Localized perforation of the cell wall by a major autolysin: atl gene products and the onset of penicillin-induced lysis of Staphylococcus aureus.

We investigated the cell surface localization of the atl gene products of Staphylococcus aureus exposed to a lytic concentration (4 MIC) of penicillin G (PCG) by means of immunoelectron microscopy using anti-62-kDa N-acetylmuramyl-L-alanine amidase or anti-51-kDa endo-beta-N-acetylglucosaminidase immunoglobulin G. Protein A-gold conjugates reacting with antigen-antibody complex localized at sites of defects of the cell wall at the nascent cross wall. Anti-62-kDa N-acetylmuramyl-L-alanine amidase or anti-51-kDa endo-beta-N-acetylglucosaminidase immunoglobulin G inhibited the decreased turbidity caused by PCG-induced lysis and the formation of defects in the wall. The autolysis-defective mutant, S. aureus RUSAL2 (atl::Tn551), exposed to 4 MIC of PCG resisted autolysis and formation of the wall defect. These results suggest that activation or deregulation of the atl gene products at localized sites where formation of new cross wall was disturbed by PCG causes small defects in the cell wall in situ, eventually leading to general autolysis.     

Identification of endo-beta-N-acetylglucosaminidase and N-acetylmuramyl-L-alanine amidase as cluster-dispersing enzymes in Staphylococcus aureus.

Two proteins which are capable of dispersing cell clusters of Staphylococcus aureus have been purified from a S. aureus FDA209P culture supernatant. Both of them were found to have bacteriolytic activity. From the elution profile of column chromatography and Western blot (immunoblot) analysis, one of them was identified as a 51-kDa endo-beta-N-acetylglucosaminidase (GL). The other was a 62-kDa protein on the basis of sodium dodecyl sulfate gel electrophoresis. Analysis of the peptidoglycan fragments following treatment with the 62-kDa protein indicated that this protein is an N-acetylmuramyl-L-alanine amidase (AM). In vitro studies of cluster dispersion activities using S. aureus mutant strains Lyt66 or S. aureus Wood46 grown as clusters demonstrated that these two enzymes act synergistically to disperse clusters into single cells. Antiserum against the 51-kDa GL cross-reacted with the 62-kDa AM, and S. aureus FDA209P grown in the presence of anti-51-kDa-GL immunoglobulin G induced giant clusters. Clusters induced by anti-51-kDa GL and by Cibacron blue F3G-A were dispersed by coincubation with the 51-kDa GL and the 62-kDa AM. Western blot analysis demonstrated that the 51-kDa GL and the 62-kDa AM were missing in culture supernatants of S. aureus Lyt66, Wood46, and RUSAL2 (Tn551 autolysin-defective mutant), which grow in clusters. These results strongly suggest that the 51-kDa GL and 62-kDa AM are involved in cell separation of daughter cells after cell division.     

Molecular characterization of an atl null mutant of Staphylococcus aureus

atl is a gene encoding a bifunctional peptidoglycan hydrolase of Staphylococcus aureus. The gene product of atl is a 138 kDa protein that has an amidase domain and a glucosaminidase domain, and undergoes processing to generate two major peptidoglycan hydrolases, a 51 kDa glucosaminidase and a 62 kDa amidase in culture supernatant. An atl null mutant was isolated by allelic replacement and characterized. The mutant grew in clusters and sedimented when grown in broth culture. Analysis of peptidoglycan prepared from the wild type and the mutant revealed that there were no differences in muropeptide composition or in glycan chain length distribution. On the other hand, the atl mutation resulted in pleiotropic effects on cell surface nature. The mutant cells showed complete inhibition of metabolic turnover of cell wall peptidoglycan and revealed a rough outer cell wall surface. The mutation also decreased the amount of protein non-covalently bound to the cell surface and altered the protein profile, but did not affect proteins covalently associated with the cell wall. Lysis of growing cells treated with otherwise lytic concentration of penicillin G was completely inhibited in the mutant, but that of non-growing cells was not affected by the mutation. The atl mutation did not significantly affect the ability of S. aureus to provoke an acute infection when inoculated intraperitoneally in a mouse sepsis model. These results further support the supposition that atl gene products are involved in cell separation, cell wall turnover and penicillin-induced lysis of the cells.     

