Crystallographic studies of the interactions of Escherichia coli lytic transglycosylase Slt35 with peptidoglycan

Lytic transglycosylases catalyze the cleavage of the beta-1, 4-glycosidic bond between N-acetylmuramic acid (MurNAc) and N-acetylglucosamine (GlcNAc) in peptidoglycan with concomitant formation of a 1,6-anhydro bond in the MurNAc residue. To understand the reaction mechanism of Escherichia coli lytic transglycosylase Slt35, three crystal structures have been determined of Slt35 in complex with two different peptidoglycan fragments and with the lytic transglycosylase inhibitor bulgecin A. The complexes define four sugar-binding subsites (-2, -1, +1, and +2) and two peptide-binding sites in a large cleft close to Glu162. The Glu162 side chain is between the -1 and +1 sugar-binding sites, in agreement with a function as catalytic acid/base. The complexes suggest additional contributions to catalysis from Ser216 and Asn339, residues which are conserved among the MltB/Slt35 lytic transglycosylases.     

The C-terminal domain of Escherichia coli YfhD functions as a lytic transglycosylase

The hypothetical Escherichia coli protein YfhD has been identified as the archetype for the family 1B lytic transglycosylases despite a complete lack of experimental characterization. The yfhD gene was amplified from the genomic DNA of E. coli W3110 and cloned to encode a fusion protein with a C-terminal His(6) sequence. The enzyme was found to be localized to the outer membrane of E. coli, as would be expected for a lytic transglycosylase. Its gene was engineered for the production of a truncated soluble enzyme derivative lacking an N-terminal signal sequence and membrane anchor. The soluble YfhD derivative was purified to apparent homogeneity, and three separate in vitro assays involving high pressure liquid chromatography and matrix-assisted laser desorption ionization time-of-flight mass spectrometry were used to demonstrate the YfhD-catalyzed release of 1,6-anhydromuro-peptides from insoluble peptidoglycan. In addition, an in vivo bioassay developed using the bacteriophage lambda lysis system confirmed that the enzyme functions as an autolysin. Based on these data, the enzyme was renamed membrane-bound lytic transglycosylase F. The modular structure of MltF was investigated through genetic engineering for the separate production of identified N-terminal and C-terminal domains. The ability to bind peptidoglycan and lytic activity were only associated with the isolated C-terminal domain. The enzymatic properties of this lytic transglycosylase domain were found to be very similar to those of the wild-type enzyme. The one notable exception was that the N-terminal domain appears to modulate the lytic behavior of the C-terminal domain to permit continued lysis of insoluble peptidoglycan, a unique feature of MltF compared with other characterized lytic transglycosylases.     

Characterization of soluble and membrane-bound family 3 lytic transglycosylases from Pseudomonas aeruginosa.

Lytic transglycosylases cleave the beta,1-->4 glycosidic linkages between the N-acetylmuramoyl (MurNAc) and N-acetylglucosaminyl (GlcNAc) residues of peptidoglycan with the concomitant formation of 1,6-anhydro-N-acetylmuramyl reaction products. The genes encoding two hypothetical lytic transglycosylases were identified in the genome of Pseudomonas aeruginosa PAO1 by a BLAST search using membrane-bound lytic transglycosylase B (MltB) from Escherichia coli as the query. The two genes were amplified by PCR and cloned as fusion proteins with C-terminal hexa-His sequences. Expression studies of the two genes in E. coli in the presence of [(3)H]palmitate resulted in the labeling of only one of the two enzymes. This enzyme, named MltB, was overexpressed to form insoluble inclusion bodies. Its gene was engineered to produce a truncated form of the enzyme lacking its N-terminal 17 residues which includes Cys17, the putative site of lipidation. This MltB derivative (named sMltB) was shown to not label with [(3)H]palmitate, and it was overexpressed in soluble form. The second, nonlabeled enzyme was overexpressed in soluble form and hence was named soluble lytic transglycosylase B (SltB). Both sMltB and SltB were purified to apparent homogeneity by a combination of affinity (Ni(2+)-NTA), cation-exchange (Mono S), and gel permeation (Superdex 75) chromatographies. The reaction products released by the two enzymes from purified, insoluble peptidoglycan were characterized by a novel high-performance anion-exchange chromatography (HPAEC) assay. Both enzymes produced the same three major soluble products which were identified as anhydromuropeptides based on ESI-MS analysis (cross-linked anhydrodisaccharide-tetrasaccharide, m/z obs 1824.9; anhydrodisaccharide-pentapeptide, m/z obs 922.2; and anhydrodisaccharide-tripeptide, m/z obs 851.3. The Michaelis-Menten kinetic parameters were also determined for the two enzymes using the same insoluble peptidoglycan substrate by aminosugar compositional analysis of soluble reaction products. At pH 5.8 and in the presence of 0.1% Triton, SltB was found to be more catalytically efficient, as reflected by its k(cat)/K(M) value, than sMltB.     

