A Fail-Safe Mechanism in the Septal Ring Assembly Pathway Generated by the Sequential Recruitment of Cell Separation Amidases and Their Activators

During cytokinesis in Escherichia coli, the peptidoglycan (PG) layer produced by the divisome must be split to promote cell separation. Septal PG splitting is mediated by the amidases: AmiA, AmiB, and AmiC. To efficiently hydrolyze PG, the amidases must be activated by LytM domain factors. EnvC specifically activates AmiA and AmiB, while NlpD specifically activates AmiC. Here, we used an exportable, superfolding variant of green fluorescent protein (GFP) to demonstrate that AmiB, like its paralog AmiC, is recruited to the division site by an N-terminal targeting domain. The results of colocalization experiments indicate that EnvC is recruited to the division site well before its cognate amidase AmiB. Moreover, we show that EnvC and AmiB have differential FtsN requirements for their localization. EnvC accumulates at division sites independently of this essential division protein, whereas AmiB localization is FtsN dependent. Interestingly, we also report that AmiB and EnvC are recruited to division sites independently of one another. The same is also true for AmiC and NlpD. However, unlike EnvC, we find that NlpD shares an FtsN-dependent localization with its cognate amidase. Importantly, when septal PG synthesis is blocked by cephalexin, both EnvC and NlpD are recruited to septal rings, whereas the amidases fail to localize. Our results thus suggest that the order in which cell separation amidases and their activators localize to the septal ring relative to other components serves as a fail-safe mechanism to ensure that septal PG synthesis precedes the expected burst of PG hydrolysis at the division site, accompanied by amidase recruitment.     

Daughter cell separation is controlled by cytokinetic ring‐activated cell wall hydrolysis

During bacterial cytokinesis, hydrolytic enzymes are used to split wall material shared by adjacent daughter cells to promote their separation. Precise control over these enzymes is critical to prevent breaches in wall integrity that can cause cell lysis. How these potentially lethal hydrolases are regulated has remained unknown. Here, we investigate the regulation of cell wall turnover at the Escherichia coli division site. We show that two components of the division machinery with LytM domains (EnvC and NlpD) are direct regulators of the cell wall hydrolases (amidases) responsible for cell separation (AmiA, AmiB and AmiC). Using in vitro cell wall cleavage assays, we show that EnvC activates AmiA and AmiB, whereas NlpD activates AmiC. Consistent with these findings, we show that an unregulated EnvC mutant requires functional AmiA or AmiB but not AmiC to induce cell lysis, and that the loss of NlpD phenocopies an AmiC^? defect. Overall, our results suggest that cellular amidase activity is regulated spatially and temporally by coupling their activation to the assembly of the cytokinetic ring.     

LytM factors affect the recruitment of autolysins to the cell division site in Caulobacter crescentus

Most bacteria possess a peptidoglycan cell wall that determines their morphology and provides mechanical robustness during osmotic challenges. The biosynthesis of this structure is achieved by a large set of synthetic and lytic enzymes with varying substrate specificities. Although the biochemical functions of these proteins are conserved and well‐investigated, the precise roles of individual factors and the regulatory mechanisms coordinating their activities in time and space remain incompletely understood. Here, we comprehensively analyze the autolytic machinery of the alphaproteobacterial model organism Caulobacter crescentus, with a specific focus on LytM‐like endopeptidases, soluble lytic transglycosylases and amidases. Our data reveal a high degree of redundancy within each protein family but also specialized functions for individual family members under stress conditions. In addition, we identify two lytic transglycosylases and an amidase as new divisome components that are recruited to midcell at distinct stages of the cell cycle. The midcell localization of these proteins is affected by two LytM factors with degenerate catalytic domains, DipM and LdpF, which may serve as regulatory hubs coordinating the activities of multiple autolytic enzymes during cell constriction and fission respectively. These findings set the stage for in‐depth studies of the molecular mechanisms that control peptidoglycan remodeling in C. crescentus.     

