A spectrofluorimetric study of human lysozyme

Aggregation, dissociation and denaturation of sesame (Sesamum indicum L.) alpha-globulin in cetyl trimethyl ammonium bromide solution

The behaviour of the major protein of sesame seed (Sesamum indicum L.) alpha-globulin has been studied in a cationic detergent, cetyl trimethyl ammonium bromide solution. Up to a critical detergent concentration the protein is precipitated from solution, above which redissolution of the protein is observed. Sedimentation velocity patterns indicate the presence of higher aggregates in the detergent concentration range 5 X 10(-5)--1 X 10(-3) M. These are considered to be the soluble precursors of the insoluble aggregates. Fluorescence measurements show that tryptophanyl groups of the protein which are in contact with the aqueous phase are perturbed by the detergent. The difference spectra of the protein in higher concentration of detergent indicate considerable red shift in the spectrum. Spectrophotometric titration of phenolic groups in 1 X 10(-2) M CTAB indicate that a conformational change in the protein has taken place.

Dissection of the functional role of structural elements of tyrosine-63 in the catalytic action of human lysozyme

The functional role of tyrosine-63 in the catalytic action of human lysozyme (EC 3.2.1.17) has been probed by site-directed mutagenesis. In order to identify the role of Tyr63 in the interaction with substrate, both the three-dimensional structures and the enzymatic functions of the mutants, in which Tyr63 was converted to phenylalanine, tryptophan, leucine, or alanine, have been characterized in comparison with those of the wild-type enzyme. X-ray crystallographical analysis of the mutant enzyme at not less than 1.77-A resolution indicated no remarkable change in tertiary structure except the side chain of 63rd residue. The conversion of Tyr63 to Phe or Trp did not change the enzymatic properties against the noncharged substrate (or substrate analogs) largely, while the conversion to Leu or Ala markedly reduced the catalytic activity to a few percent of wild-type enzyme. Kinetic analysis using p-nitrophenyl penta-N-acetyl-beta-(1----4)-chitopentaoside (PNP-(GlcNAc)5) as a substrate revealed that the reduction of activity should mainly be attributed to the reduction of affinity between enzyme and substrate. The apparent contribution of the phenolic hydroxyl group and the phenol group in the side chain of Tyr63 was estimated to 0.4 +/- 0.4 and 2.5 +/- 0.8 kcal mol-1, respectively. The result suggested that the direct contact between the planar side-chain group of Tyr63 and the sugar residue at subsite B is a major determinant of binding specificity toward a electrostatically neutral substrate in the catalytic action of human lysozyme.

The increase in human antithrombin III tryptophan fluorescence produced by heparin

The increase in fluorescence of human antithrombin III has been used to study the binding of a semi-synthetic heparin analogue. One molecule of heparin were found to bind with an association constant of 8.9 . 10(4) M-1. The intrinsic fluorescence of antithrombin III exhibits a fluorescence quantum yield of 0.17. Upon addition of heparin a marked increase in the protein fluorescence quantum yield is observed.

Stopped-flow fluorescence studies on saccharide binding to lysozyme

The binding of the beta-1-4-linked trimer of N-acetyl-D-glucosamine to hen egg-white lysozyme was studied by rapid-reaction-kinetic methods with tryptophyl fluorescence observation of the transients. It was found that discrete segments of the fluorescence-difference spectrum from this reaction were perturbed at different time-points during the binding process. The results were interpretated as the formation of the initial complex, the fast phase of the reaction, perturbing the environment of tryptophan-62 and a subsequent and slower rearrangement of the initial complex perturbing the environment of tryptophan-108. At pH 4.4, the release of protons from aspartate-101 occurred during the rearrangement step of the binding reaction. A model for the reaction is presented (E, enzyme; L, ligand): (see article) The association of this ligand with lysozyme may be visualized in three-dimensional terms as initial complex-formation across the top of the active-site cleft followed by a diving motion of the ligand into the cleft.

The low-temperature luminescence properties of bovine alpha-lactalbumin

The luminescence of bovine alpha-lactalbumin at 77 K has been studied and compared with that of lysozyme. Alpha-Lactalbumin has several unusual properties, including a fluorescence spectrum showing vibrational fine structure, an abnormal phosphorescence spectrum, a high fluorescence: phosphorescence ratio and an abnormal phosphorescence decay. These properties are largely due to the proximity of tryptophan residues to disulphide bonds. Reduction of all these bonds causes considerable changes in alpha-lactalbumin luminescence, as does denaturation in acid solution. Reduction of a single labile disulphide bond has little effect, and the properties of alpha-lactalbumin III, a variant lacking one disulphide bond and one trypotophan residue, are similar to those of the normal protein. Several differences between alpha-lactalbumin and lysozyme are reported. The results support the suggestion that the two tryptophan residues found in the active site cleft of alpha-lactalbumin may be largely responsible for its luminescence.