Individual tyrosine side-chain contributions to circular dichroism of ribonuclease

Experimental and theoretical studies using site-directed mutants of ribonuclease A (RNase A) offer more extensive information on the tyrosine side-chain contributions to the circular dichroism (CD) of the enzyme. Bovine pancreatic RNase A has three exposed tyrosine residues (Tyr73, Tyr76, and Tyr115) and three buried tyrosine residues (Tyr25, Tyr92 and Tyr97). The difference CD spectra between the wild type and the mutants at pH 7.0 (Deltaepsilon(277,wt) - Deltaepsilon(277,mut)) show bands with more negative DeltaDeltaepsilon(277) values for Y73F and Y115F than those for Y25F and Y92F and bands with positive DeltaDeltaepsilon(277) values for Y76F and Y97F. The theoretical calculations are in good semiquantitative agreement for all the mutants. The pH difference spectrum (pH 11.3-7.0) for the wild type shows a negative band at 295 nm and an enhanced positive band at 245 nm. The three mutants at buried tyrosine sites and one mutant at an exposed tyrosine site (Y76F) exhibit pH-difference spectra that are similar to that of the wild type. In contrast, two mutants at exposed tyrosine sites (Y73F and Y115F) exhibit diminished 295-nm negative bands and, instead of positive bands at 245 nm, negative bands are observed. Our results indicate that Tyr73 and Tyr115, two of the exposed tyrosine residues, are the largest contributors to the 277- and 245-nm CD bands of RNaseA, but the buried tyrosine residues and the one remaining exposed residue also contribute to these bands. Disulfide contributions to the 277- and 240-nm bands and the peptide contribution to the 240-nm band are confirmed theoretically.     

Analysis of the kinetics of folding of proteins and peptides using circular dichroism

Circular dichroism (CD) is a useful spectroscopic technique for studying the secondary structure, folding and binding properties of proteins. This protocol covers how to use the intrinsic circular dichroic properties of proteins to follow their folding and unfolding as a function of time. Included are methods of obtaining data and for analyzing the folding and unfolding data to determine the rate constants and the order of the folding and unfolding reactions. The protocol focuses on the use of CD to follow folding when it is relatively slow, on the order of minutes to days. The methods for analyzing the data, however, can also be applied to data collected with a CD machine equipped with stopped-flow accessories in the range of milliseconds to seconds and folding analyzed by other spectroscopic methods including changes in absorption or fluorescence spectra as a function of time.     

Vacuum ultraviolet circular dichroism of galactomannans

The chiroptical behaviour of plant galactomannans has been investigated by a combined vacuum ultraviolet circular dichroism (v.u.c.d) and optical rotatory dispersion (o.r.d.) approach. The samples studied were from Cyamopsis tetragonolobus (guar), Caesalpin'ia spinosa (tara), and Ceratonia siliqua (carob), with galactose levels of 39, 25 and 19%, respectively. V.u.c.d. solid film spectra have been recorded down to 140 nm, and in all cases show a positive band at 169 nm, and a negative band at 149 nm whose relative intensity increases systematically with decreasing galactose content. In solution only the lower energy band is accessible, and has the same position and width as in the solid state but substantially greater amplitude. Residual o.r.d. behaviour, after subtraction of the contribution from the 169 nm band (calculated by Kronig-Kramers transform of fitted c.d. parameters) shows a single band of the same position and width as the high energy solid state transition. The amplitude of both transitions in solution varies linearly with galactose content, consistent with simple additivity of contributions from the two different residues. Extrapolation to 0 and 100% galactose yields molarr ellipticities (10³ x deg cm² dmol^?1) at 169 and 149 nm, respectively, of +14 and ?33 for mannan, and ?8 and ?80 for galactan. Reduction in the net intensity of both transitions in the solid state, and to a lesser degree in carob gels, is attributed to conformational restriction of galactose by chain packing, with consequent increase in c.d. intensity from these residues and hence greater cancellation of mannose backbone contributions.     

