Growth of the Stress-Bearing and Shape-Maintaining Murein Sacculus of Escherichia coli

To withstand the high intracellular pressure, the cell wall of most bacteria is stabilized by a unique cross-linked biopolymer called murein or peptidoglycan. It is made of glycan strands [poly-(GlcNAc-MurNAc)], which are linked by short peptides to form a covalently closed net. Completely surrounding the cell, the murein represents a kind of bacterial exoskeleton known as the murein sacculus. Not only does the sacculus endow bacteria with mechanical stability, but in addition it maintains the specific shape of the cell. Enlargement and division of the murein sacculus is a prerequisite for growth of the bacterium. Two groups of enzymes, hydrolases and synthases, have to cooperate to allow the insertion of new subunits into the murein net. The action of these enzymes must be well coordinated to guarantee growth of the stress-bearing sacculus without risking bacteriolysis. Protein-protein interaction studies suggest that this is accomplished by the formation of a multienzyme complex, a murein-synthesizing machinery combining murein hydrolases and synthases. Enlargement of both the multilayered murein of gram-positive and the thin, single-layered murein of gram-negative bacteria seems to follow an inside-to-outside growth strategy. New material is hooked in a relaxed state underneath the stress-bearing sacculus before it becomes inserted upon cleavage of covalent bonds in the layer(s) under tension. A model is presented that postulates that maintenance of bacterial shape is achieved by the enzyme complex copying the preexisting murein sacculus that plays the role of a template.     

The exocytoskeleton

The murein or peptidoglycan wall enclosing most bacteria is essential for the life style of most organisms in the Domain of Bacteria. Only in special situations does it not play a role in the bacterial growth cycle. When life first appeared on this planet the cellular osmotic pressure was probably low and a sacculus was probably not relevant, but became necessary as bacterial life evolved from the complex and sophisticated cell called the Last Universal Ancestor. The construction of the murein wall outside of the cytoplasmic membrane is complex and requires elaborate special biochemistry. Growth of the sacculus in some parts of the surface and not in others is important for bacteria cells and allows them to divide and grow without becoming larger and larger and for their being able to maintain a shape characteristic of individual species.     

Incorporation of diaminopimelic acid into the old poles of Escherichia coli

The surface stress theory of the ontogeny of the bacterial rod depends critically on whether the old poles continue to incorporate new material into the stress-bearing murein. If insertion of peptidoglycan continues, then seemingly the shape must become gradually rounder due to the surface stress resulting from the internal hydrostatic pressure. We have reanalysed our earlier experimental data by classifying grains with respect to distance from the nearest pole, and not from the cell centre as was done previously, and conclude that old poles do incorporate new diaminopimelic acid residues. This eliminates the model we have proposed for Gram-positive rods, which assumed diffuse growth on the cylindrical sides and that poles once formed would be rigid. The new results are consistent with another model (presented elsewhere) in which insertion of new murein occurs all over the surface, although not equally. This new model leads to elongation and division if the energetics of wall expansion is altered by the cell in a control region at a particular point of the cycle by the cell.     

Murein segregation in Escherichia coli.

Peptidoglycan (murein) segregation has been studied by means of a new labeling method. The method relies on the ability of Escherichia coli cells to incorporate D-Cys into macromolecular murein. The incorporation depends on a periplasmic amino acid exchange reaction. At low concentrations, D-Cys is innocuous to the cell. The distribution of modified murein in purified sacculi can be traced and visualized by immunodetection of the -SH groups by fluorescence and electron microscopy techniques. Analysis of murein segregation in wild-type and cell division mutant strains revealed that murein in polar caps is metabolically inert and is segregated in a conservative fashion. Elongation of the sacculus apparently occurs by diffuse insertion of precursors over the cylindrical part of the cell surface. At the initiation of cell division, there is a FtsZ-dependent localized activation of murein synthesis at the potential division sites. Penicillin-binding protein 3 and the products of the division genes ftsA and ftsQ are dispensable for the activation of division sites. As a consequence, under restrictive conditions ftsA,ftsI,or ftsQ mutants generate filamentous sacculi with rings of all-new murein at the positions where septa would otherwise develop.     

