The catalytic domain of a bacterial lytic transglycosylase defines a novel class of lysozymes

The 70-kDa soluble lytic transglycosylase (SLT70) from Escherichia coli is a bacterial exo-muramidase that cleaves the cell wall peptidoglycan, producing 1,6-anhydro-muropeptides. The X-ray structure of SLT70 showed that one of its domains is structurally related to lysozyme, although there is no obvious similarity in amino acid sequence. To relate discrete structural features to differences in reaction mechanism and substrate/product specificity, we compared the threedimensional structure of the catalytic domain of SLT70 with the structures of three typical representatives of the lysozyme superfamily: chicken-type hen egg-white lysozyme, goosetype swan egg-white lysozyme, and phage-type lysozyme from bacteriophage T4. We find a particularly close relationship between the catalytic domain of SLT70 and goose-type lysozyme, with not only a significant similarity in overall structure, but even a weak homology in amino acid sequence. This finding supports the notion that the goose-type lysozyme takes up a central position in the lysozyme superfamily and that it is structurally closest to the lysozyme ancestors. The saccharide-binding groove is the most conserved part in the four structures, but only two residues are absolutely preserved: the “catalytic” glutamic acid and a structurally required glycine. The “catalytic” aspartate is absent in SLT70, a difference that can be related to a different mechanism of cleavage of the β-1,4-glycosidic bond. The unique composition of amino acids at the catalytic site, and the observation of a number of differences in the arrangements of secondary structure elements, define the catalytic domain of SLT70 as a novel class of lysozymes. Its fold is expected to be exemplary for other bacterial and bacteriophage muramidases with lytic transglycosylase activity. © 1995 Wiley-Liss, Inc.     

Relation between hen egg white lysozyme and bacteriophage T4 lysozyme: Evolutionary implications

Hen egg white lysozyme and T4 bacteriophage lysozyme have the same catalytic function, but have non-homologous amino acid sequences. Notwithstanding the differences in their primary structures, the two lysozymes have similarities in their overall backbone conformations, in their modes of binding substrates and probably in their mechanisms of action.By different criteria, the similarity between the folding of the two enzymes can be shown to be statistically significant. Also the transformation which optimizes the agreement between the backbones of the two molecules is shown to accurately align their active site clefts, so that saccharide units bound in the A, B, C and D subsites of hen egg white lysozyme coincide within 1 to 2 Å with analogous saccharides bound to phage lysozyme. Furthermore, a number of the specific interactions between enzyme and substrate which were observed for hen egg white lysozyme, and thought to be important for catalysis, are found to occur in a structurally analogous way in the phage enzyme. Fifty-four atoms from the respective active sites which appear to be equivalent, including saccharides bound in the B and C sites, superimpose with a root-mean-square discrepancy of 1.35 Å.These structural and functional similarities suggest that the two lysozymes have arisen by divergent evolution from a common precursor. This is the first case in which two proteins of completely different amino acid sequence have been shown, with high probability, to have evolved by divergent rather than convergent evolution.     

Inactivation of gram-negative bacteria by lysozyme, denatured lysozyme, and lysozyme-derived peptides under high hydrostatic pressure

We have studied the inactivation of six gram-negative bacteria (Escherichia coli, Pseudomonas fluorescens, Salmonella enterica serovar Typhimurium, Salmonella enteritidis, Shigella sonnei, and Shigella flexneri) by high hydrostatic pressure treatment in the presence of hen egg-white lysozyme, partially or completely denatured lysozyme, or a synthetic cationic peptide derived from either hen egg white or coliphage T4 lysozyme. None of these compounds had a bactericidal or bacteriostatic effect on any of the tested bacteria at atmospheric pressure. Under high pressure, all bacteria except both Salmonella species showed higher inactivation in the presence of 100 microg of lysozyme/ml than without this additive, indicating that pressure sensitized the bacteria to lysozyme. This extra inactivation by lysozyme was accompanied by the formation of spheroplasts. Complete knockout of the muramidase enzymatic activity of lysozyme by heat treatment fully eliminated its bactericidal effect under pressure, but partially denatured lysozyme was still active against some bacteria. Contrary to some recent reports, these results indicate that enzymatic activity is indispensable for the antimicrobial activity of lysozyme. However, partial heat denaturation extended the activity spectrum of lysozyme under pressure to serovar Typhimurium, suggesting enhanced uptake of partially denatured lysozyme through the serovar Typhimurium outer membrane. All test bacteria were sensitized by high pressure to a peptide corresponding to amino acid residues 96 to 116 of hen egg white, and all except E. coli and P. fluorescens were sensitized by high pressure to a peptide corresponding to amino acid residues 143 to 155 of T4 lysozyme. Since they are not enzymatically active, these peptides probably have a different mechanism of action than all lysozyme polypeptides.     

