative loss of
energy.
Emission spectroscopyConceptual Quantum mechanical picture
Some Terminology
• Luminescence: Process, in which susceptible molecules emit light from electronically excited states created by either a physical (for example, absorption of light), mechanical (friction), or chemical mechanism.
• Photoluminescence: Generation of luminescence through excitation of a molecule by ultraviolet or visible light photons. Divided into two categories: fluorescence and phosphorescence, depending upon the electronic configuration of the excited state and the emission pathway.
• Fluorescence (emission from singlet state): Some atoms and molecules absorb light at a particular wavelength, and subsequently emit light of longer wavelength after a brief interval, termed the fluorescence lifetime, . Fluorescent molecules are called fluorophores.
• Phosphorescence (emission from triplet state): Similar to fluorescence, but with a much longer excited state lifetime.
Fluorescence spectra
Absorption fluorescence
c
hhE
:(light)photon a ofEnergy
:Remember
absorption emission
In fluorescence, the return to the ground state (almost) always occurs from lowest state of excited state (0’-level).
h = 6.6·1034 J·s (Planck’s const.) … frequency
1. Excitation: Light-induced transition, molecule goes from ground state to an excited electronic & vibrational state.
2. Vibrational Relaxation: Molecule loses some energy, falls to lowest vibrational state, still in excited electronic state
3. Emission: Molecule returns to ground electronic state while emitting a higher wavelength (=lower energy) photon
Fluorescence spectra
1. Excitation Spectrum: Fluorescence intensity vs. wavelength used to excite transition resembles absorbance spectrum.
2. Emission Spectrum: Fluorescence intensity vs. wavelength emitted for transition back to ground state: red-shifted with respect to excitation spectrum.
3. Quantum Yield: Ratio of energy absorbed to that emitted (more in a bit).
Fluorescence spectra
Example: Fluorescein absorption and emission spectra
Stokes shift
Looking at the absorption and emission peaks:
Fluorescein absorbs in the blue/purple (~ 490 nm) and emits in the green (~516 nm).
Fluorescence spectra
White board example:
Looking at the fluorescein spectrum, what is the energy difference between the ground state and the excited singlet state in fluorescein?
Steady State/Frequency Domain Fluorescence Instrumentation
Dual monochromators, one for excitation and the other for emission.
Obtain an Excitation and an Emission Spectrum.
Fluorescence decay, life-time, time-resolved fluorescence
Flash sample with brief (~ns) pulse of light at ex and follow intensity vs time at em
Absorption N(0) molecules with get excited.
Fluorescence intensity is proportional to number of excited molecules.
Flu
ores
cenc
e In
tens
ity
time
maxI
e
maxI
Decay of excited molecules is a first-order process, with lifetime. Decay can happen via three pathways:
i. Fluorescence with associated intrinsic lifetime o
ii. Conversion to triplet state (phosphorescence and non-radiative decay).
iii. Non-radiative decay.
t
kt
eI
eItI
tIkdt
tdI
)0(
)0()(
)()(
When light is absorbed, only a fraction of it is emitted via fluorescence; the rest of the excited molecules decay via other processes.
Quantum yield
0
# of quanta emitted by fluorescenceQ
# of total quanta absorbed
A
k
is lifetime of all molecules in excited state, 0 is intrinsic lifetime (lifetime of “fluorescence state”).
k, is fluorescence decay constant, A is Einstein coefficient
Corollary: Fluorescence intensity is proportional to product of absorptivity (exctinction coefficient) and quantum yield.
Experimental data - fluorescence lifetime
Flash lamp pulse
Get from slope
White board example:
If Q is 0.5 for this fluorophore, what is the fluorescence lifetime?
1. Incident Light Intensity, Io ()
More photons in = more photons out. Detector reads intensity, unlike absorbance.
2. Fraction of Light Absorbed, e() c l Depends on concentration, c; path length of optical cell, l; & molar extinction coefficient, e
3. Quantum Yield, F
Only emitted photons count.
4. Fractional Emission , f() Emission at a particular wavelength
5. Detector Efficiency , d() Wavelength-dependent instrumental factor.
6. Sensitivity, S Product of extinction coefficient and quantum yield
Factors Influencing Detected Fluorescence Intensity
F() = Io( · c · (· l · F · f( · d(
F = k · c · · F
F = k · c · S
Fluorescent amino acids
Amino acid Lifetime
Absorption Fluorescence Intensity
Wavelength Exctinc. coeff.
max Wavelength
Quantum Yield
Intensity ~ max·
Tryptophan 2.6 ns 280 nm 5,600 348 nm 0.20 1120
Tyrosine 3.6 ns 274 nm 1,400 303 nm 0.1 140
Phenylalanine 6.4 ns 257 nm 200 282 nm . 0.04 8
• Three amino acid have intrinsic fluorescence
• Fluorescence of a folded protein is mixture of fluorescence from individual aromatic residues. Most of the emissions are due to excitation of tryptophan
• Tryptophan:
Highest exctinction coeff and highest quantum strongest fluorescence intensity.