The analysis of cell division and cell wall synthesis genes reveals mutationally inactivated ftsQ and mraY in a protoplast-type L-form of Escherichia coli

Cell division and cell wall synthesis are tightly linked cellular processes for bacterial growth. A protoplast-type L-form Escherichia coli, strain LW1655F+, indicated that bacteria can divide without assembling a cell wall. However, the molecular basis of its phenotype remained unknown. To establish a first phenotype-genotype correlation, we analyzed its dcw locus, and other genes involved in division of E. coli. The analysis revealed defective ftsQ and mraY genes, truncated by a nonsense and a frame-shift mutation, respectively. Missense mutations were determined in the ftsA and ftsW products yielding amino-acid replacements at conserved positions. FtsQ and MraY, obviously nonfunctional in the L-form, are essential for cell division and cell wall synthesis, respectively, in all bacteria with a peptidoglycan-based cell wall. LW1655F+ is able to survive their loss-of-functions. This points to compensatory mechanisms for cell division in the absence of murein sacculus formation. Hence, this L-form represents an interesting model to investigate the plasticity of cell division in E. coli, and to demonstrate how concepts fundamental for bacterial life can be bypassed.     

Enzymology of elongation and constriction of the murein sacculus of Escherichia coli

Multiple deletions in murein hydrolases revealed that predominantly amidases are responsible for cleavage of the septum during cell division. Endopeptidases and lytic transglycosylases seem also be involved. In the absence of these enzymes E. coli grows normally but forms chains of adhering cells. Surprisingly, mutants lacking up to eight different murein hydrolases still grow with almost unaffected growth rate. Therefore it is speculated that general enlargement of the murein sacculus may differ from cell division by using transferases rather than the two sets of hydrolytic and synthetic enzymes as seems to be the case for the constriction process. A model is presented that describes growth of the murein of both Gram-positive and -negative bacteria by the activity of murein transferases. It is speculated that enzymes exist that catalyze a transpeptidation of the pre-existing murein onto murein precursors or nascent murein by using the chemical energy present in peptide cross-bridges. Such enzymes would at the same time cleave bonds in the murein net and insert new material into the growing sacculus.     

Cell shape determination in Escherichia coli

The rigid cell wall peptidoglycan (murein) is a single giant macromolecule whose shape determines the shape of the bacterial cell. Insight into morphogenetic mechanism(s) responsible for determining the shape of the murein sacculus itself has begun to emerge only in recent years. The discovery that MfreB and Mbl are cytoskeletal actin homologues that form helical structures extending from pole to pole in rod-shaped cells has opened an exciting new field of microbial cell biology. MreB (in Gram-negative rods) and Mbl (in Gram-positive species) are essential for murein synthesis along the lateral wall and hence, the rod shape of the cell. Known members of the morphogenetic system include MreB (or Mbl), MreC, MreD and PBP2, but Rod A and murein biosynthetic enzymes involved in peptidoglycan precursor synthesis and assembly are likely to be recruited to the same multimolecular apparatus. However, the actual role of MreB in assembly of the morphogenetic complex is still not clear and little is known about regulatory mechanisms controlling the switch from lateral murein elongation to septa1 murein synthesis at the time of cell division.     

Partition of Old Murein in Small Patches over the Entire Wall of E. coli Cells Forced to Grow as a Coccoid

With the development of a technique to visualize the ages of different portions of the sacculus, De Pedro et al. showed that the sacculus of Escherichia coli was tripartite: (i) the establish poles contained only old wall, (ii) the nascent poles (or septa) were composed entirely of new murein, and (iii) the elongating cylindrical wall was a mixture of patches of both old and new peptidoglycan. This short note presents a computer analysis of data files of work presented in the recent paper by De Pedro et al. of the growth pattern of the wall of E. coli forced to grow in a quite unusual morphology as large spheres in the presence of mecillinam. Compared with rod-shaped cells, only very small patches (spikes) of old wall were retained interspersed with new murein during the conversion to large spheroids. This subdivision appeared to be the case for both the previous wall of the poles, which are ordinarily retained intact, and the previous patches retained within the cylindrical wall. These very small patches after the conversion to spheroids were much smaller than the sidewall patches in rod-shaped cells reported previously. This implies that the mechanism that prevents the insertion of new wall into both the wall of the poles and the old wall patches of the sidewall in the presence of mecillinam is superseded by insertion throughout the old wall. The work in the De Pedro et al. paper from 2001 was done with cells of same strain as in the earlier papers with rod-shaped cells, so the results of computer analysis of the fluorescence micrographs can be critically compared.     