DipM links peptidoglycan remodelling to outer membrane organization in Caulobacter

Cell division in Gram‐negative organisms requires coordinated invagination of the multilayered cell envelope such that each daughter receives an intact inner membrane, peptidoglycan (PG) layer and outer membrane (OM). Here, we identify DipM, a putative LytM endopeptidase in Caulobacter crescentus, and show that it plays a critical role in maintaining cell envelope architecture during growth and division. DipM localized to the division site in an FtsZ‐dependent manner via its PG‐binding LysM domains. Although not essential for viability, ΔdipM cells exhibited gross morphological defects, including cell widening and filamentation, indicating a role in cell shape maintenance and division that we show requires its LytM domain. Strikingly, cells lacking DipM also showed OM blebbing at the division site, at cell poles and along the cell body. Cryo electron tomography of sacculi isolated from cells depleted of DipM revealed marked thickening of the PG as compared to wild type, which we hypothesize leads to loss of trans‐envelope contacts between components of the Tol–Pal complex. We conclude that DipM is required for normal envelope invagination during division and to maintain a sacculus of constant thickness that allows for maintenance of OM connections throughout the cell envelope.     

A protein critical for cell constriction in the Gram‐negative bacterium Caulobacter crescentus localizes at the division site through its peptidoglycan‐binding LysM domains

During division of Gram‐negative bacteria, invagination of the cytoplasmic membrane and inward growth of the peptidoglycan (PG) are followed by the cleavage of connective septal PG to allow cell separation. This PG splitting process requires temporal and spatial regulation of cell wall hydrolases. In Escherichia coli, LytM factors play an important role in PG splitting. Here we identify and characterize a member of this family (DipM) in Caulobacter crescentus. Unlike its E. coli counterparts, DipM is essential for viability under fast‐growth conditions. Under slow‐growth conditions, the ΔdipM mutant displays severe defects in cell division and FtsZ constriction. Consistent with its function in division, DipM colocalizes with the FtsZ ring during the cell cycle. Mutagenesis suggests that the LytM domain of DipM is essential for protein function, despite being non‐canonical. DipM also carries two tandems of the PG‐binding LysM domain that are sufficient for FtsZ ring localization. Localization and fluorescence recovery after photobleaching microscopy experiments suggest that DipM localization is mediated, at least in part, by the ability of the LysM tandems to distinguish septal, multilayered PG from non‐septal, monolayered PG.     

The crystal structure of the cell division amidase AmiC reveals the fold of the AMIN domain,a new peptidoglycan binding domain

Binary fission is the ultimate step of the prokaryotic cell cycle. In Gram‐negative bacteria like Escherichia coli, this step implies the invagination of three biological layers (cytoplasmic membrane, peptidoglycan and outer membrane), biosynthesis of the new poles and eventually, daughter cells separation. The latter requires the coordinated action of the N‐acetylmuramyl‐L‐alanine amidases AmiA/B/C and their LytM activators EnvC and NlpD to cleave the septal peptidoglycan. We present here the 2.5 Å crystal structure of AmiC which includes the first report of an AMIN domain structure, a β‐sandwich of two symmetrical four‐stranded β‐sheets exposing highly conserved motifs on the two outer faces. We show that this N‐terminal domain, involved in the localization of AmiC at the division site, is a new peptidoglycan‐binding domain. The C‐terminal catalytic domain shows an auto‐inhibitory alpha helix obstructing the active site. AmiC lacking this helix exhibits by itself an activity comparable to that of the wild type AmiC activated by NlpD. We also demonstrate the interaction between AmiC and NlpD by microscale thermophoresis and confirm the importance of the active site blocking alpha helix in the regulation of the amidase activity.     

Peptidoglycan hydrolysis mediated by the amidase AmiC and its LytM activator NlpD is critical for cell separation and virulence in the phytopathogen Xanthomonas campestris