Protein conformation wheels: cytochromes and lysozymes

Conformation wheels, directly relating to amino acid sequence to the local torsion angles in a protein molecule, are presented for cytochromes c, c2, c550, and c551 and for lysozymes from hen egg-white and T4 bacteriophage. The circular plots for the cytochrome molecules aid in visualizing the common three-dimensional folding ("cytochrome fold") observed in this family of proteins. Conformation wheels for lysozymes from two different species reveal the characteristic differences in their folding patterns. These novel plots are also useful in storing and comparing the several sets of crystallographic data reported for lysozyme.     

Comparison of the internal dynamics of globular proteins in the microcrystalline and rehydrated lyophilized states

Natural abundance solid-state 13C-NMR spin-lattice relaxation experiments in the laboratory (T1) and off-resonance rotating (T(1rho)) frames were applied for qualitative comparison of the internal molecular dynamics of barstar, hen egg white lysozyme and bacteriophage T4 lysozyme in both the microcrystalline and the rehydrated (water content is 50% of the protein mass) lyophilized states. The microcrystalline state of proteins provides a better spectral resolution; however, less is known about the local structure and dynamics in the different states. We found by visual comparison of both T1 and T(1rho) relaxation decays of various resonance bands of the CPMAS spectra that within the ns-mus range of correlation times there is no appreciable difference in the internal dynamics between rehydrated lyophilized and crystalline states for all three proteins tested. This suggests that the internal conformational dynamics depends weakly if at all on inter-protein interactions in the solid state. Hence, physical properties of globular proteins in a fully hydrated solid state seem to be similar to those in solution. This result at least partly removes concerns about biological relevance of studies of globular proteins in the solid state.     

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.     

Differential Patterns of Bacteriolytic Activities in Potato in Comparison to Bacteriophage T4 and Hen Egg White Lysozymes

A comparison of the enzymatic activities of endogenous potato bacteriolytic enzymes with bacteriophage T4 and hen egg white lysozyme has been performed. Using Erwinia carotovora atroseptica and Pseudomonas solanacearum as substrates in, comparison to Micrococcus lysodeikticus a differential pattern of bacteriolytic activities could be detected. The expression pattern of endogenous potato lysozymes suggests that their functional activity against phytopathogenic bacteria in planta is unlikely. Antibacterial activities in transformed, T4 lysozyme expressing and non–transformed potato plants are evaluated.     

Crystal structure of the lytic transglycosylase from bacteriophage lambda in complex with hexa-N-acetylchitohexaose

The three-dimensional structure of the lytic transglycosylase from bacteriophage lambda, also known as bacteriophage lambda lysozyme, complexed to the hexasaccharide inhibitor, hexa-N-acetylchitohexaose, has been determined by X-ray crystallography at 2.6 A resolution. The unit cell contains two molecules of the lytic transglycosylase with two hexasaccharides bound. Each enzyme molecule is found to interact with four N-acetylglucosamine units from one hexasaccharide (subsites A-D) and two N-acetylglucosamine units from the second hexasaccharide (subsites E and F), resulting in all six subsites of the active site of this enzyme being filled. This crystallographic structure, therefore, represents the first example of a lysozyme in which all subsites are occupied, and detailed protein-oligosaccharide interactions are now available for this bacteriophage lytic transglycosylase. Examination of the active site furthermore reveals that of the two residues that have been implicated in the reaction mechanism of most other c-type lysozymes (Glu35 and Asp52 in hen egg white lysozyme), only a homologous Glu residue is present. The lambda lytic transglycosylase is therefore functionally closely related to the Escherichia coli Slt70 and Slt35 lytic transglycosylases and goose egg white lysozyme which also lack the catalytic aspartic acid.     