Murein (peptidoglycan) structure, architecture and biosynthesis in Escherichia coli

The periplasmic murein (peptidoglycan) sacculus is a giant macromolecule made of glycan strands cross-linked by short peptides completely surrounding the cytoplasmic membrane to protect the cell from lysis due to its internal osmotic pressure. More than 50 different muropeptides are released from the sacculus by treatment with a muramidase. Escherichia coli has six murein synthases which enlarge the sacculus by transglycosylation and transpeptidation of lipid II precursor. A set of twelve periplasmic murein hydrolases (autolysins) release murein fragments during cell growth and division. Recent data on the in vitro murein synthesis activities of the murein synthases and on the interactions between murein synthases, hydrolases and cell cycle related proteins are being summarized. There are different models for the architecture of murein and for the incorporation of new precursor into the sacculus. We present a model in which morphogenesis of the rod-shaped E. coli is driven by cytoskeleton elements competing for the control over the murein synthesis multi-enzyme complexes.     

Demonstration of molecular interactions between the murein polymerase PBP1B, the lytic transglycosylase MltA, and the scaffolding protein MipA of Escherichia coli

Enlargement of the stress-bearing murein sacculus of bacteria depends on the coordinated interaction of murein synthases and hydrolases. To understand the mechanism of interaction of these two classes of proteins affinity chromatography and surface plasmon resonance (SPR) studies were performed. The membrane-bound lytic transglycosylase MltA when covalently linked to CNBr-activated Sepharose specifically retained the penicillin-binding proteins (PBPs) 1B, 1C, 2, and 3 from a crude Triton X-100 membrane extract of Escherichia coli. In the presence of periplasmic proteins also PBP1A was specifically bound. At least five different non-PBPs showed specificity for MltA-Sepharose. The amino-terminal amino acid sequence of one of these proteins could be obtained, and the corresponding gene was mapped at 40 min on the E. coli genome. This MltA-interacting protein, named MipA, in addition binds to PBP1B, a bifunctional murein transglycosylase/transpeptidase. SPR studies with PBP1B immobilized to ampicillin-coated sensor chips showed an oligomerization of PBP1B that may indicate a dimerization. Simultaneous application of MipA and MltA onto a PBP1B sensor chip surface resulted in the formation of a trimeric complex. The dissociation constant was determined to be about 10(-6) M. The formation of a complex between a murein polymerase (PBP1B) and a murein hydrolase (MltA) in the presence of MipA represents a first step in a reconstitution of the hypothetical murein-synthesizing holoenzyme, postulated to be responsible for controlled growth of the stress-bearing sacculus of E. coli.     

Murein (peptidoglycan) structure, architecture and biosynthesis in Escherichia coli

The periplasmic murein (peptidoglycan) sacculus is a giant macromolecule made of glycan strands cross-linked by short peptides completely surrounding the cytoplasmic membrane to protect the cell from lysis due to its internal osmotic pressure. More than 50 different muropeptides are released from the sacculus by treatment with a muramidase. Escherichia coli has six murein synthases which enlarge the sacculus by transglycosylation and transpeptidation of lipid II precursor. A set of twelve periplasmic murein hydrolases (autolysins) release murein fragments during cell growth and division. Recent data on the in vitro murein synthesis activities of the murein synthases and on the interactions between murein synthases, hydrolases and cell cycle related proteins are being summarized. There are different models for the architecture of murein and for the incorporation of new precursor into the sacculus. We present a model in which morphogenesis of the rod-shaped E. coli is driven by cytoskeleton elements competing for the control over the murein synthesis multi-enzyme complexes.     

