Patchiness of murein insertion into the sidewall of Escherichia coli (original) (raw)
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Journal of Bacteriology, 1982
Cells of Escherichia coli PA3092 were synchronized by centrifugal elutriation. The synchronously growing cells were double labeled with -3H or DL-[meso-2,6-14C]diaminopimelic acid (DAP) at different times. Cells incorporated [3H]DAP at a continuously increasing rate during their cycle, with a maximum occurring at about 30 min before division for trichloroacetic acid-precipitated cells (whole cells) and about 10 min before division for sodium dodecyl sulfate-treated cells (sacculi). This was in good agreement with the observed kinetics of volume growth under these conditions. Furazlocillin, which preferentially interacts with penicillin-binding protein 3, modified the pattern of incorporation of [3H]DAP. Electron microscopy indicated that furazlocillin did not inhibit the initiation of division but rather its completion. In addition, we measured the cross-linking of the murein inserted at different times during synchronous growth. The highest percentages were found to occur around di...
Journal of bacteriology, 1987
Resting cells of Escherichia coli are able to initiate growth and murein biosynthesis in the presence of beta-lactam antibiotics binding to penicillin-binding proteins (PBPs) 1a and 1b (E. J. de la Rosa, M. A. de Pedro, and D. Vázquez, Proc. Natl. Acad. Sci. USA 82:5632-5635, 1985). Under these conditions, cells elongate normally until they approach the first doubling in mass, the time at which cell lysis starts. Assuming that coupling between DNA replication and cell division both in cells starting growth and in growing cells is essentially similar, triggering of the lytic response in the beta-lactam-treated cells coincides with the termination of the first round of DNA replication. This coincidence suggests that both events are interrelated. We investigated this possibility by studying the initiation of growth in cultures of wild-type strains and in cell division mutants treated with beta-lactams inhibiting PBPs 1a and 1b and with the DNA replication inhibitor nalidixic acid. Addi...
Medical Microbiology and Immunology, 1999
The classical concept of the architecture of microbial murein assumes cross-linked glycan chains to be arranged in horizontal layers outside of the plasma membrane. It necessitates elaborate hypotheses to explain processes such as the biosynthesis, growth and division of the bacterial cell wall and provides no explanation for transenvelope macromolecular transport. Moreover, this model is difficult to reconcile with a number of basic chemical and electron microscopical data. According to a fundamentally distinct concept which is presented here, glycan strands in the microbial wall run perpendicular to the plasma membrane, each strand being cross-linked by peptide bridges with four other strands. This arrangement allows the formation of a structured matrix pierced with ordered ionophoric channels potentially harboring either lipoprotein or teichoic (lipoteichoic) acid molecules in Gram-negative and Gram-positive bacteria, respectively. New wall structures are synthesized in toto emerging from the cytoplasmic membrane as a condensed gel-like network below the old wall without being covalently attached to it, expanding due to inherent elasticity as the old wall is lyzed. This model reflects published genetic and biochemical data and offers a simple explanation for peptidoglycan biogenesis. As the biosynthesis is terminated by enzymic cleavage of all glycan strands, murein is irreversibly released from the membrane. The murein detachment prepares the membrane for de novo assembly of both the new wall synthesis machinery and the multicomponent factory for protein, DNA and phospholipid transfer. Being assembled in parallel, both new murein and the traffic complexes grow from the membrane together. This concept eliminates the necessity for the traffic complexes to penetrate intact murein. In the process of simultaneous assembly, the expanding murein functions as a lifting platform driven by the force of turgor pressure, transporting macromolecules through the perisplasmic space.