Inactivation of Gram-Negative Bacteria by Lysozyme, Denatured Lysozyme, and Lysozyme-Derived Peptides under High Hydrostatic Pressure

We have studied the inactivation of six gram-negative bacteria (Escherichia coli, Pseudomonas fluorescens, Salmonella enterica serovar Typhimurium, Salmonella enteritidis, Shigella sonnei, and Shigella flexneri) by high hydrostatic pressure treatment in the presence of hen egg-white lysozyme, partially or completely denatured lysozyme, or a synthetic cationic peptide derived from either hen egg white or coliphage T4 lysozyme. None of these compounds had a bactericidal or bacteriostatic effect on any of the tested bacteria at atmospheric pressure. Under high pressure, all bacteria except both Salmonella species showed higher inactivation in the presence of 100 μg of lysozyme/ml than without this additive, indicating that pressure sensitized the bacteria to lysozyme. This extra inactivation by lysozyme was accompanied by the formation of spheroplasts. Complete knockout of the muramidase enzymatic activity of lysozyme by heat treatment fully eliminated its bactericidal effect under pressure, but partially denatured lysozyme was still active against some bacteria. Contrary to some recent reports, these results indicate that enzymatic activity is indispensable for the antimicrobial activity of lysozyme. However, partial heat denaturation extended the activity spectrum of lysozyme under pressure to serovar Typhimurium, suggesting enhanced uptake of partially denatured lysozyme through the serovar Typhimurium outer membrane. All test bacteria were sensitized by high pressure to a peptide corresponding to amino acid residues 96 to 116 of hen egg white, and all except E. coli and P. fluorescens were sensitized by high pressure to a peptide corresponding to amino acid residues 143 to 155 of T4 lysozyme. Since they are not enzymatically active, these peptides probably have a different mechanism of action than all lysozyme polypeptides.     

Cell wall substrate specificity of six different lysozymes and lysozyme inhibitory activity of bacterial extracts

We have investigated the specificity of six different lysozymes for peptidoglycan substrates obtained by extraction of a number of gram-negative bacteria and Micrococcus lysodeikticus with chloroform/Tris-HCl buffer (chloroform/buffer). The lysozymes included two that are commercially available (hen egg white lysozyme or HEWL, and mutanolysin from Streptomyces globisporus or M1L), and four that were chromatographically purified (bacteriophage lambda lysozyme or LaL, bacteriophage T4 lysozyme or T4L, goose egg white lysozyme or GEWL, and cauliflower lysozyme or CFL). HEWL was much more effective on M. lysodeikticus than on any of the gram-negative cell walls, while the opposite was found for LaL. Also the gram-negative cell walls showed remarkable differences in susceptibility to the different lysozymes, even for closely related species like Escherichia coli and Salmonella Typhimurium. These differences could not be due to the presence of lysozyme inhibitors such as Ivy from E. coli in the cell wall substrates because we showed that chloroform extraction effectively removed this inhibitor. Interestingly, we found strong inhibitory activity to HEWL in the chloroform/buffer extracts of Salmonella Typhimurium, and to LaL in the extracts of Pseudomonas aeruginosa, suggesting that other lysozyme inhibitors than Ivy exist and are probably widespread in gram-negative bacteria.     

Exploring structural homology of proteins.

A method for systematically comparing the folding of the three-dimensional structures of proteins has been developed. A search function, plotted in terms of three Eulerian angles, represents the number of sequentially equivalenced amino acids. For each orientation one protein structure is rotated about its center of mass with respect to the other and probabilities are calculated which estimate the degree of structural parallelism. The structurally equivalent residues with highest probabilities are then selected for the best common topology. It was observed that, when structures containing about 150 residues were compared, the random background had a mean value of around 14 residues and the standard deviation was approximately nine residues. The method has been shown to be successful in determining the similarity of the NAD binding domains of lactate dehydrogenase and glyceraldehyde-3-phosphate dehydrogenase, and in comparing the heme binding fold of cytochrome b₅ with the globins.Application of the method to compare hen egg white lysozyme and T4 phage lysozyme led to a single significant peak of 62 residues. The structural homology indicated by this peak showed that the substrate, as bound to hen egg white lysozyme, has a corresponding binding site in the large cleft of the phage lysozyme. The predicted binding site of N-acetyl glucosamine at position C compares well with an N-acetyl glucosamine center observed to bind to crystalline phage lysozyme (B. W. Matthews, personal communication).Some results for the comparison of the two Fe-S cage binding domains of ferredoxin are also presented.     