The essential stages of bacterial cell separation are described as the synthesis and hydrolysis of septal peptidoglycan (PG). The amidase, AmiC, which cleaves the peptide side‐chains linked to the glycan strands, contributes critically to this process and has been studied extensively in model strains of Escherichia coli. However, insights into the contribution of this protein to other processes in the bacterial cell have been limited. Xanthomonas campestris pv. campestris (Xcc) is a phytopathogen that causes black rot disease in many economically important plants. We investigated how AmiC and LytM family regulators, NlpD and EnvC, contribute to virulence and cell separation in this organism. Biochemical analyses of purified AmiC demonstrated that it could hydrolyse PG and its activity could be potentiated by the presence of the regulator NlpD. We also established that deletion of the genes encoding amiC1 or nlpD led to a reduction in virulence as well as effects on colony‐forming units and cell morphology. Moreover, further genetic and biochemical evidence showed that AmiC1 and NlpD affect the secretion of type III effector XC3176 and hypersensitive response (HR) induction in planta. These findings indicate that, in addition to their well‐studied role(s) in cell separation, AmiC and NlpD make an important contribution to the type III secretion (T3S) and virulence regulation in this important plant pathogen.     

FtsEX is required for CwlO peptidoglycan hydrolase activity during cell wall elongation in Bacillus subtilis

The peptidoglycan (PG) sacculus, a meshwork of polysaccharide strands cross‐linked by short peptides, protects bacterial cells against osmotic lysis. To enlarge this covalently closed macromolecule, PG hydrolases must break peptide cross‐links in the meshwork to allow insertion of new glycan strands between the existing ones. In the rod‐shaped bacterium Bacillus subtilis, cell wall elongation requires two redundant endopeptidases, CwlO and LytE. However, it is not known how these potentially autolytic enzymes are regulated to prevent lethal breaches in the cell wall. Here, we show that the ATP‐binding cassette transporter‐like FtsEX complex is required for CwlO activity. In Escherichia coli, FtsEX is thought to harness ATP hydrolysis to activate unrelated PG hydrolases during cell division. Consistent with this regulatory scheme, B. subtilis FtsE mutants that are unable to bind or hydrolyse ATP cannot activate CwlO. Finally, we show that in cells depleted of both CwlO and LytE, the PG synthetic machinery continues moving circumferentially until cell lysis, suggesting that cross‐link cleavage is not required for glycan strand polymerization. Overall, our data support a model in which the FtsEX complex is a remarkably flexible regulatory module capable of controlling a diverse set of PG hydrolases during growth and division in different organisms.     

Cell Separation in Vibrio cholerae Is Mediated by a Single Amidase Whose Action Is Modulated by Two Nonredundant Activators

Synthesis and hydrolysis of septal peptidoglycan (PG) are critical processes at the conclusion of cell division that enable separation of daughter cells. Cleavage of septal PG is mediated by PG amidases, hydrolytic enzymes that release peptide side chains from the glycan strand. Most gammaproteobacteria, including Escherichia coli, encode several functionally redundant periplasmic amidases. However, members of the Vibrio genus, including the enteric pathogen Vibrio cholerae, encode only a single PG amidase, AmiB. Here, we show that V. cholerae AmiB is crucial for cell division and growth. Genetic and biochemical analyses indicated that AmiB is regulated by two activators, EnvC and NlpD, at least one of which is required for AmiB''s localization to the cell division site. Localization of the activators (and thus of AmiB) is dependent upon the cell division protein FtsN. These factors mediate septal PG cleavage in E. coli as well; however, their precise roles vary between the two organisms in a number of ways. Notably, even though V. cholerae EnvC and NlpD appear to be functionally redundant under most growth conditions tested, NlpD is specifically required for intestinal colonization in the infant mouse model of cholera and for V. cholerae resistance against bile salts, perhaps due to environmental regulation of AmiB or its activators. Collectively, our findings reveal that although the cellular components that enable cleavage of septal PG appear to be generally conserved between E. coli and V. cholerae, they can be combined into diverse functional regulatory networks.     

Early midcell localization of Escherichia coli PBP4 supports the function of peptidoglycan amidases