Intensity, quantum yield, and wavelength of maximum fluorescence emission are very solvent dependent. Fluorescence spectrum shifts to shorter wavelength and intensity increases as polarity of the solvent surrounding the tryptophane residue decreases.
Tryptophan fluorescence can be quenched by neighboring protonated acidic groups such as Asp or Glu.
http://dwb.unl.edu/Teacher/NSF/C08/C08Links/pps99.cryst.bbk.ac.uk/projects/gmocz/fluor.htm
• Tyrosine Like tryptophan, has strong absorption bands at 280 nm. Tyrosine is a weaker emitter than tryptophan, but it may still contribute significantly to protein fluorescence because it usually present in larger numbers. The fluorescence from tyrosine can be easily quenched by nearby tryptophan residues because of energy transfer effects.
• Phenylalanine Only a benzene ring and a methylene group is weakly fluorescent (product of quantum yield and molar absorbtivity maximum is low. Phenylalanine fluorescence is observed only in the absence of both tyrosine and tryptophane.
Fluorescence Excitation & Emission Spectra of
Aromatic Amino Acids
Absorption and Emission spectra of the aromatic amino acids in pH 7 in aqueous solutions (I. Gryczynski)
Hg – or Xe lamp
Collimating lens
Excitation filter
Specimen
Objective lens
Dichroic mirror
Emission filter
CameraSchematics from: http://www.ifr87.cnrs-gif.fr/pbc/imagerie/outils/micros/microimg/mictout.gif
Powerful application of fluorescence: Fluorescence microscopy(shown here: epi-fluorescence illumination)
Note: Photobleaching: Fluorophores will “die” after a while of intense illumination.
Hg – or Xe lamp
Collimating lens
Excitation filter
Specimen
Objective lens
Dichroic mirror
Emission filter
CameraSchematics from: http://www.ifr87.cnrs-gif.fr/pbc/imagerie/outils/micros/microimg/mictout.gif
Normal African Green Monkey Kidney Fibroblast Cells (CV-1) (from Olympus web page: http://www.olympusmicro.com). Immunofluorescently labeled with primary anti-tubulin mouse monoclonal antibodies followed by goat anti-mouse Fab fragments conjugated to Rhodamine Red-X. In addition, the specimen was stained with DAPI (targeting DNA in the nucleus).
Fluorescence microscopy
Fluorescence microscopy
• Advantages:
– Can label selected features of a sample, eg. Nucleus, DNA, microtubules, specific proteins
– Can observe how those molecule behave over time.
– Can see (though not resolve) features on nanometer level, even single molecules.
Solvent effects
Solvents can affect the fluorescence emission spectrum hugely.
Emission wavelength can be shifted and quantum yield can change.
There are specific and general solvent effects.
Changing Fluorescence can be used to detect solvent interactions.
Specific solvent interaction:
2-anilinonaphthalene fluorescence was changed to high wavelength by replacing cyclohexan with ethanol. Ethanol forms hydrogen bond.
Specific solvent effects: A chemical reaction of the excited state with the solvent. Example: Hydrogen-bonds, acid-base interactions, charge transfer.
Solvent effects
H20
0rg
Putting a fluorophore from cyclohexan (low dielectric constant) into water
(high dielectric constant), shifts fluorescence to higher wavelengths.
Lower Lower E: E: E = hc/E = hc/ Emission at longer Emission at longer
Polarization Red-ShiftPolarization Red-Shift
General solvent effects: Fluorescence depends on polarizability of solvent
Increasing dielectric constant of solvent shifts usually fluorescence to
higher wavelength.
Polar interactions lower energy of excited state (stabilize excited state).
Quantum yield depends very much on environment
Qrel = 1.00
Qrel = 0.46
Qrel = 0.23
Application: Staining of DNA in gels.
Fluorophores with good DNA binding
affinities (often intercalation), extremely
large fluorescence enhancements upon
binding nucleic acids (some >1000-fold),
and negligible fluorescence for the free
dyes.
SYBR stained dsDNA gel. Excite with UV, emits in visible. (DNA/SYBR Green I complex: Q~0.8; ~300-fold increase over free dye)
Increased quantum yield upon binding Changing quantum yield upon binding
Fluorescence resonance energy transfer (FRET)
When two fluorophores are close together it is possible that one of them absorbs the light (donor), then transfers the energy to the neighboring fluorophore (acceptor), which then emits the light.
The two conditions for this to happen are:
1. Transition dipole interaction between the two fluorophores (i.e., they need to be close together and aligned).
2. Significant overlap of the emission spectrum of the donor with the absorption spectrum of the acceptor.
Example: Fluorescein (donor) and Alexa-546 (acceptor):
The absorption and emisson spectra of some fluorophores
Good FRET pair
Fluorescence resonance energy transfer (FRET)
Basically, FRET is a great method to determine the distance between two fluorophores (molecules) in the range of ~1-10 nm.