Inhibition of membrane-bound lytic transglycosylase B by NAG-thiazoline

The lytic transglycosylases cleave the bacterial cell wall heteropolymer peptidoglycan with the same specificity as the muramidases (lysozymes), between the N-acetylmuramic acid and N-acetylglucosamine residues, with the concomitant formation of a 1,6-anhydromuramoyl residue. The putative catalytic residue in the family 3 lytic transglycosylase from Pseudomonas aeruginosa, Glu162 as identified by sequence alignment to the homologous enzyme from Escherichia coli, was replaced with both Ala and Asp by site-directed mutagenesis. Neither mutant enzyme differed structurally from the wild-type enzyme, as judged by CD spectroscopy, but both were enzymatically inactive confirming the essential role of Glu162 in the mechanism of action of this lytic transglycosylase. The beta-hexosaminidase inhibitor NAG-thiazoline was shown to inhibit the activity of lytic transglycosylase activity, thus providing the first direct evidence that the formation of the 1,6-anhydromuramoyl residue may proceed through an oxazolinium ion intermediate involving anchimeric assistance. Using surface plasmon resonance and difference absorbance spectroscopy, Kd values of 1.8 and 1.4 mM, respectively, were determined for NAG thiazoline, while its parent compound N-acetylglucosamine neither inhibited nor appeared to bind the lytic transglycosylase with any significant affinity.     

Role of arginine residues in the active site of the membrane-bound lytic transglycosylase B from Pseudomonas aeruginosa

Lytic transglycosylases cleave the beta-(1-->4)-glycosidic bond in the bacterial cell wall heteropolymer peptidoglycan between the N-acetylmuramic acid (MurNAc) and N-acetylglucosamine (GlcNAc) residues with the concomitant formation of a 1,6-anhydromuramoyl residue. On the basis of both sequence alignments with and structural considerations of soluble lytic transglycosylase Slt35 from Escherichia coli, four residues were predicted to be involved in substrate binding at the -1 subsite in the soluble derivative of Pseudomonas aeruginosa membrane-bound lytic transglycosylase MltB. These residues were targeted for site-specific replacement, and the effect on substrate binding and catalysis was determined. The residues Arg187 and Arg188, believed to be involved in binding the stem peptide on MurNAc, were shown to play an important role in substrate binding, as evidenced by peptidoglycan affinity assays and SUPREX analysis using MurNAc-dipeptide as ligand. The Michaelis-Menten parameters were determined for the respective mutants using insoluble peptidoglycan as substrate. In addition to affecting the steady-state binding of ligand to enzyme, as indicated by increases in K(M) values, significant decreases in k(cat) values suggested that replacement of either Arg187 and Arg188 with alanine perturbed the stabilization of both the transition state(s) and reaction intermediate. Thus, it appears that Arg187 and Arg188 are vital for proper orientation of the substrate in the active site, and furthermore this supports the proposed role of the stem peptide at binding subsite -2 in catalysis. Replacement of Gln100, a residue that would appear to interact with the N-acetyl group on MurNAc, did not show any changes in substrate affinity or activity.     

Crystal structure of MltA from Escherichia coli reveals a unique lytic transglycosylase fold

Lytic transglycosylases are bacterial enzymes involved in the maintenance and growth of the bacterial cell-wall peptidoglycan. They cleave the beta-(1,4)-glycosidic bonds in peptidoglycan forming non-reducing 1,6-anhydromuropeptides. The crystal structure of the lytic transglycosylase MltA from Escherichia coli without a membrane anchor was solved at 2.0A resolution. The enzyme has a fold completely different from those of the other known lytic transglycosylases. It contains two domains, the largest of which has a double-psi beta-barrel fold, similar to that of endoglucanase V from Humicola insolens. The smaller domain also has a beta-barrel fold topology, which is weakly related to that of the RNA-binding domain of ribosomal proteins L25 and TL5. A large groove separates the two domains, which can accommodate a glycan strand, as shown by molecular modelling. Several conserved residues, one of which is in a position equivalent to that of the catalytic acid of the H.insolens endoglucanase, flank this putative substrate-binding groove. Mutation of this residue, Asp308, abolished all activity of the enzyme, supporting the direct participation of this residue in catalysis.     