How to study proteins by circular dichroism

Circular dichroism (CD) is being increasingly recognised as a valuable technique for examining the structure of proteins in solution. However, the value of many studies using CD is compromised either by inappropriate experimental design or by lack of attention to key aspects of instrument calibration or sample characterisation. In this article, we summarise the basis of the CD approach and its application to the study of proteins, and then present clear guidelines on how reliable data can be obtained and analysed.     

Tryptophan contributions to the unusual circular dichroism of fd bacteriophage.

The circular dichroism (CD) spectrum of fd bacteriophage has a deep minimum at 222 nm characteristic of highly alpha-helical protein, but there is a shoulder at 208 nm rather than a minimum, with a 222/208-nm amplitude ratio near 1.5 rather than near 1. Oxidation of fd phage with the tryptophan reagent N-bromosuccinimide (NBS) changes the ratio. In this report, the NBS titration of fd is followed by CD and three other spectroscopies, the results of which yield an explanation of the unusual CD spectrum. Absorbance, fluorescence, and Raman data show the oxidation to have two phases, the first of which involves the destruction of tryptophan and the second, tryptophan and tyrosine. Raman spectra reveal the invariance of an environmentally-sensitive tyrosine Fermi resonance doublet during the first oxidative phase. Raman spectra also show that little or no change of alpha-helicity occurs in the first or second oxidation phase, although very slight changes in the helix parameters might be occurring. Concurrent with the destruction of tryptophan during the first phase is the appearance in CD difference spectra ([theta]NBS-treated fd - [theta]native fd) of positive maxima at 208-210 nm and negative maxima at 224 nm, with crossovers at 217 nm. Enormous difference ellipticities, per oxidized subunit of 50 amino acids, of +490,000 +/- 80,000 deg cm2 dmol-1 at 208 nm and -520,000 +/- 110,000 deg cm2 dmol-1 at 224 nm have been derived from the data.(ABSTRACT TRUNCATED AT 250 WORDS)     

Vacuum ultraviolet circular dichroism of keratan sulfate

The vacuum ultraviolet CD of keratan sulfate reveals an intense negative CD band at 171 nm. Its intensity can be rationalized with a recently proposed quadrant rule in terms of the acetamido group being slightly tilted toward the hexosaminidic linkage oxygen. The same structural feature accounts for the particularly intense negative n-pi CD band near 210 nm.     

A model for solvent contributions to polypeptide and protein circular dichroism

The possibility of bound solvent contributing directly to the circular dichroism of polypeptides and proteins is discussed. The model presented is based on the requirement of a breakdown in the planar symmetry of the amide environment. This symmetry breakdown is described in terms of the conformational states of the chain, and leads to necessary, but not sufficient, conditions for observable solvent contributions. Application of the model leads to the conclusion that, while some chain conformations are intrinsically incapable of roviding the required breakdown in the symmetry of solvent perturbations, other conformations force such a breakdown, notably poly-L -proline II and disordered chains.     

Recent contributions of electronic circular dichroism to the investigation of oligopeptide conformations

Recent applications in our laboratories of electronic circular dichroism to the study of peptide secondary structures and their changes under external stimuli are briefly reviewed. More specifically, this article deals with: 1). characterization of a novel peptide conformation; 2). origin of amino acid homo-chirality on Earth; 3). bend and helical peptides as spacers; and 4). transfer and propagation of chirality in peptides.     

