Peptidoglycan turnover during growth of a Bacillus megaterium Dap- Lys- mutant.

The aim of this study was to ascertain whether or not the absence of cell wall growth zones, deduced from the analysis of autoradiographs of DL-[3H]mesodiaminopimelic acid pulse-labeled cells of a Dap- Lys- mutant of Bacillus megaterium, was due to a high peptidoglycan turnover. Turnover was determined in very precise experimental conditions because two kinds of turnover occurred: a low, acid-soluble turnover and a high, acid-insoluble one. The latter was detected during a chase in the culture medium when bacteria were centrifuged before treatment with trichloroacetic acid. Otherwise the acid-insoluble released material precipitated with the bacteria. In the electron microscope this material presented a globular structure and contained both peptidoglycan and teichoic acid. The acid-insoluble turnover was mainly produced by a lytic acitivity that was released into the culture medium. This thermolabile activity was not due to cell lysis. It was implicated in septum cleavage and in the detachment of wall fragments from the cell surface, but did not seem indispensable for cell elongation. The acid-soluble turnover was much weaker and seemed to be indispensable for cell elongation.     

Injury and recovery of Bacillus megaterium from mild chlorhexidine treatment

Treatment of Bacillus megaterium cell suspensions with 12 /μmol/1 chlorhexidine diacetate for 5 min led to an approximate 50%, reduction in viability when plated onto tryptone soya agar (TSA). Fifty percent of the surviving fraction were unable to form colonies on TSA containing 5.5% w/v KCI. Such loss of KCl tolerance is indicative of membrane damage, and was recovered within 30 min of incubation in tryptone soya broth (TSB). Multiplication of the damaged organisms did not recommence in this medium until after 60 min. Inclusion of inhibitors of respiration, and of protein, RNA and DNA synthesis in the TSB recovery medium did not significantly affect either the rate or extent of the recovery of KCl tolerance by damaged organisms.     

Nucleoid partitioning in Escherichia coli during steady-state growth and upon recovery from chloramphenicol treatment

To distinguish between a gradual or an abrupt movement of the Escherichia coli nucleoid during partitioning we determined the distances between nucleoid borders and cell poles. Measurements were performed on fixed but hydrated cells and on living cells growing in steady state. The distance between nucleoid outer border and cell pole remained constant in cells with either one or two nucleoids. Thus the nucleoid outer borders moved gradually during the partition process. To study partitioning during recovery from protein-synthesis inhibition cells were treated with chloramphenicol. After growth resumption, cells and nucleoids first elongated before partitioning occurred. Again, no indication of a rapid displacement of the nucleoid to one-quarter and three-quarter positions in the cell was observed.     

Peptidoglycan transformations during Bacillus subtilis sporulation

While vegetative Bacillus subtilis cells and mature spores are both surrounded by a thick layer of peptidoglycan (PG, a polymer of glycan strands cross‐linked by peptide bridges), it has remained unclear whether PG surrounds prespores during engulfment. To clarify this issue, we generated a slender ΔponA mutant that enabled high‐resolution electron cryotomographic imaging. Three‐dimensional reconstructions of whole cells in near‐native states revealed a thin PG‐like layer extending from the lateral cell wall around the prespore throughout engulfment. Cryotomography of purified sacculi and fluorescent labelling of PG in live cells confirmed that PG surrounds the prespore. The presence of PG throughout engulfment suggests new roles for PG in sporulation, including a new model for how PG synthesis might drive engulfment, and obviates the need to synthesize a PG layer de novo during cortex formation. In addition, it reveals that B. subtilis can synthesize thin, Gram‐negative‐like PG layers as well as its thick, archetypal Gram‐positive cell wall. The continuous transformations from thick to thin and back to thick during sporulation suggest that both forms of PG have the same basic architecture (circumferential). Endopeptidase activity may be the main switch that governs whether a thin or a thick PG layer is assembled.     

Expression of a Bacillus megaterium sporulation-specific gene during sporulation of Bacillus subtilis

The gene for the Bacillus megaterium spore C protein, a sporulation-specific gene, has been transferred into Bacillus subtilis. The B. megaterium gene was expressed little, if at all, during log-phase and early-stationary-phase growth, but was expressed during sporulation with the same kinetics as and at a level similar to that of the analogous B. subtilis genes. This finding is most consistent with the regulation of this class of genes by a mechanism of positive control.     

Relationships between intracellular proteolytic activity and protein turnover in Bacillus megaterium.

When incubated in a sporulation medium, the sporogenous strains of Bacillus megaterium degrade proteins at a rate of 4-10% X h-1. The maximal rate of protein turnover is reached after 3-4 hrs at the time of development of forespores and then decreases again. The rate of protein turnover in the asporogenous strain decreases steadily under similar conditions from 3-8% X h-1 at the beginning of incubation to 1% X h-1 after 5-6 hrs in the sporulation medium. The rate of degradation of proteins in vitro in protoplast lysates is similar or higher than the rate of protein turnover. The exocellular, as well as periplasmic proteolytic activity, is suppressed by amino acids more severely than the activity in protoplasts. Mutants devoid of the exocellular proteolytic enzyme contain also less proteolytic activity in the periplasm than in the protoplasts, in contrast to the wild strain. However, their rate of protein turnover, as well as the degradation of abnormal proteins is similar to that in the wild strain. This supports a view that the proteolytic system in protoplasts is involved in intracellular protein catabolism. The periplasmic enzyme can be considered as a kind of the exocellular proteinase.     

Peptidoglycan hydrolase LytF plays a role in cell separation with CwlF during vegetative growth of Bacillus subtilis.

Peptidoglycan hydrolase, LytF (CwlE), was determined to be identical to YhdD (deduced cell wall binding protein) by zymography after insertional inactivation of the yhdD gene. YhdD exhibits high sequence similarity with CwlF (PapQ, LytE) and p60 of Listeria monocytogenes. The N-terminal region of YhdD has a signal sequence followed by five tandem repeated regions containing polyserine residues. The C-terminal region corresponds to the catalytic domain, because a truncated protein without the N-terminal region retained cell wall hydrolase activity. The histidine-tagged LytF protein produced in Escherichia coli cells hydrolyzed the linkage of D-gamma-glutamyl-meso-diaminopimelic acid in murein peptides, indicating that it is a D,L-endopeptidase. Northern hybridization and primer extension analyses indicated that the lytF gene was transcribed by EsigmaD RNA polymerase. Disruption of lytF led to slightly filamentous cells, and a lytF cwlF double mutant exhibited extraordinary microfiber formation, which is similar to the cell morphology of the cwlF sigD mutant.