Identification and molecular characterization of an N-acetylmuramyl-L-alanine amidase Sle1 involved in cell separation of Staphylococcus aureus

We purified a peptidoglycan hydrolase involved in cell separation from a Staphylococcus aureus atl null mutant and identified its gene. Characterization of the gene product shows a 32 kDa N-acetylmuramyl-L-alanine amidase that we designated Sle1. Analysis of peptidoglycan digests showed Sle1 preferentially cleaved N-acetylmuramyl-L-Ala bonds in dimeric cross-bridges that interlink the two murein strands in the peptidoglycan. An insertion mutation of sle1 impaired cell separation and induced S. aureus to form clusters suggesting Sle1 is involved in cell separation of S. aureus. The Sle1 mutant revealed a significant decrease in pathogenesis using an acute infection mouse model. Atl is the major autolysin of S. aureus, which has been implicated in cell separation of S. aureus. Generation of an atl/sle1 double mutant revealed that the mutant cell separation was heavily impaired suggesting that S. aureus uses two peptidoglycan hydrolases, Atl and Sle1, for cell separation. Unlike Atl, Sle1 is not directly involved in autolysis of S. aureus.     

Subcellular Localization of the Major Autolysin,ATL and Its Processed Proteins in Staphylococcus aureus

The Staphylococcus aureus autolysin gene, atl, encodes a unique 138-kDa protein (ATL) with amidase and glucosaminidase domains. ATL has been suggested to undergo proteolytic processing to generate two extracellular peptidoglycan hydrolases, 51-kDa endo-β-N-acetylglucosaminidase (51-kDa GL) and 62-kDa N-acetylmuramyl-L-alanine amidase (62-kDa AM). To investigate cell-associated bacteriolytic enzymes for atl gene products, proteins were extracted from the cells as follows. The cells were exposed to 3 M LiCl followed by 4% SDS. Thereafter, the cells were disrupted and again extracted with 4% SDS. Whole SDS-stable cell-associated bacteriolytic proteins were extracted without disrupting the cells. Exposure to 3 M LiCl released major 138-, 115-, 85-, 62- and 51-kDa bacteriolytic proteins, and subsequent 4% SDS extraction released major 138- and 115-kDa bacteriolytic proteins. These bacteriolytic proteins were missing in extracts of atl mutant RUSAL2 (S. aureus RN450 atl:: Tn551). Immunoblotting studies suggest that these are all atl gene products: the 138-kDa protein is an ATL with a cleaved signal sequence; the 115-and 85-kDa proteins are intermediates; and the 51- and 62-kDa proteins are cell-associated 51-kDa GL and 62-kDa AM, respectively. The trypsin susceptibility of these proteins suggests that they are located outside the cell membrane. Differences in extractability and immunoelectron microscopic studies suggest that atl gene products are associated with cells in two different ways, LiCl extractable and non extractable. We suggest that the 138-kDa ATL undergoes processing through intermediate proteins (115- and 85-kDa proteins) to mature as the active cell cluster-dispersing enzymes 51-kDa GL and 62-kDa AM on the cell surface.     

Characterization and functional analysis of atl, a novel gene encoding autolysin in Streptococcus suis

Streptococcus suis serotype 2 (S. suis 2) is an important swine and human pathogen responsible for septicemia and meningitis. A novel gene, designated atl and encoding a major autolysin of S. suis 2 virulent strain HA9801, was identified and characterized in this study. The Atl protein contains 1,025 amino acids with a predicted molecular mass of 113 kDa and has a conserved N-acetylmuramoyl-l-alanine amidase domain. Recombinant Atl was expressed in Escherichia coli, and its bacteriolytic and fibronectin-binding activities were confirmed by zymography and Western affinity blotting. Two bacteriolytic bands were shown in the sodium dodecyl sulfate extracts of HA9801, while both were absent from the atl inactivated mutant. Cell chains of the mutant strain became longer than that of the parental strain. In the autolysis assay, HA9801 decreased to 20% of the initial optical density (OD) value, while the mutant strain had almost no autolytic activity. The biofilm capacity of the atl mutant was reduced ～30% compared to the parental strain. In the zebrafish infection model, the 50% lethal dose of the mutant strain was increased up to 5-fold. Furthermore, the adherence to HEp-2 cells of the atl mutant was 50% less than that of the parental strain. Based on the functional analysis of the recombinant Atl and observed effects of atl inactivation on HA9801, we conclude that Atl is a major autolysin of HA9801. It takes part in cell autolysis, separation of daughter cells, biofilm formation, fibronectin-binding activity, cell adhesion, and pathogenesis of HA9801.     