Insertion of new material into the Escherichia coli peptidoglycan (PG) sacculus between the cytoplasmic membrane and the outer membrane requires a well-organized balance between synthetic and hydrolytic activities to maintain cell shape and avoid lysis. Since most bacteria carry multiple enzymes carrying the same type of PG hydrolytic activity, we know little about the specific function of given enzymes. Here we show that the DD-carboxy/endopeptidase PBP4 localizes in a PBP1A/LpoA and FtsEX dependent fashion at midcell during septal PG synthesis. Midcell localization of PBP4 requires its non-catalytic domain 3 of unknown function, but not the activity of PBP4 or FtsE. Microscale thermophoresis with isolated proteins shows that PBP4 interacts with NlpI and the FtsEX-interacting protein EnvC, an activator of amidases AmiA and AmiB, which are needed to generate denuded glycan strands to recruit the initiator of septal PG synthesis, FtsN. The domain 3 of PBP4 is needed for the interaction with NlpI and EnvC, but not PBP1A or LpoA. In vivo crosslinking experiments confirm the interaction of PBP4 with PBP1A and LpoA. We propose that the interaction of PBP4 with EnvC, whilst not absolutely necessary for mid-cell recruitment of either protein, coordinates the activities of PBP4 and the amidases, which affects the formation of denuded glycan strands that attract FtsN. Consistent with this model, we found that the divisome assembly at midcell was premature in cells lacking PBP4, illustrating how the complexity of interactions affect the timing of cell division initiation.     

DipM,a new factor required for peptidoglycan remodelling during cell division in Caulobacter crescentus

In bacteria, cytokinesis is dependent on lytic enzymes that facilitate remodelling of the cell wall during constriction. In this work, we identify a thus far uncharacterized periplasmic protein, DipM, that is required for cell division and polarity in Caulobacter crescentus. DipM is composed of four peptidoglycan binding (LysM) domains and a C‐terminal lysostaphin‐like (LytM) peptidase domain. It binds to isolated murein sacculi in vitro, and is recruited to the site of constriction through interaction with the cell division protein FtsN. Mutational analyses showed that the LysM domains are necessary and sufficient for localization of DipM, while its peptidase domain is essential for function. Consistent with a role in cell wall hydrolysis, DipM was found to interact with purified murein sacculi in vitro and to induce cell lysis upon overproduction. Its inactivation causes severe defects in outer membrane invagination, resulting in a significant delay between cytoplasmic compartmentalization and final separation of the daughter cells. Overall, these findings indicate that DipM is a periplasmic component of the C. crescentus divisome that facilitates remodelling of the peptidoglycan layer and, thus, coordinated constriction of the cell envelope during the division process.     

The cell wall amidase AmiB is essential for Pseudomonas aeruginosa cell division,drug resistance and viability

The physiological function of cell wall amidases has been investigated in several proteobacterial species. In all cases, they have been implicated in the cleavage of cell wall material synthesized by the cytokinetic ring. Although typically non‐essential, this activity is critical for daughter cell separation and outer membrane invagination during division. In Escherichia coli, proteins with LytM domains also participate in cell separation by stimulating amidase activity. Here, we investigated the function of amidases and LytM proteins in the opportunistic pathogen Pseudomonas aeruginosa. In agreement with studies in other organisms, ^PaAmiB and three LytM proteins were found to play crucial roles in P. aeruginosa cell separation, envelope integrity and antibiotic resistance. Importantly, the phenotype of amidase‐defective P. aeruginosa cells also differed in informative ways from the E. coli paradigm; ^PaAmiB was found to be essential for viability and the successful completion of cell constriction. Our results thus reveal a key role for amidase activity in cytokinetic ring contraction. Furthermore, we show that the essential function of ^PaAmiB can be bypassed in mutants activated for a Cpx‐like envelope stress response, suggesting that this signaling system may elicit the repair of division machinery defects in addition to general envelope damage.     

Cell division is antagonized by the activity of peptidoglycan endopeptidases that promote cell elongation

A peptidoglycan (PG) cell wall composed of glycans crosslinked by short peptides surrounds most bacteria and protects them against osmotic rupture. In Escherichia coli, cell elongation requires crosslink cleavage by PG endopeptidases to make space for the incorporation of new PG material throughout the cell cylinder. Cell division, on the contrary, requires the localized synthesis and remodeling of new PG at midcell by the divisome. Little is known about the factors that modulate transitions between these two modes of PG biogenesis. In a transposon-insertion sequencing screen to identify mutants synthetically lethal with a defect in the division protein FtsP, we discovered that mutants impaired for cell division are sensitive to elevated activity of the endopeptidases. Increased endopeptidase activity in these cells was shown to interfere with the assembly of mature divisomes, and conversely, inactivation of MepS was found to suppress the lethality of mutations in essential division genes. Overall, our results are consistent with a model in which the cell elongation and division systems are in competition with one another and that control of PG endopeptidase activity represents an important point of regulation influencing the transition from elongation to the division mode of PG biogenesis.     