From growth to autolysis: the murein hydrolases inEscherichia coli

Murein hydrolases cleave bonds in the bacterial exoskeleton, the murein (peptidoglycan) sacculus, a covalently closed bag-shaped polymer made of glycan strands that are crosslinked by peptides. During growth and division of a bacterial cell, these enzymes are involved in the controlled metabolism of the murein sacculus. Murein hydrolases are believed to function as pacemaker enzymes for the enlargement of the murein sacculus since opening of bonds in the murein net is needed to allow the insertion of new subunits into the sacculus. Furthermore, they are responsible for splitting the septum during cell division. The murein turnover products that are released during growth are further degraded by these hydrolases to products that can be recycled by the biosynthetic enzymes. As potentially suicidal (autolytic) enzymes, murein hydrolases must be strictly controlled by the cell, Inhibition of murein synthesis, for example by penicillin, triggers an unbalanced action of murein hydrolases causing bacteriolysis. InEscherichia coli, 14 different murein hydrolases have so far been identified, includingN-acetylmuramyl-l-alanine amidases,dd-endopeptidases,dd-carboxypeptidases,ld-carboxypeptidases, andN-acetylglucosaminidases. In addition lysozyme-like enzymes, called “lytic transglycosylases,” produce (1→6)-anhydromuramic acid derivatives by an intramolecular transglycosylation reaction.     

The three-for-one model for Gram-negative wall growth: a problem and a possible solution

The murein wall in Gram-negative bacteria is so thin that the mechanism of growth is necessarily complicated. From analytical data of murein components, Höltje suggested a model for the growth mechanism that would lead to safe wall enlargement. The model depended on the formation of trimers of peptidoglycan disaccharides linked via their pentapeptides. In the `three-for-one' model three oligopeptidoglycan chains are linked to each other in the usual linkages between the carboxyl group of d-alanine residues and the ϵ-amino group of diaminopimelic acid residues; these are designated `tail-to-tail' linkages. This three-chained raft is then linked to the stress-bearing wall via the formation of trimers, defined as three peptide chains linked together by tail-to-tail linkages. Then by autolyzing the oldest bonds in each trimer, the old chain is excised and the raft becomes part of the stress-bearing wall and the wall is enlarged. There is a problem with the three-for-one model in that it demands a precise fitting of the prefabricated raft of three crosslinked chains to a stress-bearing chain in the wall fabric to allow the series of trimer linkages to form. Because the wall, when bearing stress, must be pulled into a `honeycomb' structure, the end-to-end distance would be shortened. The possibility is raised here that the glycan chains in the stress-bearing wall are stretched to a sufficient degree by the cell's turgor pressure to compensate for its zig-zag structure; this could allow the model to function. A calculation is presented that assumes that the area of the pores in the fabric, called tessera, is maximized by the cell's turgor pressure. In this case the glycan chain must stretch 10% (and the end-to-end distance of peptide strands stretch 28%) so that the end-to-end distance of a glycan chain in the stress-bearing wall and the unstretched nascent wall can be the same and permit indefinite stable growth.     

Morphogenesis of Escherichia coli.

Morphogenesis of the rod-shaped Escherichia coli is determined by controlled growth of an exoskeleton made of murein (peptidoglycan). Recent insights in the growth strategy of the stress-bearing murein sacculus has contributed to our understanding of how the required concerted action of murein polymerizing and hydrolyzing enzymes is achieved. The proteins involved are coordinated by the formation of multienzyme complexes. In this review, we summarize the recent results on murein structure and metabolism. On the basis of these findings, we present a model that explains maintenance of the specific rod shape of E. coli.     

Morphogenesis of Escherichia coli

Morphogenesis of the rod-shaped Escherichia coli is determined by controlled growth of an exoskeleton made of murein (peptidoglycan). Recent insights in the growth strategy of the stress-bearing murein sacculus has contributed to our understanding of how the required concerted action of murein polymerizing and hydrolyzing enzymes is achieved. The proteins involved are coordinated by the formation of multienzyme complexes. In this review, we summarize the recent results on murein structure and metabolism. On the basis of these findings, we present a model that explains maintenance of the specific rod shape of E. coli.     

Evidence for multisite growth of Escherichia coli murein involving concomitant endopeptidase and transpeptidase activities.

During diaminopimelic acid starvation of Escherichia coli W7, a large fraction of the preexisting murein cross-links are opened by murein endopeptidase and the resulting uncross-linked material is degraded. This is reflected morphologically in a general loss of rigidity of the murein sacculus long before lysis occurs. In growing cells, a dynamic situation is demonstrable. When cells whose murein sacculi are uniformly labeled with [14C]diaminopimelic acid were chased with unlabeled DAP, a significant, rapid shift of [14C]diaminopimelic acid from the donor to the acceptor half of dimers was observed. The shift can be explained by the presence of about 100 separate sites where new murein strands were being inserted between old radioactive strands of murein. Thus, the gradual loss of rigidity of the murein sacculus as endopeptidase continues to function during starvation of E. coli W7 suggests an even distribution of the active endopeptidases. This is consistent with the kinetic data which suggest that endopeptidase, along with murein synthetase and transpeptidase, acts at about 100 distinct sites to elongate the murein sacculus.     

