The role of Arg114 at subsites E and F in reactions catalyzed by hen egg-white lysozyme

To understand better the role of subsites E and F in lysozyme-catalyzed reactions, mutant enzymes, in which Arg114, located on the right side of subsites E and F in hen egg-white lysozyme (HEL), was replaced with Lys, His, or Ala, were prepared. Replacement of Arg114 with His or Ala decreased hydrolytic activity toward an artificial substrate, glycol chitin, while replacement with Lys had little effect. Kinetic analysis with the substrate N-acetylglucosamine pentamer, (GlcNAc)(5), revealed that the replacement for the Arg residue reduced the binding free energies of E-F sites and the rate constant of transglycosylation. The rate constant of transglycosylation for R114A was about half of that for the wild-type enzyme. (1)H-NMR analysis of R114H and R114A indicated that the structural changes induced by the mutations were not restricted to the region surrounding Arg114, but rather extended to the aromatic side chains of Phe34 and Trp123, of which the signals are connected with each other through nuclear Overhauser effect (NOE) in the wild-type. We speculate that such a conformational change causes differences in substrate and acceptor binding at subsites E and F, lowering the efficiency of glycosyl transfer reaction of lysozyme.     

Mechanism of lysozyme catalysis: role of ground-state strain in subsite D in hen egg-white and human lysozymes.

The association constants for the binding of various saccharides to hen egg-white lysozyme and human lysozyme have been measured by fluorescence titration. Among these are the oligosaccharides GlcNAc-beta(1 leads to 4)-MurNAc-beta(1 leads to 4)-GlcNAc-beta(1 leads to 4)-GlcNAc, GlcNAc-beta(1 leads to 4)-MurNAc-beta(1 leads to 4)-GlcNAc-beta(1 leads to 4)-N-acetyl-D-xylosamine, and GlcNAc-beta(1 leads to 4-GlcNAc-beta(1 leads to 4)-MurNAc, prepared here for the first time. The binding constants for saccharides which must have N-acetylmuramic acid, N-acetyl-D-glucosamine, or N-acetyl-D-xylosamine bound in subsite D indicate that there is no strain involved in the binding of N-acetyl-D-glycosamine in this site, and that the lactyl group of N-acetylmuramic acid (rather than the hydroxymethyl group) is responsible for the apparent strain previously reported for binding at this subsite. For hen egg-white lysozyme, the dependence of saccharide binding on pH or on a saturating concentration of Gd(III) suggests that the conformation of several of the complexes are different from one another and from that proposed for a productive complex. This is supported by fluorescence difference spectra of the various hen egg-white lysozyme-saccharide complexes. Human lysozyme binds most saccharides studied more weakly than the hen egg-white enzyme, but binds GlcNAc-beta(1 leads to 4)-MurNAc-beta(1leads to 4)-GlcNAc-beta(1 leads to 4)-MurNAc more strongly. It is suggested that subsite C of the human enzyme is "looser" than the equivalent site in the hen egg enzyme, so that the rearrangement of a saccharide in this subsite in response to introduction of an N-acetylmuramic acid residue into subsite D destabilizes the saccharide complexes of human lysozyme less than it does the corresponding hen egg-white lysozyme complexes. This difference and the differences in the fluorescence difference spectra of hen egg-white lysozyme and human lysozyme are ascribed mainly to the replacement of Trp-62 in hen egg-white lysozyme by Tyr-63 in the human enzyme. The implications of our findings for the assumption of superposition and additivity of energies of binding in individual subsites, and for the estimation of the role of strain in lysozyme catalysis, are discussed.     

卵清溶菌酶淀粉样纤维形成的研究

淀粉样纤维与老年性痴呆症、帕金森病和非神经性组织淀粉样变性病等人类疾病相关。运用ThT荧光、刚果红结合、远紫外圆二色、透射电镜的方法研究了不同条件下卵清溶菌酶（HEWL）淀粉样纤维的形成。实验结果表明pH值2．0是HEWL淀粉样纤维形成的必要条件,HEWL淀粉样纤维的形成是一个典型的浓度依赖型过程。三氟乙醇（TFE）对HEWL淀粉样纤维形成影响结果表明中低浓度（低于40％）的TFE加速了溶菌酶淀粉样纤维的形成,其中5％～15％（v／v）的TFE促进效果最为显著,大大缩短了淀粉样纤维的成核期;而高浓度的TFE（50％）则完全抑制了溶菌酶淀粉样纤维的形成。透射电镜直接观察了溶菌酶淀粉样纤维的形态,不加TFE时溶菌酶淀粉样纤维聚集成簇,形成相互缠绕的成熟纤维,而10％的TFE存在时,观察到的形态则主要是短的原纤维,且没有发生纤维的相互交联实验。结果表明溶菌酶形成相互缠绕的成熟纤维主要由弱的疏水相互作用来驱动。     

Amyloid fibrillation of hen egg-white lysozyme is inhibited by TCEP

This work examines the inhibitory effect of TCEP on the in vitro fibrillation of hen lysozyme at pH 2. We demonstrate that the inhibition of hen lysozyme fibrillation by TCEP follows a dose-dependent manner. Our data show that the addition of TCEP prevents α-to-β transition and promoted unfolding of lysozyme. Moreover, our findings suggested that the TCEP-induced attenuated fibrillation is associated with disulfide disruption and structural unfolding of HEWL.     

