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Absorption Spectroscopy of Biopolymers

Absorption Spectroscopy of Biopolymers. Overview. Visible & near-UV region wavelength (nm) Microwave & radiowave region frequency (Hz) Infared region wavenumber (cm -1 ) Far-UV , x-ray, g -ray energy ( DE =h n ). Absorption & Emission. Rapid process(10 -15 s).

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Absorption Spectroscopy of Biopolymers

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  1. Absorption Spectroscopy of Biopolymers Overview

  2. Visible & near-UV region wavelength (nm) Microwave & radiowave region frequency (Hz) Infared region wavenumber (cm-1) Far-UV, x-ray, g-ray energy (DE=hn)

  3. Absorption & Emission Rapid process(10-15s)

  4. Absorption & Emission

  5. Radiation-Induced Transition • Absorption • Stimulated emission • Spontaneous emission

  6. UV-Visible Spectroscopy • Ultraviolet-visible spectroscopy involves the absorption of ultraviolet/visible light by a molecule causing the promotion of an electron from a ground electronic state to an excited electronic state. • Ultraviolet/Visible light: wavelengths (l) between 190 and 800 nm

  7. UV-visible spectrum • The two main properties of an absorbance peak are: • Absorption wavelength • lmax • Absorption intensity • Amax Housecroft and Sharpe, p. 466

  8. Beer-Lambert Law Beer-Lambert Law: log(I0/I) =ebc e =A/cb A =ebc A =ec (whenbis 1 cm) • I0 = intensity of incident light • I = intensity of transmitted light • = molar absoptivity coefficient in cm2 mol-1 c = concentration in mol L-1 b= pathlength of absorbing solution in cm-1 A = absorbance = log(Io/I) ℓ 0.1 cm http://www.hellma-worldwide.de/en/default.asp

  9. Beer-Lambert Law • A Absorbance or optical density (OD) • eabsorptivity; M-1 cm-1 • c concentration; M • T transmittance

  10. Transmittance, Absorbance, and Cell Pathlength http://www.shu.ac.uk/schools/sci/chem/tutorials/molspec/beers1.htm

  11. Deviations from the Beer-Lambert Law Lowc High c The Beer-Lambert law assumes that all molecules contribute to the absorption and that no absorbing molecule is in the shadow of another http://www.shu.ac.uk/schools/sci/chem/tutorials/molspec/beers1.htm

  12. Sample Concentrations Solution too concentrated Diluted five-fold

  13. UV-visible spectrum of 4-nitroanaline Molecular mass = 138 Solvent: Ethanol Concentration: 15.4 mg L-1 Pathlength: 1 cm Harwood and Claridge, p. 18

  14. UV-visible spectrum of 4-nitroanaline • Determine the absorption maxima (lmax) and absorption intensities (A) from the spectrum: • lmax = 227 nm, A227 = 1.55 lmax = 375 nm, A375 = 1.75 • 2. Calculate the concentration of the compound: • (1.54 x 10-2 g L-1)/(138 g/mol) = 1.12 x 10-4 mol L-1 • Determine the molar absorptivity coefficients (e) from the Beer-Lambert Law: e = A/cℓ • e227 = 1.55/(1.0 cm x 1.12 x 10-4 mol L-1) = 13,900 mol-1 L cm-1 • e375 = 1.75/(1.0 cm x 1.12 x 10-4 mol L-1) = 15,700 mol-1 L cm-1

  15. Molar absorptivities (e) Molar absoptivities are very large for strongly absorbing chromophores (e >10,000) and very small if the absorption is weak (e = 10 to 100). The magnitude of e reflects both the size of the chromophore and the probability that light of a given wavelength will be absorbed when it strikes the chromophore. A general equation stating this relationship may be written as follows: • = 0.87 x 1020P x a where P is the transition probability (0 to 1) a is the chromophore area in cm2 The transition probability depends on a number of factors including where the transition is an “allowed” transition or a “forbidden” transition http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/UV-Vis/uvspec.htm#uv2

  16. UV-visible spectrum of 4-nitroanaline Molecular mass = 138 Solvent: Ethanol Concentration: 15.4 mg L-1 Pathlength: 1 cm Harwood and Claridge, p. 18

  17. UV-visible spectrum of 4-nitroanaline • Determine the absorption maxima (lmax) and absorption intensities (A) from the spectrum: • lmax = 227 nm, A227 = 1.55 lmax = 375 nm, A375 = 1.75 • 2. Calculate the concentration of the compound: • (1.54 x 10-2 g L-1)/(138 g/mol) = 1.12 x 10-4 mol L-1 • Determine the molar absorptivity coefficients (e) from the Beer-Lambert Law: e = A/cℓ • e227 = 1.55/(1.0 cm x 1.12 x 10-4 mol L-1) = 13,900 mol-1 L cm-1 • e375 = 1.75/(1.0 cm x 1.12 x 10-4 mol L-1) = 15,700 mol-1 L cm-1

  18. UV-visible spectroscopy definitions chromophore Any group of atoms that absorbs light whether or not a color is thereby produced. auxochrome A group which extends the conjugation of a chromophore by sharing of nonbonding electrons. bathochromic shift The shift of absorption to a longer wavelength. hypsochromic shift The shift of absorption to a shorter wavelength. hyperchromic effect An increase in absorption intensity. hypochromic effect A decrease in absorption intensity.