LytM-Domain Factors Are Required for Daughter Cell Separation and Rapid Ampicillin-Induced Lysis in Escherichia coli

Bacterial cytokinesis is coupled to the localized synthesis of new peptidoglycan (PG) at the division site. This newly generated septal PG is initially shared by the daughter cells. In Escherichia coli and other gram-negative bacteria, it is split shortly after it is made to promote daughter cell separation and allow outer membrane constriction to closely follow that of the inner membrane. We have discovered that the LytM (lysostaphin)-domain containing factors of E. coli (EnvC, NlpD, YgeR, and YebA) are absolutely required for septal PG splitting and daughter cell separation. Mutants lacking all LytM factors form long cell chains with septa containing a layer of unsplit PG. Consistent with these factors playing a direct role in septal PG splitting, both EnvC-mCherry and NlpD-mCherry fusions were found to be specifically recruited to the division site. We also uncovered a role for the LytM-domain factors in the process of β-lactam-induced cell lysis. Compared to wild-type cells, mutants lacking LytM-domain factors were delayed in the onset of cell lysis after treatment with ampicillin. Moreover, rather than lysing from midcell lesions like wild-type cells, LytM⁻ cells appeared to lyse through a gradual loss of cell shape and integrity. Overall, the phenotypes of mutants lacking LytM-domain factors bear a striking resemblance to those of mutants defective for the N-acetylmuramyl-l-alanine amidases: AmiA, AmiB, and AmiC. E. coli thus appears to rely on two distinct sets of putative PG hydrolases to promote proper cell division.Cytokinesis in Escherichia coli and other gram-negative bacteria proceeds via the coordinated constriction of their envelope layers (outer membrane, inner membrane, and peptidoglycan [PG]) (12, 13, 34, 89). This coordination is achieved by a multi-protein division machine referred to as the septal ring or divisome (20). Assembly of the septal ring begins with the polymerization of the bacterial tubulin protein, FtsZ, into a ring structure just underneath the inner membrane at the prospective site of cell division (8). Once formed, this so-called Z-ring facilitates the recruitment of a number of essential and nonessential division proteins to the division site for the assembly of the trans-envelope divisome organelle (20).A major function of the cytokinetic machinery is to promote the synthesis of the PG layer that will eventually fortify the new poles of the developing daughter cells. PG is a polysaccharide polymer composed of repeating units of N-acetyl-glucosamine (GlcNAc) and N-acetyl-muramic acid (MurNAc) linked by a β-1,4-glycosidic bond (46). Attached to the MurNAc sugar is a short peptide that is used to form cross-links between adjacent polysaccharide strands (46). Such cross-links allow for the construction of a cell-shaped PG meshwork that surrounds the cell membrane and protects it from osmotic rupture.A new wave of zonal PG synthesis is initiated at the division site during each cell cycle (23, 25, 72, 77, 91). Several of the major PG synthases called penicillin-binding proteins are components of the divisome organelle and play important roles in the synthesis of PG during division (7, 21, 62, 67, 73, 74, 80, 81, 88, 90). The septal PG layer produced by these and perhaps other components of the divisome is thought to be initially shared by the daughter cells (46). In gram-positive bacteria, this septal PG layer is typically split some time after the daughter cells have been compartmentalized by membrane fusion (11). In gram-negative bacteria, however, the septal PG layer is split shortly after it is formed to allow constriction of the outer membrane to closely follow that of the inner (cytoplasmic) membrane (12, 13, 34, 89). This gives rise to the characteristic constricted appearance of predivisional cells of E. coli and its relatives.PG hydrolysis is required to promote septal PG splitting and eventual daughter cell separation (87). E. coli, like many bacteria, encodes a vast array of factors with known or predicted PG hydrolase activity (at least 30 genes and 11 different protein families) (29, 31, 87). In most cases, the loss of individual PG hydrolase factors has little effect on growth