Ultrastructure of the cell envelope and amino acid composition of the murein of Clostridium symbiosum

Abstract The cell envelope of the Gram-negative staining Clostridium symbiosum is 18 nm thick. It appears triple-layered and consists of an inner electrondense layer of about 5 nm, a lighter zone of 4 nm and an outer electron-dense layer of 9 nm. The inner layer corresponds to the murein sacculus, since the isolated peptidoglycan sacculi showed a thickness of 3–5 nm. Analysis showed that it belongs to the A₂pm-direct murein type. The outer layer could be removed by sodium dodecylsulfate. It contained mainly protein, small amounts of sugars and essentially no lipid, indicative of an S-layer rather than a typical Gram-negative type of outer membrane. Furthermore, l -alanine aminopeptidase activity characteristic of Gram-negative aerobic bacteria was absent in this organism and in other anaerobic Gram-negative bacteria tested. This demonstrates that such activity is an unreliable tool for the classification of anaerobic eubacteria. In spite of the thin murein layer, which is the likely reason for the Gram-negative reaction, the anaerobic growth, peritrichous flagellation and endospore formation indicate that this organism belongs to the genus Clostridium .     

Interaction between two murein (peptidoglycan) synthases, PBP3 and PBP1B, in Escherichia coli

The murein (peptidoglycan) sacculus is an essential polymer embedded in the bacterial envelope. The Escherichia coli class B penicillin-binding protein (PBP) 3 is a murein transpeptidase and essential for cell division. In an affinity chromatography experiment, the bifunctional transglycosylase-transpeptidase murein synthase PBP1B was retained by PBP3-sepharose when a membrane fraction of E. coli was applied. The direct protein-protein interaction between purified PBP3 and PBP1B was characterized in vitro by surface plasmon resonance. The interaction was confirmed in vivo employing two different methods: by a bacterial two-hybrid system, and by cross-linking/co-immunoprecipitation. In the bacterial two-hybrid system, a truncated PBP3 comprising the N-terminal 56 amino acids interacted with PBP1B. Both synthases could be cross-linked in vivo in wild-type cells and in cells lacking FtsW or FtsN. PBP1B localized diffusely and in foci at the septation site and also at the side wall. Statistical analysis of the immunofluorescence signals revealed that the localization of PBP1B at the septation site depended on the physical presence of PBP3, but not on the activity of PBP3. These studies have demonstrated, for the first time, a direct interaction between a class B PBP (PBP3) and a class A PBP (PBP1B) in vitro and in vivo, indicating that different murein synthases might act in concert to enlarge the murein sacculus during cell division.     

Constitutive septal murein synthesis in Escherichia coli with impaired activity of the morphogenetic proteins RodA and penicillin-binding protein 2.

The pattern of peptidoglycan (murein) segregation in cells of Escherichia coli with impaired activity of the morphogenetic proteins penicillin-binding protein 2 and RodA has been investigated by the D-cysteine-biotin immunolabeling technique (M. A. de Pedro, J. C. Quintela, J.-V. H?ltje, and H. Schwarz, J. Bacteriol. 179:2823-2834, 1997). Inactivation of these proteins either by amdinocillin treatment or by mutations in the corresponding genes, pbpA and rodA, respectively, leads to the generation of round, osmotically stable cells. In normal rod-shaped cells, new murein precursors are incorporated all over the lateral wall in a diffuse manner, being mixed up homogeneously with preexisting material, except during septation, when strictly localized murein synthesis occurs. In contrast, in rounded cells, incorporation of new precursors is apparently a zonal process, localized at positions at which division had previously taken place. Consequently, there is no mixing of new and old murein. Old murein is preserved for long periods of time in large, well-defined areas. We propose that the observed patterns are the result of a failure to switch off septal murein synthesis at the end of septation events. Furthermore, the segregation results confirm that round cells of rodA mutants do divide in alternate, perpendicular planes as previously proposed (K. J. Begg and W. D. Donachie, J. Bacteriol. 180:2564-2567, 1998).