Pressure-dependent changes in the solution structure of hen egg-white lysozyme

The "rules" governing protein structure and stability are still poorly understood. Important clues have come from proteins that operate under extreme conditions, because these clarify the physical constraints on proteins. One obvious extreme is pressure, but so far little is known of the behavior of proteins under pressure, largely for technical reasons. We have therefore developed new methodology for calculating structure change in solution with pressure, using NMR chemical shift changes, and we report the change in structure of lysozyme on going from 30 bar to 2000 bar, this being the first solution structure of a globular protein under pressure. The alpha-helical domain is compressed by approximately 1%, due to tighter packing between helices. The interdomain region is also compressed. By contrast, the beta-sheet domain displays very little overall compression, but undergoes more structural distortion than the alpha-domain. The largest volume changes tend to occur close to hydrated cavities. Because isothermal compressibility is related to volume fluctuation, this suggests that buried water molecules play an important role in conformational fluctuation at normal pressures, and are implicated as the nucleation sites for structural changes leading to pressure denaturation or channel opening.     

Cell fusion induced by herpes simplex is inhibited by hen egg-white lysozyme

The formation of syncytia in cell monolayers infected with a macroplaque strain (MP) of herpes simplex virus was found to be inhibited by hen egg-white lysozyme. Inhibition was roughly proportional to the enzyme concentration. The virus titres in supernatant fluids of lysozyme-treated cultures were also reduced compared with untreated cultures. Control experiments excluded the possibility that lysozyme altered the virus viability and infectivity or impaired cell growth. Since lysozyme is a cationic protein, further experiments were performed in order to discover whether its antisyncytiogenic effect depended on its enzymatic activity or on its positive charge. Inhibition of the MP-induced polycaryocytosis was found to be caused by heat-inactivated lysozyme and three chemically-modified lysozymes with a higher positive charge (one retaining and two lacking enzymatic activity).     

On the inhibition of hen egg-white lysozyme activity by aminoglycosidic antibiotics.

Lytic activity of hen egg-white lysozyme towards bacterial cells of Micrococcus lysodeikticus was pH-dependent inhibited by several aminoglycosidic antibiotics, the structure of which is related to the saccharidic substrates of the enzyme.Inhibition extent suggests the role of the positive charges of this type of antibiotics on the mechanism of lysozyme activity inhibition.     

Effects of copolypeptides on amyloid fibrillation of hen egg-white lysozyme

The fibrillation of hen egg-white lysozyme (HEWL) in the absence and presence of simple, unstructured D,L-lysine-co-glycine (D,L-Lys-co-gly) and D,L-lysine-co-L-phenylalanine (D,L-Lys-co-Phe) copolypeptides was studied by using a variety of analytical techniques. The attenuating and decelerating effects on fibrillation are significantly dependent on the polypeptide concentration and the composition ratios in the polypeptide chain. Interestingly, D,L-Lys-co-gly and D,L-Lys-co-Phe copolypeptides with the same composition ratio have comparable attenuating effects on fibrillation. The copolypeptide with highest molar fraction of glycine residue exhibits the strongest suppression of HEWL fibrillation. The copolypeptide has the highest hydrophobic interacting capacity due to the more molar ratio of apolar monomer in the polymer backbone. The major driving forces for the association of HEWL and copolypeptides are likely to be hydrogen bonding and hydrophobic interactions, and these interactions reduce the concentration of free protein in solution available to proceed to fibrillation, leading to the increase of lag time and attenuation of fibrillation. The results of this work may contribute to the understanding of the molecular factors affecting amyloid fibrillation and the molecular mechanism(s) of the interactions between the unstructured polypeptides and the amyloid proteins.     

Effects of glutathione on amyloid fibrillation of hen egg-white lysozyme

This study examined the effects of glutathione on the fibrillation of hen egg-white lysozyme. We found that the fibrillation of lysozyme was considerably reduced by GSH while no anti-aggregating activity was detected with only GSSG. SDS-PAGE results also revealed that the addition of GSH led to an early occurrence of prominent lysozyme hydrolysis. Moreover, GSH was effective in inhibiting lysozyme fibrillation when GSH was added within 6 days of incubation. We conclude that the attenuation of lysozyme fibrillation is strongly dependent upon the redox environment. Our data may contribute to decipher the molecular mechanism of amyloid fibrillation.