and division, suggesting that there is significant functional overlap between the various hydrolases (87). This dearth of phenotypic information has consequently made it difficult to understand the physiological roles of PG hydrolases and identify the subset of these factors needed for septal PG splitting. An approach that has helped overcome this limitation in E. coli, however, has been the systematic deletion of all members of a particular PG hydrolase family from the genome (22, 44, 45, 63). Thus far, of all the families of PG hydrolases encoded by E. coli, the factors that play the predominant role in cell separation appear to be the LytC-type N-acetylmuramyl-l-alanine amidases: AmiA, AmiB, and AmiC (44, 45, 69). Loss of all three of these amidases results in a severe defect in cell separation and the formation of extremely long cell chains. This chaining phenotype can be exacerbated by the loss of members of other classes of PG hydrolases like the lytic transglycosylases or d,d-endopeptidases (44, 68). However, relative to strains defective for the amidases, mutants lacking multiple lytic transglycosylases or d,d-endopeptidases alone do not display significant chaining phenotypes in E. coli. These PG hydrolases therefore appear to be playing more of an ancillary role in cell separation.The LytM (lysostaphin/peptidase M23)-domain containing factors (referred to as LytM factors for convenience) are a widely distributed class of putative PG hydrolases that have been poorly characterized with regard to their role in PG biogenesis in E. coli and other bacteria (31). The most well-studied members of this family of factors, LytM and lysostaphin, are metallo-endopeptidases that cleave the pentaglycine cross-bridges found in staphylococcal PG (9, 30, 64). Based on this activity, other LytM factors are also likely to be PG hydrolases but with altered cleavage specificity because pentaglycine cross-bridges are only found among the staphylococci (75). Indeed, the LytM protein, gp13, from the Bacillus subtilis phage Φ29 was recently shown to be a d,d-endopeptidase that cleaves the meso-diaminopimelic acid-d-Ala cross-links of B. subtilis PG (17).E. coli encodes four factors with identifiable LytM-domains: EnvC, NlpD, YgeR, and YebA (29) (Fig. ​(Fig.1).1). Of the four, only EnvC has been studied in appreciable detail. EnvC⁻ mutants have a mild cell separation (chaining) defect when grown in medium containing salt and a severe division defect when grown at high temperatures in medium lacking salt (5, 42, 48, 71). In addition, purified EnvC protein was found to possess PG hydrolase activity using a gel-based zymogram assay, and an EnvC-green fluorescent protein (GFP) fusion exported to the periplasm via the Tat system was shown to be recruited to the division site (5). In all, these results support a model in which EnvC is targeted to the division site to participate directly in septal PG splitting and daughter cell separation.Open in a separate windowFIG. 1.Predicted domain structure of the E. coli LytM factors. Shown is a diagram depicting the predicted domain architecture of the four E. coli factors with identifiable LytM domains. Abbreviations: LytM, LytM domain; LysM, LysM PG-binding domain (29); CC, coiled coil; T, transmembrane domain; SS, signal sequence; SS*, lipoprotein signal sequence. The UniProtKB/Swiss-Prot accession numbers are as follows: EnvC (P37690), NlpD (P0ADA3), YebA (P0AFS9), and YgeR (Q46798).In the present study, we investigated the physiological role(s) of the entire set of E. coli LytM factors by generating mutant strains lacking all possible combinations of them. We found that, like the amidases, LytM factors play a critical role in daughter cell separation. Furthermore, studies of their subcellular localization revealed that NlpD is recruited to the division site along with EnvC, indicating that both of these LytM factors are likely to be participating directly in the septal PG splitting process. We also discovered that mutants lacking multiple LytM factors lyse more slowly and display an altered morphological response relative to wild-type (WT) cells when they are treated with ampicillin. This finding suggests that in addition to cell separation, LytM proteins play a role in the lytic mechanism of β-lactam antibiotics.     