Identification and characterization of novel cell wall hydrolase CwlT: a two-domain autolysin exhibiting n-acetylmuramidase and DL-endopeptidase activities

A cell wall hydrolase homologue, Bacillus subtilis YddH (renamed CwlT), was determined to be a novel cell wall lytic enzyme. The cwlT gene is located in the region of an integrative and conjugative element (ICEBs1), and a cwlT-lacZ fusion experiment revealed the significant expression when mitomycin C was added to the culture. Judging from the Pfam data base, CwlT (cell wall lytic enzyme T (Two-catalytic domains)) has two hydrolase domains that exhibit high amino acid sequence similarity to dl-endopeptidases and relatively low similarity to lytic transglycosylases at the C and N termini, respectively. The purified C-terminal domain of CwlT (CwlT-C-His) could hydrolyze the linkage of d-gamma-glutamyl-meso-diaminopimelic acid in B. subtilis peptidoglycan, suggesting that the C-terminal domain acts as a dl-endopeptidase. On the other hand, the purified N-terminal domain (CwlT-N-His) could also hydrolyze the peptidoglycan of B. subtilis. However, on reverse-phase HPLC and mass spectrometry (MS) and MS-MS analyses of the reaction products by CwlT-N-His, this domain was determined to act as an N-acetylmuramidase and not a lytic transglycosylase. Moreover, the site-directed mutagenesis analysis revealed that Glu-87 and Asp-94 are sites related with the cell wall lytic activity. Because the amino acid sequence of the N-terminal domain of CwlT exhibits low similarity compared with those of the soluble lytic transglycosylase and muramidase (goose lysozyme), this domain represents "a new category of cell wall hydrolases."     

Peptidoglycan maturation enzymes affect flagellar functionality in bacteria

The flagellar machinery is a highly complex organelle composed of a free rotating flagellum and a fixed stator that converts energy into movement. The assembly of the flagella and the stator requires interactions with the peptidoglycan layer through which the organelle has to pass for externalization. Lytic transglycosylases are peptidoglycan degrading enzymes that cleave the sugar backbone of peptidoglycan layer. We show that an endogenous lytic transglycosylase is required for full motility of Helicobacter pylori and colonization of the gastric mucosa. Deficiency of motility resulted from a paralysed phenotype implying an altered ability to generate flagellar rotation. Similarly, another Gram‐negative pathogen Salmonella typhimurium and the Gram‐positive pathogen Listeria monocytogenes required the activity of lytic transglycosylases, Slt or MltC, and a glucosaminidase (Auto), respectively, for full motility. Furthermore, we show that in absence of the appropriate lytic transglycosylase, the flagellar motor protein MotB from H. pylori does not localize properly to the bacterial pole. We present a new model involving the maturation of the surrounding peptidoglycan for the proper anchoring and functionality of the flagellar motor.     

AtlA functions as a peptidoglycan lytic transglycosylase in the Neisseria gonorrhoeae type IV secretion system

Type IV secretion systems require peptidoglycan lytic transglycosylases for efficient secretion, but the function of these enzymes is not clear. The type IV secretion system gene cluster of Neisseria gonorrhoeae encodes two peptidoglycan transglycosylase homologues. One, LtgX, is similar to peptidoglycan transglycosylases from other type IV secretion systems. The other, AtlA, is similar to endolysins from bacteriophages and is not similar to any described type IV secretion component. We characterized the enzymatic function of AtlA in order to examine its role in the type IV secretion system. Purified AtlA was found to degrade macromolecular peptidoglycan and to produce 1,6-anhydro peptidoglycan monomers, characteristic of lytic transglycosylase activity. We found that AtlA can functionally replace the lambda endolysin to lyse Escherichia coli. In contrast, a sensitive measure of lysis demonstrated that AtlA does not lyse gonococci expressing it or gonococci cocultured with an AtlA-expressing strain. The gonococcal type IV secretion system secretes DNA during growth. A deletion of ltgX or a substitution in the putative active site of AtlA severely decreased DNA secretion. These results indicate that AtlA and LtgX are actively involved in type IV secretion and that AtlA is not involved in lysis of gonococci to release DNA. This is the first demonstration that a type IV secretion peptidoglycanase has lytic transglycosylase activity. These data show that AtlA plays a role in type IV secretion of DNA that requires peptidoglycan breakdown without cell lysis.     