Process evaluations and economic analyses of recombinant human lysozyme and hen egg-white lysozyme purifications

Human lysozyme and hen egg-white lysozyme have antibacterial, antiviral, and antifungal properties with numerous potential commercial applications. Currently, hen egg-white lysozyme dominates low cost applications but the recent high-level expression of human lysozyme in rice could provide an economical source of lysozyme. This work compares human lysozyme and hen egg-white lysozyme adsorption to the cation exchange resin, SP-Sepharose FF, and the effect of rice extract components on lysozyme purification. With one exception, the dynamic binding capacities of human lysozyme were lower than those of hen egg-white at pH 4.5, 6, and 7.5 with ionic strengths ranging from 0 to 100 mM (5-20 mS). Ionic strength and pH had a similar effect on the adsorption capacities, but human lysozyme was more sensitive to these two factors than hen egg-white lysozyme. In the presence of rice extract, the dynamic binding capacities of human and hen egg-white lysozymes were reduced by 20-30% and by 32-39% at pH 6. Hen egg-white lysozyme was used as a benchmark to compare the effectiveness of human lysozyme purification from transgenic rice extract. Process simulation and cost analyses for human lysozyme purification from rice and hen egg-white lysozyme purification from egg-white resulted in similar unit production costs at 1 ton per year scale.     

Linear correlation between thermal stability and folding kinetics of lysozyme

We have studied the refolding and thermal denaturation of hen egg white lysozyme in a wide range of pH values (from 1.5 to 9.4) using stopped-flow circular dichroism (CD) and differential scanning calorimetry (DSC). A linear correlation was found between the thermal denaturation temperature (T(m)) and the logarithm of the refolding rate of the slow folding phase of hen egg white lysozyme (lnk(2)).     

Crystallographic determination of the mode of binding of oligosaccharides to T4 bacteriophage lysozyme: Implications for the mechanism of catalysis

Phage lysozyme has catalytic activity similar to that of hen egg white lysozyme, but the amino acid sequences of the two enzymes are completely different.The binding to phage lysozyme of several saccharides including N-acetylglucosamine (GlcNAc), N-acetylmuramic acid (MurNAc) and (GlcNAc)₃ have been determined crystallographically and shown to occupy the pronounced active site cleft. GlcNAc binds at a single location analogous to the C site of hen egg white lysozyme. MurNAc binds at the same site. (GlcNAc)₃ clearly occupies sites B and C, but the binding in site A is ill-defined.Model building suggests that, with the enzyme in the conformation seen in the crystal structure, a saccharide in the normal chair configuration cannot be placed in site D without incurring unacceptable steric interference between sugar and protein. However, as with hen egg white lysozyme, the bad contacts can be avoided by assuming the saccharide to be in the sofa conformation. Also Asp20 in T4 lysozyme is located 3 Å from carbon C₍₁₎ of saccharide D, and is in a position to stabilize the developing positive charge on a carbonium ion intermediate. Prior genetic evidence had indicated that Asp20 is critically important for catalysis. This suggests that in phage lysozyme catalysis is promoted by a combination of steric and electronic effects, acting in concert, The enzyme shape favors the binding in site D of a saccharide with the geometry of the transition state, while Asp20 stabilizes the positive charge on the oxocarbonium ion of this intermediate. Tn phage lysozyme, the identity of the proton donor is uncertain. In contrast to hen egg white lysozyme, where Glu35 is 3 Å from the glycosidic DOE bond, and is in a non-polar environment, phage lysozyme has an ion pair, Glull … Arg145, 5 Å away from the glycosidic oxygen. Possibly Glull undergoes a conformational adjustment in the presence of bound substrate, and acts as the proton donor. Alternatively, the proton might come from a bound water molecule.     

Conversion of Trp 62 of hen egg-white lysozyme to Tyr by site-directed mutagenesis

An expression plasmid for hen egg-white lysozyme in Saccharomyces cerevisiae was constructed by inserting almost full-length cDNA (about 600 base pairs) encoding hen egg-white pre-lysozyme into a yeast expression vector, pAM 82. The hen lysozyme was expressed under the control of the repressible acid phosphatase promoter of pAM 82 in S. cerevisiae. About half of the expressed lysozyme was secreted in the yeast growth medium as a precise mature protein which exhibited specific activity consistent with that of authentic hen egg-white lysozyme. The replacement of Trp 62 of hen egg-white lysozyme with a tyrosine residue was performed by site-directed mutagenesis using a 19-mer oligodeoxyribonucleotide. The mutant lysozyme with Tyr 62 was found to exhibit enhanced bacteriolytic activity.     