Crystal Structure of the LasA Virulence Factor from Pseudomonas aeruginosa: Substrate Specificity and Mechanism of M23 Metallopeptidases

Pseudomonas aeruginosa is an opportunist Gram-negative bacterial pathogen responsible for a wide range of infections in immunocompromized individuals and is a leading cause of mortality in cystic fibrosis patients. A number of secreted virulence factors, including various proteolytic enzymes, contribute to the establishment and maintenance of Pseudomonas infection. One such is LasA, an M23 metallopeptidase related to autolytic glycylglycine endopeptidases such as Staphylococcus aureus lysostaphin and LytM, and to DD-endopeptidases involved in entry of bacteriophage to host bacteria. LasA is implicated in a range of processes related to Pseudomonas virulence, including stimulating ectodomain shedding of the cell surface heparan sulphate proteoglycan syndecan-1 and elastin degradation in connective tissue. Here we present crystal structures of active LasA as a complex with tartrate and in the uncomplexed form. While the overall fold resembles that of the other M23 family members, the LasA active site is less constricted and utilizes a different set of metal ligands. The active site of uncomplexed LasA contains a five-coordinate zinc ion with trigonal bipyramidal geometry and two metal-bound water molecules. Using these structures as a starting point, we propose a model for substrate binding by LasA that explains its activity against a wider range of substrates than those used by related lytic enzymes, and offer a catalytic mechanism for M23 metallopeptidases consistent with available structural and mutagenesis data. Our results highlight how LasA is a structurally distinct member of this endopeptidase family, consistent with its activity against a wider range of substrates and with its multiple roles in Pseudomonas virulence.     

A new factor stimulating peptidoglycan hydrolysis to separate daughter cells in Caulobacter crescentus

Cell division in Gram‐negative bacteria involves the co‐ordinated invagination of the three cell envelope layers to form two new daughter cell poles. This complex process starts with the polymerization of the tubulin‐like protein FtsZ into a Z‐ring at mid‐cell, which drives cytokinesis and recruits numerous other proteins to the division site. These proteins are involved in Z‐ring constriction, inner‐ and outer‐membrane invagination, peptidoglycan remodelling and daughter cell separation. Three papers in this issue of Molecular Microbiology, from the teams of Lucy Shapiro, Martin Thanbichler and Christine Jacobs‐Wagner, describe a novel protein, called DipM for Division Involved Protein with LysM domains, that is required for cell division in Caulobacter crescentus. DipM localizes to the mid‐cell during cell division, where it is necessary for the hydrolysis of the septal peptidoglycan to remodel the cell wall. Loss of DipM results in severe defects in cell envelope constriction, which is deleterious under fast‐growth conditions. State‐of‐the‐art microscopy experiments reveal that the peptidoglycan is thicker and that the cell wall is incorrectly organized in DipM‐depleted cells compared with wild‐type cells, demonstrating that DipM is essential for reorganizing the cell wall at the division site, for envelope invagination and cell separation in Caulobacter.     

Identification of the potential active site of the septal peptidoglycan polymerase FtsW

SEDS (Shape, Elongation, Division and Sporulation) proteins are widely conserved peptidoglycan (PG) glycosyltransferases that form complexes with class B penicillin-binding proteins (bPBPs, with transpeptidase activity) to synthesize PG during bacterial cell growth and division. Because of their crucial roles in bacterial morphogenesis, SEDS proteins are one of the most promising targets for the development of new antibiotics. However, how SEDS proteins recognize their substrate lipid II, the building block of the PG layer, and polymerize it into glycan strands is still not clear. In this study, we isolated and characterized dominant-negative alleles of FtsW, a SEDS protein critical for septal PG synthesis during bacterial cytokinesis. Interestingly, most of the dominant-negative FtsW mutations reside in extracellular loops that are highly conserved in the SEDS family. Moreover, these mutations are scattered around a central cavity in a modeled FtsW structure, which has been proposed to be the active site of SEDS proteins. Consistent with this, we found that these mutations blocked septal PG synthesis but did not affect FtsW localization to the division site, interaction with its partners nor its substrate lipid II. Taken together, these results suggest that the residues corresponding to the dominant-negative mutations likely constitute the active site of FtsW, which may aid in the design of FtsW inhibitors.     