  19. Absorption and Emission of Photons http://micro.magnet.fsu.edu/optics/lightandcolor/frequency.html

  20. Absorption and Emission Emission Absorption Absorption: A transition from a lower level to a higher level with transfer of energy from the radiation field to an absorber, atom, molecule, or solid. Emission: A transition from a higher level to a lower level with transfer of energy from the emitter to the radiation field. If no radiation is emitted, the transition from higher to lower energy levels is called nonradiative decay. http://www.chemistry.vt.edu/chem-ed/spec/spectros.html

  21. Singlet and Triplet Excited States http://www.shu.ac.uk/schools/sci/chem/tutorials/molspec/lumin1.htm

  22. Absorption and emission pathways McGarvey and Gaillard, Basic Photochemistry at http://classes.kumc.edu/grants/dpc/instruct/index2.htm

  23. Selection Rules • In electronic spectroscopy there are three selection rules which determine whether or not transitions are formally allowed: • Spin selection rule: DS = 0 • allowed transitions: singlet  singletor triplet  tripletforbidden transitions: singlet  triplet or triplet  singlet • Changes in spin multiplicity are forbidden http://www.shu.ac.uk/schools/sci/chem/tutorials/molspec/lumin1.htm

  24. Selection rules • Laporte selection rule: there must be a change in the parity (symmetry) of the complex • Laporte-allowed transitions: g u Laporte-forbidden transitions: g  goru  u • g stands for gerade – compound with a center of symmetry • u stands for ungerade – compound without a center of symmetry • Selection rule of Dℓ = ± 1 (ℓ is the azimuthal or orbital quantum number, where ℓ = 0 (s orbital), 1 (p orbital), 2 (d orbital), etc.) • allowed transitions: s  p, p  d, d  f, etc. • forbidden transitions: s  s, d  d, p  f, etc.

  25. s and s* orbitals http://www.cem.msu.edu/~reusch/VirtualText/intro3.htm#strc8a

  26. p and p* orbitals http://www.cem.msu.edu/~reusch/VirtualText/intro3.htm#strc8a

  27. Electronic Transitions: p p* http://www.cem.msu.edu/~reusch/VirtualText /Spectrpy/UV-Vis/uvspec.htm#uv2 The pp* transition involves orbitals that have significant overlap, and the probability is near 1.0 as they are “symmetry allowed”. McGarvey and Gaillard, Basic Photochemistry at http://classes.kumc.edu/grants/dpc/instruct/index2.htm

  28. p  p* transitions - Triple bonds Organic compounds with -C≡C- or -C≡N groups, or transition metals complexed by C≡N- or C≡O ligands, usually have “low-lying” p* orbitals http://www.cem.msu.edu/~reusch/VirtualText/intro3.htm#strc8a

  29. Electronic Transitions: n  p* http://www.cem.msu.edu/~reusch/VirtualText /Spectrpy/UV-Vis/uvspec.htm#uv2 The n-orbitals do not overlap at all well with the p* orbital, so the probability of this excitation is small. The e of the np* transition is about 103 times smaller than e for the pp* transition as it is “symmetry forbidden”. McGarvey and Gaillard, Basic Photochemistry at http://classes.kumc.edu/grants/dpc/instruct/index2.htm

  30. Lycopene from Tomatoes http://www.purdue.edu/UNS/html4ever/020617.Handa.lycopene.html

  31. Chlorophyll B-carotene hemoglobin

  32. Quantitative Analysis • A plot of absorption versus wavelength is the absorption spectrum

  33. Solutions containing the amino acids tryptophan and tyrosine can be analyzed under alkaline conditions (0.1 M KOH) from their different uv spectra. The extinction coefficients under these conditions at 240 nm and 280 nm are A 10-mg smaple of the protein glucagon is hydrolyzed to its constituent amino acids and diluter to 100 mL in 0.1 M KOH. The absorbance of this solution (1 cm path) was 0.717 at 240 nm and 0.239 at 280 nm. Estimate the content of tryptophan and tyrosine in mol (g protein)-1

  34. Isosbestic points Isosbestic wavelength the wavelength at which two or more components have the same extinction coefficient The occurrence of two or more isosbestics in the spectra of a series of solutions of the same total concentration demonstrates the presence of two and only two components absorbing in that spectra region.

  35. Isosbestic points

  36. UV spectrum of BSA UV spectrum of DNA from E. coli

  37. UV Absorption of amino acid

  38. Effect of Secondary structure

  39. Origin of Spectroscopic Changes • Change in local charge distribution • Change in dielectric constant • Change in bonding interaction • Change in dynamic coupling between different parts of the molecule

  40. Human Eye http://www2.mrc-lmb.cam.ac.uk/groups/GS/eye.html Retina Light sensitive protein Retina Outer segment

  41. Rhodopsin is a protein in the membrane of the photoreceptor cell in the retina of the eye. It catalyses the only light sensitive step in vision. The 11-cis-retinal chromophore lies in a pocket of the protein and is isomerised to all-trans retinal when light is absorbed. The isomerisation of retinal leads to a change of the shape of rhodopsin which triggers a cascade of reactions which lead to a nerve impulse which is transmitted to the brain by the optical nerve 1BRD http://www2.mrc-lmb.cam.ac.uk/groups/GS/rmovie.html

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