Characterization of Staphylococcus aureus cell wall glycan strands, evidence for a new beta-N-acetylglucosaminidase activity

Using sequential digestion with the glycyl-glycine endopeptidase lysostaphin followed by the pneumococcal N-acetylmuramyl-L-alanine amidase (amidase), the glycan strands of the peptidoglycan of Staphylococcus aureus were purified and analyzed by a combination of reverse-phase-high pressure liquid chromatography (HPLC) and mass spectrometry. Reverse-phase-HPLC resolved the glycan strands to a family of major peaks, which represented oligosaccharides composed of repeating disaccharide units (N-acetylglucosamine-[beta-1, 4]-N-acetylmuramic acid) with different degrees of polymerization and terminating with N-acetylmuramic acid residues at the reducing ends. The method allowed separation of strands up to 23-26 disaccharide units with a predominant length between 3 and 10 and an average degree of polymerization of approximately 6. Glycan strands with a higher degree of polymerization (>26 disaccharide units) represented 10-15% of the total UV absorbing glycan material. A unique feature of the staphylococcal glycan strands was the presence of minor satellite peaks that were present throughout the HPLC elution profile eluting either just prior or shortly after the major oligosaccharide peaks. A number of observations including mass spectrometric analysis suggest that the satellites are the products of an N-acetylglucosaminidase activity that differs from the atl gene product and that appears to be involved with modification of the glycan strand structure.     

Targeting of muralytic enzymes to the cell division site of Gram-positive bacteria: repeat domains direct autolysin to the equatorial surface ring of Staphylococcus aureus.

Staphylococcus aureus secretes autolysin (Atl) to complete cell division by hydrolyzing its thick cell wall layer at a designated site, known as the equatorial surface ring. Secreted pro-Atl (1256 amino acids) is cleaved at residues 198 and 775 to generate a pro-peptide, amidase and glucosaminidase, respectively. Here we examined the mechanism that directs amidase and glucosaminidase to the cell division site on the staphylococcal surface. Targeting of pro-Atl to the cell surface occurred prior to its proteolytic processing. Three repeat domains (R1, R2 and R3) located at the center of pro-Atl are necessary and sufficient for the targeting of reporter proteins to the equatorial surface ring. Pro-Atl cleavage at residue 775 separates the polypeptide such that R1 and R2 are linked to the C-terminus of amidase, whereas R3 is located at the N-terminus of glucosaminidase. Thus, it appears that the repeat domains direct pro-Atl, amidase and glucosaminidase to a specific receptor at the equatorial surface ring of staphylococci, thereby allowing localized peptidoglycan hydrolysis and separation of the dividing cells.     

Involvement of N-acetylmuramyl-l-alanine amidases in cell separation and antibiotic-induced autolysis of Escherichia coli

N-acetylmuramyl-L-alanine amidases are widely distributed among bacteria. However, in Escherichia coli, only one periplasmic amidase has been described until now, which is suggested to play a role in murein recycling. Here, we report that three amidases, named AmiA, B and C, exist in E. coli and that they are involved in splitting of the murein septum during cell division. Moreover, the amidases were shown to act as powerful autolytic enzymes in the presence of antibiotics. Deletion mutants in amiA, B and C were growing in long chains of unseparated cells and displayed a tolerant response to the normally lytic combination of aztreonam and bulgecin. Isolated murein sacculi of these chain-forming mutants showed rings of thickened murein at the site of blocked septation. In vitro, these murein ring structures were digested more slowly by muramidases than the surrounding murein. In contrast, when treated with the amidase AmiC or the endopeptidase MepA, the rings disappeared, and gaps developed at these sites in the murein sacculi. These results are taken as evidence that highly stressed murein cross-bridges are concentrated at the site of blocked cell division, which, when cleaved, result in cracking of the sacculus at this site. As amidase deletion mutants accumulate trimeric and tetrameric cross-links in their murein, it is suggested that these structures mark the division site before cleavage of the septum.     

Purification and characterization of a cell wall hydrolase encoded by the cw1A gene of Bacillus subtilis

A cell wall hydrolase of Bacillus subtilis was prepared from Escherichia coli cells harboring a plasmid containing the B. subtilis cwlA gene and purified by hydroxyapatite column chromatography and HPLC through TSK-gel G3000SWXL. In contrast to the molecular mass of 29,919 Da deduced from its nucleotide sequence, the purified CWLA is a 23 kDa protein. Characterization of the specific substrate bond cleaved by CWLA indicated the enzyme is an N-acetylmuramyl-L-alanine amidase. A 32-kDa precursor protein was detected on zymography of a crude cell homogenate. Some of the enzymatic properties of CWLA are also described.     

Intracellular location of the autolytic N-acetylmuramyl-L-alanine amidase in Bacillus subtilis 168 and in an autolysis-deficient mutant by immunoelectron microscopy.