The GpsB files: the truth is out there

Peptidoglycan (PG), an essential stress‐bearing component of the bacterial cell wall, is synthesised by penicillin binding proteins (PBPs). PG synthesis at the cell division septum is necessary for constructing new poles of progeny cells, and cells cannot elongate without inserting new PG in the side‐wall. The cell division regulator GpsB appears to co‐ordinate PG synthesis at the septum during division and at the side‐wall during elongation in rod‐shaped and ovococcoid Gram‐positive bacteria. How the control over PG synthesis is exerted is unknown. In this issue of Molecular Microbiology, Rued et al. show that in pneumococci GpsB forms complexes with PBP2a and PBP2b, and that deletion or depletion of GpsB prevents closure of the septal ring that in itself is PBP2x‐dependent. Loss of GpsB can be suppressed by spontaneous mutations, including within the gene encoding the only PP2C Ser/Thr phosphatase in Streptococcus pneumoniae, indicating that GpsB plays a key – but unknown – role in protein phosphorylation in pneumococci. Rued et al. combine phenotypic and genotypic analyses of mutant strains that suggest discrepancies in the literature concerning GpsB might have arisen from accumulation of unidentified suppressors, highlighting the importance and power of strain validation and whole genome sequencing in this context.     

How FtsEX localizes to the Z ring and interacts with FtsA to regulate cell division

In Escherichia coli, FtsEX, a member of the ABC transporter superfamily, is involved in regulating the assembly and activation of the divisome to couple cell wall synthesis to cell wall hydrolysis at the septum. Genetic studies indicate FtsEX acts on FtsA to begin the recruitment of the downstream division proteins but blocks septal PG synthesis until a signal is received that divisome assembly is complete. However, the details of how FtsEX localizes to the Z ring and how it interacts with FtsA are not clear. Our results show that recruitment of FtsE and FtsX is codependent and suggest that the FtsEX complex is recruited through FtsE interacting with the conserved tail of FtsZ (CCTP), thus adding FtsEX to a growing list of proteins that interacts with the CCTP of FtsZ. Furthermore, we find that the N‐terminus of FtsX is not required for FtsEX localization to the Z ring but is required for its functions in cell division indicating that it interacts with FtsA. Taken together, these results suggest that FtsEX first interacts with FtsZ to localize to the Z ring and then interacts with FtsA to promote divisome assembly and regulate septal PG synthesis.     

Specialized Peptidoglycan Hydrolases Sculpt the Intra-bacterial Niche of Predatory Bdellovibrio and Increase Population Fitness

Bdellovibrio are predatory bacteria that have evolved to invade virtually all Gram-negative bacteria, including many prominent pathogens. Upon invasion, prey bacteria become rounded up into an osmotically stable niche for the Bdellovibrio, preventing further superinfection and allowing Bdellovibrio to replicate inside without competition, killing the prey bacterium and degrading its contents. Historically, prey rounding was hypothesized to be associated with peptidoglycan (PG) metabolism; we found two Bdellovibrio genes, bd0816 and bd3459, expressed at prey entry and encoding proteins with limited homologies to conventional dacB/PBP4 DD-endo/carboxypeptidases (responsible for peptidoglycan maintenance during growth and division). We tested possible links between Bd0816/3459 activity and predation. Bd3459, but not an active site serine mutant protein, bound β-lactam, exhibited DD-endo/carboxypeptidase activity against purified peptidoglycan and, importantly, rounded up E. coli cells upon periplasmic expression. A ΔBd0816 ΔBd3459 double mutant invaded prey more slowly than the wild type (with negligible prey cell rounding) and double invasions of single prey by more than one Bdellovibrio became more frequent. We solved the crystal structure of Bd3459 to 1.45 Å and this revealed predation-associated domain differences to conventional PBP4 housekeeping enzymes (loss of the regulatory domain III, alteration of domain II and a more exposed active site). The Bd3459 active site (and by similarity the Bd0816 active site) can thus accommodate and remodel the various bacterial PGs that Bdellovibrio may encounter across its diverse prey range, compared to the more closed active site that “regular” PBP4s have for self cell wall maintenance. Therefore, during evolution, Bdellovibrio peptidoglycan endopeptidases have adapted into secreted predation-specific proteins, preventing wasteful double invasion, and allowing activity upon the diverse prey peptidoglycan structures to sculpt the prey cell into a stable intracellular niche for replication.