Neisseria gonorrhoeae uses two lytic transglycosylases to produce cytotoxic peptidoglycan monomers

Peptidoglycan fragments released by Neisseria gonorrhoeae contribute to the inflammation and ciliated cell death associated with gonorrhea and pelvic inflammatory disease. However, little is known about the production and release of these fragments during bacterial growth. Previous studies demonstrated that one lytic transglycosylase, LtgA, was responsible for the production of approximately half of the released peptidoglycan monomers. Systematic mutational analysis of other putative lytic transglycosylase genes identified lytic transglycosylase D (LtgD) as responsible for release of peptidoglycan monomers from gonococci. An ltgA ltgD double mutant was found not to release peptidoglycan monomers and instead released large, soluble peptidoglycan fragments. In pulse-chase experiments, recycled peptidoglycan was not found in cytoplasmic extracts from the ltgA ltgD mutant as it was for the wild-type strain, indicating that generation of anhydro peptidoglycan monomers by lytic transglycosylases facilitates peptidoglycan recycling. The ltgA ltgD double mutant showed no growth abnormalities or cell separation defects, suggesting that these enzymes are involved in pathogenesis but not necessary for normal growth.     

Mutation of a single lytic transglycosylase causes aberrant septation and inhibits cell separation of Neisseria gonorrhoeae

The function of lytic peptidoglycan transglycosylases is poorly understood. Single lytic transglycosylase mutants of Escherichia coli have no growth phenotype. By contrast, mutation of Neisseria gonorrhoeae ltgC inhibited cell separation without affecting peptidoglycan monomer production. Thus, LtgC has a dedicated function in gonococcal cell division.     

A peptidoglycan hydrolase similar to bacteriophage endolysins acts as an autolysin in Neisseria gonorrhoeae

We have identified a gene encoding an autolysin (atlA) from Neisseria gonorrhoeae . The deduced amino acid sequence of AtlA shows significant similarity to the peptidoglycan degrading transglycosylases (endolysins) of bacteriophages lambda and P2, suggesting that the encoded protein also functions in peptidoglycan hydrolysis. An atlA mutant was identical to the wild-type strain in exponential growth rate, but demonstrated reduced lysis and peptidoglycan turnover in the stationary phase of growth. When transferred into a buffer solution, at a pH non-permissive for other gonococcal autolysins, an autolytic activity was detectable in the wild-type strain that was not present in the mutant. The most dramatic phenotype of the mutant occurred after extended time in stationary phase. After approximately 16 h in stationary phase, both strains underwent an apparent replication event, after which the wild-type strain died rapidly whereas the atlA mutant survived considerably longer. Even after both the wild-type and mutant cells were dead, many of the mutant cells maintained intact morphology, whereas the wild-type cells were lysed. These results suggest that AtlA is a peptidoglycan transglycosylase related to bacteriophage endolysins and acts as an autolysin in the stationary phase.     

Substrate binding affinity of Pseudomonas aeruginosa membrane-bound lytic transglycosylase B by hydrogen-deuterium exchange MALDI MS

Lytic transglycosylases cleave the beta-(1-->4)-glycosidic bond in the bacterial cell wall heteropolymer, peptidoglycan, between the N-acetylmuramic acid (MurNAc) and N-acetylglucosamine (GlcNAc) residues with the concomitant formation of a 1,6-anhydromuramoyl residue. With 72% amino acid sequence identity between the enzymes, the theoretical structure of the membrane-bound lytic transglycosylase B (MltB) from Psuedomonas aeruginosa was modeled on the known crystal structure of Escherichia coli Slt35, the soluble derivative of its MltB. Of the twelve residues in Slt35 known to make contacts with peptidoglycan derivatives in Slt35, nine exist in the same position in the P. aeruginosa homologue, with two others only slightly displaced. To probe the binding properties of an engineered soluble form of the P. aeruginosa MltB, a SUPREX method involving hydrogen/deuterium exchange coupled with MALDI mass spectrometry detection was developed. Dissociation constants were calculated for a series of peptidoglycan components and compared to those obtained by difference UV absorption spectroscopy. These data indicated that GlcNAc alone does not bind to MltB with any measurable affinity but it does contribute to the binding of GlcNAc-MurNAc-dipeptide. With the MurNAc series of ligands, significant binding contributions are made through both the N-acetyl and C-3 lactyl moieties of the aminosugar with additional contributions to binding provided by associated peptides.     