Antisera against purified autolytic N-acetylmuramyl-L-alanine amidase from Bacillus subtilis 168 were prepared in rabbits. They neutralized the enzymatic action of the purified amidase acting on isolated sodium dodecyl sulfate (SDS)-treated walls from the same organism. They also inhibited the lysis of native walls, but only after the walls lysed partially. Amidase adsorbed to insoluble walls still combined with antibody. Antisera did not stop the lysis of whole cells. Lowicryl HM20 sections of both strain 168 and its autolytic mutant strain FJ6 were prepared by the progressive-lowering-of-temperature technique, immunolabeled with the antisera, and visualized with colloidal gold particles as markers. The highest concentration of gold particles seemed to be in the septa of dividing cells, followed by the side walls. There was some labeling of the cytoplasm. Adsorption of sera with SDS-treated walls reduced the overall labeling of sections considerably but did not alter the relative intracellular distribution of particles. The results for strains 168 and FJ6 were similar. Labeling of SDS-treated walls unexpectedly revealed the presence of a wall-bound amidase fraction.     

Lytic transglycosylases RlpA and MltC assist in Vibrio cholerae daughter cell separation

The cell wall is a crucial structural feature in the vast majority of bacteria and comprises a covalently closed network of peptidoglycan (PG) strands. While PG synthesis is important for survival under many conditions, the cell wall is also a dynamic structure, undergoing degradation and remodeling by ‘autolysins’, enzymes that break down PG. Cell division, for example, requires extensive PG remodeling, especially during separation of daughter cells, which depends heavily upon the activity of amidases. However, in Vibrio cholerae, we demonstrate that amidase activity alone is insufficient for daughter cell separation and that lytic transglycosylases RlpA and MltC both contribute to this process. MltC and RlpA both localize to the septum and are functionally redundant under normal laboratory conditions; however, only RlpA can support normal cell separation in low‐salt media. The division‐specific activity of lytic transglycosylases has implications for the local structure of septal PG, suggesting that there may be glycan bridges between daughter cells that cannot be resolved by amidases. We propose that lytic transglycosylases at the septum cleave PG strands that are crosslinked beyond the reach of the highly regulated activity of the amidase and clear PG debris that may block the completion of outer membrane invagination.     

Characterization of proteins belonging to the CHAP-related superfamily within the Firmicutes

Cell division is a dynamic process ending by separation of the daughter cells. This final step requires the cleavage of the murein septum synthetized during cell division. In Streptococcus thermophilus, cse plays an important role in cell separation. Cse protein contains, at its N-terminal end, a signal peptide and a putative LysM motif suggesting that it is secreted and able to bind to the cell wall. Furthermore, the C-terminus of Cse carries a putative cysteine, histidine-dependent amidohydrolases/peptidases (CHAP) domain conferring to the protein a potential catalytic activity. To gain insight into the role of Cse in the cell division process, in silico analysis of the Firmicutes proteins displaying CHAP-related domain was undertaken. This work allowed us to distinguish and characterize within the Firmicutes the 2 families of proteins (CHAP and NlpC/p60) belonging to the CHAP superfamily. These 2 families regroup mainly peptidoglycan hydrolases. Data from the literature indicate that NlpC/p60 and CHAP proteins cleave distinct peptidoglycan bonds. Among the enzymes characterized within the Firmicutes, NlpC/p60 proteins are gamma-D-glutamate-meso-diaminopimelate muropeptidase. Instead, CHAP enzymes involved in cell separation are N-acetylmuramoyl-L-alanine amidase and CHAP lysins have endopeptidase activity.     

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.     

Biological role of the pneumococcal amidase. Cloning of the lytA gene in Streptococcus pneumoniae

A pneumococcal recombinant plasmid, pRG2, containing the lytA gene that codes for the pneumococcal N-acetylmuramoyl-L-alanine amidase has been constructed using the pneumococcal plasmid pLS1 as a vector. pRG2 was introduced by genetic transformation into a mutant of Streptococcus pneumoniae (M31) that has a complete deletion of the lytA gene. The transformed strain (M51) grew at a normal growth rate as 'diplo' cells and underwent autolysis at the end of the exponential phase of growth, two properties that had been lost in the deleted mutant M31. M51 lysed very rapidly at the end of the exponential phase when the cells were grown in choline-containing medium probably because of the higher level of amidase activity present in this strain as compared to the lysis-prone strain M11. These findings show that the expression of the plasmid-linked gene was placed under the mechanism(s) of control of the cell during the exponential phase. Our results demonstrate that the physiological role of the pneumococcal amidase was to catalyze the separation of the daughter cells at the end of the cell division to produce diplo cells; in addition we have also confirmed the basic role of this autolysin in the bacteriolytic nature of beta-lactam antibiotics.     