Enhancement in the lysozyme activity of the hen egg white foam matrix by cross-linking in the presence of N-acetyl glucosamine.

Lysozyme naturally present in raw hen egg white was immobilized by cross-linking the egg white foam with glutaraldehyde. Inclusion of N-acetyl glucosamine, a competitive inhibitor of lysozyme, was found to enhance the yield of lysozyme activity by fivefold.     

Comparison of goose-type, chicken-type, and phage-type lysozymes illustrates the changes that occur in both amino acid sequence and three-dimensional structure during evolution

The three-dimensional structure of goose-type lysozyme (GEWL), determined by x-ray crystallography and refined at high resolution, has similarities to the structures of hen (chicken) egg-white lysozyme (HEWL) and bacteriophage T4 lysozyme (T4L). The nature of the structural correspondence suggests that all three classes of lysozyme diverged from a common evolutionary precursor, even though their amino acid sequences appear to be unrelated (Grütter et al. 1983). In this paper we make detailed comparisons of goose-type, chicken-type, and phage-type lysozymes. The lysozymes have undergone conformational changes at both the global and the local level. As in the globins, there are corresponding alpha-helices that have rigid-body displacements relative to each other, but in some cases corresponding helices have increased or decreased in length, and in other cases there are helices in one structure that have no counterpart in another. Independent of the overall structural correspondence among the three lysozyme backbones is another, distinct correspondence between a set of three consecutive alpha-helices in GEWL and three consecutive alpha-helices in T4L. This structural correspondence could be due, in part, to a common energetically favorable contact between the first and the third helices. There are similarities in the active sites of the three lysozymes, but also one striking difference. Glu 73 (GEWL) spatially corresponds to Glu 35 (HEWL) and to Glu 11 (T4L). On the other hand, there are two aspartates in the GEWL active site, Asp 86 and Asp 97, neither of which corresponds exactly to Asp 52 (HEWL) or Asp 20 (T4L). (The discrepancy in the location of the carboxyl groups is about 10 A for Asp 86 and 4 A for Asp 97.) This lack of structural correspondence may reflect some differences in the mechanisms of action of the three lysozymes. When the amino acid sequences of the three lysozyme types are aligned according to their structural correspondence, there is still no apparent relationship between the sequences except for possible weak matching in the vicinity of the active sites.     

Redesign of the substrate-binding site of hen egg white lysozyme based on the molecular evolution of C-type lysozymes.

On the basis of the molecular evolution of hen egg white, human, and turkey lysozymes, three replacements (Trp62 with Tyr, Asn37 with Gly, and Asp101 with Gly) were introduced into the active-site cleft of hen egg white lysozyme by site-directed mutagenesis. The replacement of Trp62 with Tyr led to enhanced bacteriolytic activity at pH 6.2 and a lower binding constant for chitotriose. The fluorescence spectral properties of this mutant hen egg white lysozyme were found to be similar to those of human lysozyme, which contains Tyr at position 62. The replacement of Asn37 with Gly had little effect on the enzymatic activity and binding constant for chitotriose. However, the combination of Asn37----Gly (N37G) replacement with Asp101----Gly (D101G) and Trp62----Tyr (W62Y) conversions enhanced bacteriolytic activity much more than each single mutation and restored hydrolytic activity toward glycol chitin. Consequently, the mutant lysozyme containing triple replacements (N37G, W62Y, and D101G) showed about 3-fold higher bacteriolytic activity than the wild-type hen lysozyme at pH 6.2, which is close to the optimum pH of the wild-type enzyme.     

Primary Structure of Lysozymes from Man and Goose

The primary structure of goose egg white lysozyme seems to be distinct from that of hen egg white and human leukaemia lysozymes.     

不同来源溶菌酶的性质比较

比较两种从新鲜鸡蛋清中提取溶菌酶的方法。采用较为简单的并且产率较高的结晶法分别从鸡蛋清、鹌鹑蛋清中提取了溶菌酶 ,并分别测定了各溶菌酶的酶活力、最适pH值和最适温度。同时 ,证明了该法无法从鸭蛋清中提取出纯溶菌酶 ,故仅对粗提物进行了酶活力、最适 pH值和最适温度的测定