Overproduction of inactive variants of the murein synthase PBP1B causes lysis in Escherichia coli

Penicillin-binding protein 1B (PBP1B) of Escherichia coli is a bifunctional murein synthase containing both a transpeptidase domain and a transglycosylase domain. The protein is present in three forms (alpha, beta, and gamma) which differ in the length of their N-terminal cytoplasmic region. Expression plasmids allowing the production of native PBP1B or of PBP1B variants with an inactive transpeptidase or transglycosylase domain or both were constructed. The inactive domains contained a single amino acid exchange in an essential active-site residue. Overproduction of the inactive PBP1B variants, but not of the active proteins, caused lysis of wild-type cells. The cells became tolerant to lysis by inactive PBP1B at a pH of 5.0, which is similar to the known tolerance for penicillin-induced lysis under acid pH conditions. Lysis was also reduced in mutant strains lacking several murein hydrolases. In particular, a strain devoid of activity of all known lytic transglycosylases was virtually tolerant, indicating that mainly the lytic transglycosylases are responsible for the observed lysis effect. A possible structural interaction between PBP1B and murein hydrolases in vivo by the formation of a multienzyme complex is discussed.     

Role of Ser216 in the mechanism of action of membrane-bound lytic transglycosylase B: further evidence for substrate-assisted catalysis

Lytic transglycosylases cleave the beta-(1-->4)-glycosidic bond in the bacterial cell wall heteropolymer peptidoglycan between the N-acetylmuramic acid (MurNAc) and N-acetylglucosamine (GlcNAc) residues with the concomitant formation of a 1,6-anhydromuramoyl residue. Based on sequence alignments, Ser216 in Pseudomonas aeruginosa membrane-bound lytic transglycosylase B (MltB) was targeted for replacement with alanine to delineate its role in the enzyme's mechanism of action. The specific activity of the Ser216-->Ala MltB derivative was less than 12% of that for the wild-type enzyme, while its substrate binding affinity remained virtually unaltered. These data are in agreement with a role of Ser216 in orienting the N-acetyl group on MurNAc at the -1 subsite of MltB for its participation in a substrate-assisted mechanism of action.     

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.     

The role of peptidoglycan structure and structural dynamics during endospore dormancy and germination

Dormant, bacterial endospores are the most resistant living structures known. The spore cell wall (cortex) maintains dormancy, core dehydration, and heat resistance. The cortex peptidoglycan has a unique, spore specific structure that enables it to fulfill its role. The cross-linking index of spore cortex peptidoglycan is very low, occurring at only 2.9% of the muramic acid residues compared to 33% in vegetative cells. The level of cross-linking of the cortex may be important in maintaining spore dormancy and heat resistance. Approximately 50% of the muramic acid residues in spore cortex are substituted with muramic -lactam. This modification is spore specific and is the major characteristic feature of the cortex. The muramic -lactam has no apparent role in establishing core dehydration, maintaining dormancy or heat resistance. However, the muramic -lactam residues are necessary for spore cortex hydrolysis during germination. They constitute part of the substrate recognition profile of the germination specific lytic enzymes (GSLEs) which are responsible for cortex hydrolysis.Germination results in loss of dormant spore properties and hydrolysis of the cortex is essential for later germination events and outgrowth. Application of muropeptide analysis to determine peptidoglycan structural dynamics during germination has revealed an unexpected degree of complexity in peptidoglycan hydrolysis. At least three hydrolytic activities, an N-acetyl glucosaminidase, a lytic transglycosylase and a possible amidase, are involved. A non-hydrolytic acitivity, likely to be an epimerase of muramic acid also occurs early during germination.The lytic transglycosylase generates anhydro-muropeptides which are released during germination and may be recycled during outgrowth to form part of the new vegetative cell wall.     

Crystal structure of Escherichia coli lytic transglycosylase Slt35 reveals a lysozyme-like catalytic domain with an EF-hand.