The price of independence: cell separation in fission yeast

The ultimate goal of cell division is to give rise to two viable independent daughter cells. A tight spatial and temporal regulation between chromosome segregation and cytokinesis ensures the viability of the daughter cells. Schizosaccharomyces pombe, commonly known as fission yeast, has become a leading model organism for studying essential and conserved mechanisms of the eukaryotic cell division process. Like many other eukaryotic cells it divides by binary fission and the cleavage furrow undergoes ingression due to the contraction of an actomyosin ring. In contrast to mammalian cells, yeasts as cell-walled organisms, also need to form a division septum made of cell wall material to complete the process of cytokinesis. The division septum is deposited behind the constricting ring and it will constitute the new ends of the daughter cells. Cell separation also involves cell wall degradation and this process should be precisely regulated to avoid cell lysis. In this review, we will give a brief overview of the whole cytokinesis process in fission yeast, from the positioning and assembly of the contractile ring to the final step of cell separation, and the problems generated when these processes are not precise.     

Role of staphylococcal wall teichoic acid in targeting the major autolysin Atl

Staphylococcal cell separation depends largely on the bifunctional autolysin Atl that is processed to amidase‐R_1,2 and R₃‐glucosaminidase. These murein hydrolases are targeted via repeat domains (R) to the septal region of the cell surface, thereby allowing localized peptidoglycan hydrolysis and separation of the dividing cells. Here we show that targeting of the amidase repeats is based on an exclusion strategy mediated by wall teichoic acid (WTA). In Staphylococcus aureus wild‐type, externally applied repeats (R_1,2) or endogenously expressed amidase were localized exclusively at the cross‐wall region, while in ΔtagO mutant that lacks WTA binding was evenly distributed on the cell surface, which explains the increased fragility and autolysis susceptibility of the mutant. WTA prevented binding of Atl to the old cell wall but not to the cross‐wall region suggesting a lower WTA content. In binding studies with ConcanavalinA‐fluorescein (ConA‐FITC) conjugate that binds preferentially to teichoic acids, ConA‐FITC was bound throughout the cell surface with the exception of the cross wall. ConA binding suggest that either content or polymerization of WTA gradually increases with distance from the cross‐wall. By preventing binding of Atl, WTA directs Atl to the cross‐wall to perform the last step of cell division, namely separation of the daughter cells.     

Evidence for a role of N-acetylmuramyl-L-alanine amidase in septum separation in Escherichia coli.

Septum formation and septum separation have been studied in a chain-forming mutant of Escherichia coli K-12 bearing the envA mutation and its parental strain. In comparison to the wild type, the mutant showed a sixfold reduction in the specific activity of the enzyme, N-acetylmuramyl-L-alanine amidase (EC 3.5.1.28), part of which was associated to the outer membrane. Genetic as well as physiological suppression of chain formation resulted in an increase in amidase activity. The addition of N-acetylmuramyl-L-alanyl-D-glutamyl-meso-diaminopimelic acid to growing wild-type cells and to cells bearing the envA mutation caused an inhibition of cell separation and an increased frequency of visible septa. The kinetics of septum formation and separation was followed in chains by the use of ampicillin and nalidixic acid. The latter drug inhibited initiation of new septa but allowed preformed ones to go to cell separation at a rate corresponding to that of steady-state growing cells. Ampicillin treatment, on the other hand, resulted in a more rapid decrease in the frequency of septa. The disparate effects of ampicillin and nalidixic acid were not explained by a difference in amidase activity but could be due to an inhibitory effect of ampicillin on a septal peptidoglycan fusing activity.     

Cloning and expression of a Staphylococcus aureus gene encoding a peptidoglycan hydrolase activity.

A gene of Staphylococcus aureus PS47 encoding lytic activity was cloned and expressed in Escherichia coli. Deletion analysis of a recombinant plasmid carrying a 7.4-kilobase-pair fragment (kbp) of S. aureus DNA suggested that the gene was located within a 2.5-kbp EcoRI-XbaI fragment. Analysis of extracts of E. coli harboring recombinant plasmids on denaturing polyacrylamide gels containing purified cell walls of S. aureus showed a clearing zone by a polypeptide of apparent Mr 23,000. The release of dinitrophenylalanine but not reducing groups from purified cell walls by a cell extract of recombinant E. coli suggested that we had cloned an N-acetylmuramyl-L-alanine amidase.     

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.