Clever example: Molecular Beacons (also: more later on quenching)
used to detect presence of a certain DNA sequence in solution or cells (show on white board).
transfer 6
0
1E
r1
R
Efficiency of transfer:
Close together FRET signal
Far apart (further than Förster radius) no FRET signal
r … D-A distance
R0 Förster radius
Fluorescence energy resonance transfer (FRET)Donor-acceptor pairs
White board example:
a. What is the FRET efficiency for a fluorescein-rhodamine pair, that is 2.25 nm apart?
b. If excited with 488 nm light, what is the main emitted wavelength?
FRET Application:
Coexisting conformations of fibronectin in cell culture imaged using fluorescence resonance energy transfer, Baneyx et al., PNAS 98:14464, 2001
DA
Extended conformation: Donor and acceptor are far apart: no FRET (donor emits)
Folded conformation: Donor and acceptor are close FRET (acceptor emits)
FRET Detects FRET Detects CompactCompact and and ExtendedExtended Fibronectin Fibronectin Conformations in Cultured CellsConformations in Cultured Cells
Fluorophore = fluorescein Quencher = dabcylFluorophore = fluorescein Quencher = dabcyl
QuenchingSome molecules are quenchers they suppress fluorescence when they are close to a fluorophore
Molecular Beacons & Fluorescence QuenchingMolecular Beacons & Fluorescence Quenching
Quenched
no light
Not quenched light
Linear polarization of fluorescence Light to excite fluorophore is now linearly polarized
Emitted fluorescent light will be depolarized
(De-)Polarization of emitted light depends on:1. Orientation of emitting transition dipole relative to absorbing transition dipole2. Amount of molecular rotation during fluorescent lifetime! Depolarization of emitted light
Absorption is best for those molecules whose transition dipole is parallel to plane of polarization.
Fluorescence anisotropy:
I Ir=
I 2I
1. Assume molecules don’t rotate while being excited
depolarization due only to random orientation of molecules with respect to incoming light, , and angle
Depolarization is described in terms of:
20
1r ( 3cos 1)
5
If there is no molecular rotation, anisotropy will vary between 2/5 (absorbing and emitting trans. dipoles are parallel) and-1/5 (dipoles are perpendicular).
Anisotropy for fluorescence of rhodamine as a function of of exciting light
Linear polarization of fluorescence
2. Now assume molecules tumble (rotate) before emitting.
depolarization due rotation of molecules.
Two extremes: i) molecules don’t rotate before emission r = r0
ii) molecules randomly orient before emitting: r = 0
Time-resolved fluorescence provides a convenient way to measure rotational motion of biological molecules.
t /0r t r e
… correlation time
information about size &shape of molecule
large slow tumbling large molecular weight
Flu
or. a
niso
trop
y r
time
0r
e
0r
Linear polarization of fluorescence
How long for BSA to “tumble”?How long for BSA to “tumble”?
Rotational Correlation Time:Rotational Correlation Time:
= V = V / k T = / k T = ((8.1E-20)*(0.01) / [1.38E-16 * 293]8.1E-20)*(0.01) / [1.38E-16 * 293]
= = 2.0E-8 sec = 20 nsec2.0E-8 sec = 20 nsec
BSA rotates in ~ 10 - 20 nanonsecondsBSA rotates in ~ 10 - 20 nanonsecondsFluorescent lifetime ~ 5 nanosecondsFluorescent lifetime ~ 5 nanoseconds
Example: rotational correlation time for BSA Example: rotational correlation time for BSA Mol Wt = 66,500 grams/moleMol Wt = 66,500 grams/mole
DDrotrot = 8.3E6 sec-1 = 8.3E6 sec-1
Large slow rotation large molecule
Small faster rotation compact molecule
Linear polarization of fluorescence
Perrin plotsInstead of pulse illumination, use continuous illumination to measure anisotropy will get average anisotropy ravg.
HW 11.6
B
0
k T1 11
r r V T
… lifetime
… viscosity
T … temperature
V … volume of molecule
1
r
T
T
B
0
kslope:
r V
0
1intercept:
r
Applications of fluorescence to proteins
• Fluorescence microscopy
• Analytical detection of presence of proteins
• Monitor changes in quantum yield as indication of changing
environment (binding, unfolding, etc.)
• Effects of energy transfer (FRET). Determine distance of
fluorescent groups from each other in 1-10 nm range.
• Changes in fluorescence polarization to determine shape and size
of molecules (tumbling depends on shape and size)
• Monitor (change) in fluorescence parameters to determine
stoichiometry, presence of intermediates, binding constants, etc.
Application of fluorescence to DNA
• Staining of oligonucleotides in gels• Monitoring the unwinding of double-
stranded DNA helicase• Monitoring DNA melting
Also: there are tons of reactive fluorophores that can be used to label proteins (Cysteines, primary amines, etc) and DNA.
See: Molecular Probes, Inc.
http://probes.invitrogen.com/