BACKGROUND: Lytic transglycosylases are bacterial muramidases that catalyse the cleavage of the beta- 1,4-glycosidic bond between N-acetylmuramic acid (MurNAc) and N-acetylglucosamine (GlcNAc) in peptidoglycan with concomitant formation of a 1,6-anhydrobond in the MurNAc residue. These muramidases play an important role in the metabolism of the bacterial cell wall and might therefore be potential targets for the rational design of antibacterial drugs. One of the lytic transglycosylases is Slt35, a naturally occurring soluble fragment of the outer membrane bound lytic transglycosylase B (MltB) from Escherichia coli. RESULTS: The crystal structure of Slt35 has been determined at 1.7 A resolution. The structure reveals an ellipsoid molecule with three domains called the alpha, beta and core domains. The core domain is sandwiched between the alpha and beta domains. Its fold resembles that of lysozyme, but it contains a single metal ion binding site in a helix-loop-helix module that is surprisingly similar to the eukaryotic EF-hand calcium-binding fold. Interestingly, the Slt35 EF-hand loop consists of 15 residues instead of the usual 12 residues. The only other prokaryotic proteins with an EF-hand motif identified so far are the D-galactose-binding proteins. Residues from the alpha and core domains form a deep groove where the substrate fragment GlcNAc can be bound. CONCLUSIONS: The three-domain structure of Slt35 is completely different from the Slt70 structure, the only other lytic transglycosylase of known structure. Nevertheless, the core domain of Slt35 closely resembles the fold of the catalytic domain of Slt70, despite the absence of any obvious sequence similarity. Residue Glu162 of Slt35 is in an equivalent position to Glu478, the catalytic acid/base of Slt70. GlcNAc binds close to Glu162 in the deep groove. Moreover, mutation of Glu162 into a glutamine residue yielded a completely inactive enzyme. These observations indicate the location of the active site and strongly support a catalytic role for Glu162.     

Structure of the bacteriophage phi KZ lytic transglycosylase gp144

Lytic transglycosylases are enzymes that act on the peptidoglycan of bacterial cell walls. They cleave the glycosidic linkage between N-acetylmuramoyl and N-acetylglucosaminyl residues with the concomitant formation of a 1,6-anhydromuramoyl product. The x-ray structure of the lytic transglycosylase gp144 from the Pseudomonas bacteriophage phi KZ has been determined to 2.5-A resolution. This protein is probably employed by the bacteriophage in the late stage of the virus reproduction cycle to destroy the bacterial cell wall to release the phage progeny. phi KZ gp144 is a 260-residue alpha-helical protein composed of a 70-residue N-terminal cell wall-binding domain and a C-terminal catalytic domain. The fold of the N-terminal domain is similar to the peptidoglycan-binding domain from Streptomyces albus G D-Ala-D-Ala carboxypeptidase and to the N-terminal prodomain of human metalloproteinases that act on extracellular matrices. The C-terminal catalytic domain of gp144 has a structural similarity to the catalytic domain of the transglycosylase Slt70 from Escherichia coli and to lysozymes. The gp144 catalytic domain has an elongated groove that can bind at least five sugar residues at sites A-E. As in other lysozymes, the peptidoglycan cleavage (catalyzed by Glu 115 in gp144) occurs between sugar-binding subsites D and E. The x-ray structure of the phi KZ transglycosylase complexed with the chitotetraose (N-acetylglucosamine)(4) has been determined to 2.6-A resolution. The N-acetylglucosamine residues of the chitotetraose bind in sites A-D.     

Structural Analysis of a Specialized Type III Secretion System Peptidoglycan-cleaving Enzyme

The Gram-negative bacterium enteropathogenic Escherichia coli uses a syringe-like type III secretion system (T3SS) to inject virulence or “effector” proteins into the cytoplasm of host intestinal epithelial cells. To assemble, the T3SS must traverse both bacterial membranes, as well as the peptidoglycan layer. Peptidoglycan is made of repeating N-acetylmuramic acid and N-acetylglucosamine disaccharides cross-linked by pentapeptides to form a tight mesh barrier. Assembly of many macromolecular machines requires a dedicated peptidoglycan lytic enzyme (PG-lytic enzyme) to locally clear peptidoglycan. Here we have solved the first structure of a T3SS-associated PG-lytic enzyme, EtgA from enteropathogenic E. coli. Unexpectedly, the active site of EtgA has features in common with both lytic transglycosylases and hen egg white lysozyme. Most notably, the β-hairpin region resembles that of lysozyme and contains an aspartate that aligns with lysozyme Asp-52 (a residue critical for catalysis), a conservation not observed in other previously characterized lytic transglycosylase families to which the conserved T3SS enzymes had been presumed to belong. Mutation of the EtgA catalytic glutamate, Glu-42, conserved across lytic transglycosylases and hen egg white lysozyme, and this differentiating aspartate diminishes type III secretion in vivo, supporting its essential role in clearing the peptidoglycan for T3SS assembly. Finally, we show that EtgA forms a 1:1 complex with the building block of the polymerized T3SS inner rod component, EscI, and that this interaction enhances PG-lytic activity of EtgA in vitro, collectively providing the necessary strict localization and regulation of the lytic activity to prevent overall cell lysis.