In Escherichia coli, the cytoplasmic proteins MreB and FtsZ play crucial roles in ensuring that new muropeptide subunits are inserted into the cell wall in a spatially correct way during elongation and division. In particular, to retain a constant diameter and overall shape, new material must be inserted into the wall uniformly around the cell's perimeter. Current thinking is that MreB accomplishes this feat through intermediary proteins that tether peptidoglycan synthases to the outer face of the inner membrane. We tested this idea in E. coli by using a DD-carboxypeptidase mutant that accumulates pentapeptides in its peptidoglycan, allowing us to visualize new muropeptide incorporation. Surprisingly, inhibiting MreB with the antibiotic A22 did not result in uneven insertion of new wall, although the cells bulged and lost their rod shapes. Instead, uneven (clustered) incorporation occurred only if MreB and FtsZ were inactivated simultaneously, providing the first evidence in E. coli that FtsZ can direct murein incorporation into the lateral cell wall independently of MreB. Inhibiting penicillin binding protein 2 (PBP 2) alone produced the same clustered phenotype, implying that MreB and FtsZ tether peptidoglycan synthases via a common mechanism that includes PBP 2. However, cell shape was determined only by the presence or absence of MreB and not by the even distribution of new wall material as directed by FtsZ.
Branching of Escherichia coli Cells Arises from Multiple Sites of Inert Peptidoglycan
Journal of Bacteriology, 2003
Some strains of Escherichia coli defective for dacA , the gene coding for penicillin-binding protein 5, exhibit a strong branching phenotype when cell division is blocked. Since such branch formation implies a differentiation of polar caps at ectopic locations in the cell envelope, we analyzed murein segregation and observed a strong correlation between areas of inert murein and these morphological anomalies. In particular, the tips of branches exhibited the same properties as those described for polar caps of wild-type cells, i.e., the synthesis and turnover of murein were inhibited. Also, the mobility of cell envelope proteins was apparently constrained in areas with morphological defects. Polar regions of branching cells and sacculi had aberrant morphologies with a very high frequency. Of special interest was that areas of inert murein at polar caps were often split by areas of active synthesis, a situation unlike that observed in wild-type cells. These observations suggest that ...
Physiological and geometrical conditions for cell division in Escherichia coli
Annales de l'Institut Pasteur. Microbiologie
During recovery of division in filaments of a temperature-sensitive DNA replication mutant, DNA-less cells were formed with a broad variation in cell lengths. It is argued that segregated nucleoids are necessary to indicate the site of division and that, in their absence, the cell has no additional mechanism to locate the division site. A second condition for division is based on geometrical arguments: the cell must be able to reestablish its original surface to volume ratio or its diameter, either of which may decrease during elongation. Electron microscopy and auto-radiography of radio-labelled sacculi prepared from E. coli MC4100 lysA, cultured in glucose minimal medium, showed that these cells elongate at a constant diameter and double their rate of surface synthesis during the constriction period.
Towards a comprehensive view of the bacterial cell wall
Trends in Microbiology, 2005
Direct in vivo visualization, in full atomic detail, of the microbial cell wall and its stress-bearing structural architecture remains one of the prime challenges in microbiology. In the meantime, molecular modeling can provide a framework for explaining and predicting mechanisms involved in morphogenesis, bacterial cell growth and cell division, during which the wall and its major structural component -murein -have to protect the cell from osmotic pressure and multiple tensile forces. Here, we illustrate why the scaffold concept of murein architecture provides a more comprehensive representation of bacterial cell wall physiology than previous models.
Morphological analysis of the division cycle of two Escherichia coli substrains during slow growth
Journal of Bacteriology
Morphological parameters of the cell division cycle have been examined in Escherichia coli B/r A and K. Whereas the shape factor (length of newborn cell/width) of the two strains was the same at rapid growth (doubling time, tau, less than 60 min), with decreasing growth rate the dimensions of the two strains did change so that B/r A cells became more rounded and B/r K cells became more elongated. The process of visible cell constriction (T period) lasted longer in B/r A than in B/r K during slow growth, reaching at tau = 200 min values of 40 and 17 min, respectively. The time between termination of chromosome replication and cell division (D period) was found to be longer in B/r A than in B/r K. As a result, in either strain completion of chromosome replication seemed always to occur before initiation of cell constriction. Nucleoplasmic separation did not coincide with termination as during rapid growth but occurred in both strains within the T period, about 10 min before cell divis...