Aromatic side-chain cluster of biotin binding site of avidin allows circular dichroism spectroscopic investigation of its ligand binding properties

Promiscuous ligand binding by hen egg-white avidin has been demonstrated and studied by using circular dichroism (CD) spectroscopy complemented by molecular docking calculations. It has been shown that the biotin-binding pocket of avidin is able to accommodate a wide variety of chemical compounds including therapeutic drugs (e.g., thalidomide, NSAIDs, antihistamines), natural compounds (bilirubin, myristic acid), and synthetic agents (xanthenone dyes). The cluster of aromatic residues located at the biotin-binding pocket renders the intrinsic CD spectrum of avidin sensitive to ligand binding that results in the increase of the vibronic components of the (1) L(b) transition of the Trp residues. Extrinsic (induced) CD bands measured with chemically diverse avidin ligands are generated by intramolecular coupled oscillator (e.g., bilirubin) or by intermolecular ligand-Trp exciton coupling mechanism [e.g., 2-(4'-hydroxyazobenzene)-benzoic acid (HABA)]. Among the compounds of which avidin-binding affinity constants have been calculated, two novel high-affinity ligands, flufenamic acid and an enzyme inhibitor thiazole derivative have been identified (K(d) ≈ 1 μM). Avidin binding mode of the ligand molecules has been discussed in the light of docking results. The induced CD profile of the thiazole derivative has been correlated with the stereochemistry of its docked conformation. The important role in the ligand binding of a polar side-chain cluster at the bottom of the biotin-binding cavity as well as the analogous avidin-binding mode of HABA and fenamic acid type NSAIDs have been proposed.     

Deconvolution of the circular dichroism spectra of proteins: the circular dichroism spectra of the antiparallel beta-sheet in proteins.

A recently developed algorithm, called Convex Constraint Analysis (CCA), was successfully applied to determine the circular dichroism (CD) spectra of the pure beta-pleated sheet in globular proteins. On the basis of X-ray diffraction determined secondary structures, the original data set used (Perczel, A., Hollosi, M., Tusnady, G. Fasman, G.D. Convex constraint analysis: A natural deconvolution of circular dichroism curves of proteins, Prot. Eng., 4:669-679, 1991), was improved by the addition of proteins with high beta-pleated sheet content. The analysis yielded CD curves of the pure components of the main secondary structural elements (alpha-helix, antiparallel beta-pleated sheet, beta-turns, and unordered conformation), as well as a curve attributed to the "aromatic contribution" in the wavelength range of 195-240 nm. Upon deconvolution the curves obtained were assigned to various secondary structures. The calculated weights (percentages determining the contributions of each pure component curve in the measured CD spectra of a given protein) were correlated with the X-ray diffraction determined percentages in an assignment procedure and were evaluated. The Pearson product correlation coefficients (R) are significant for all five components. The new pure component curves, which were obtained through deconvolution of the protein CD spectra alone, are promising candidates for determining the percentages of the secondary structural components in globular proteins without the necessity of adopting an X-ray database. The CD spectrum of the CheY protein was interesting because it has the characteristic shape associated with the alpha-helical structure, but upon analysis yielded a considerable amount of beta-sheet in agreement with the X-ray structure.     

First-principles calculations of protein circular dichroism in the near ultraviolet

Electronic transitions in aromatic side chains are responsible for the characteristics of proteins in the near UV. We present the first systematic study of a large number of proteins focused on the accurate calculation of near-UV circular dichroism (CD) spectra. We report new parameter sets derived from ab initio calculations for benzene, phenol, and indole that describe the valence electronic transitions to the (1)L(b), (1)L(a), (1)B(b), and (1)B(a) states in the side chains of amino acids phenylalanine, tyrosine, and tryptophan. CD spectra were calculated, using the matrix method with the new side-chain parameters, for 30 proteins whose CD spectra and crystal structures have been made publicly available. The new parameter sets are fully self-consistent and yield near-UV spectra better than those obtained using previous parameter sets. The mean absolute errors for computed wild-type spectra in the near UV are reduced by a factor of approximately 2. A similiar reduction is found for the near-UV spectra (and difference spectra) of mutants involving aromatic amino acids. Empirical modifications to model vibronic coupling in the side-chain chromophore of phenylalanine offer no overall improvement. Protein CD calculations from first principles coupled with atomic-level modeling enhance the utility and interpretability of CD measurements in the near UV.