Alterations in peptidoglycan chemical composition associated with rod-to-sphere transition in a conditional mutant of Klebsiella pneumoniae.

Klebsiella pneumoniae Mir M7 is a spontaneous parentless morphology mutant which grows as cocci at pH 7 and as rods at pH 5.8. This strain has been characterized as defective in lateral wall formation (at pH7). Data suggest that the cell wall is mainly made up of poles of the rods (G. Satta, R. Fontana, P. Canepari, and G. Botta, J. Bacteriol. 137:727--734, 1979). In this work the isolation and the biochemical properties of the peptidoglycan of both Mir M7 rods and cocci and a nonconditional rod-shaped Mir M7 revertant (strain Mir A12) are described. The peptidoglycan of Mir M7 (both rods and cocci) and Mir A12 strains carried covalently bound proteins which could be easily removed by pronase treatment in Mir M7 rods and Mir A12 cells, but not in Mir M7 round cells. However, when the sodium dodecyl sulfate-insoluble residues of Mir M7 cocci were pretreated with ethylenediaminetetraacetic acid (EDTA), pronase digestion removed the covalently bound proteins, and pure peptidoglycan was obtained. EDTA treatment of the rigid layer of Mir M7 cocci removed amounts of Mg2+ and Ca2+, which were 10- and 50-fold higher, respectively, than the amount liberated from the rigid layer of Mir M7 rods and Mir A12 cells. Amino acid composition was qualitatively similar in both strains, but Mir M7 cocci contained a higher amount of alanine and glucosamine. Mir M7 cocci contained approximately 50% less peptidoglycan than rods. Under electron microscopy, the rigid layer of the Mir M7 rods and Mir A12 cells appeared to be rod-shaped and their shape remained unchanged after EDTA and pronase treatment. On the contrary, the Mir M7 cocci rigid layer appeared to be round, and after EDTA treatment it collapsed and lost any definite morphology. In spite of these alterations, the peptidoglycan of Mir M7 cocci still appeared able to determine the shape of the cell and protect it from osmotic shock and mechanical damages. The accumluation of divalent cations appeared necessary for the peptidoglycan to acquire sufficient rigidity for shape determination and cell protection. We concluded that the coccal shape in Mir M7 cells is not due to loss of cell wall rigidity but is a consequence of the formation of a round peptidoglycan molecule. The possibility that the alterations found in the Mir M7 cocci rigid layer may reflect natural differences in the biochemical composition of the septa and lateral wall of normally shaped bacteria is discussed.     

Control of cell septation by lateral wall extension in a pH-conditional morphology mutant of Klebsiella pneumoniae.

The pH-conditional morphology mutant of Klebsiella pneumoniae strain MirM7 grows as cocci at pH 7 and as rods at pH 5.8. The mutant has a high-level mecillinam resistance (50% lethal dose greater than 200 micrograms/ml) in both forms. When broth cultures of the rod-shaped mutant were grown with 0.7 microgram of mecillinam per ml, cells assumed a round shape and continued to divided at a higher rate than the untreated control. A MirM7 rod-shaped revertant (MirA12), when treated with the same antibiotic concentration, changed to coccal shape and stopped dividing. The penicillin-binding proteins (PBPs) of strains MirA12 and MirM7 were analyzed. K. pneumoniae had six major PBPs quite similar to those of Escherichia coli. No differences were seen in the PBPs of MirM7 cocci and rods and MirA12 cells. In particular, PBP2 was found to be present and similar in MirM7 rods and cocci and MirA12 cells. We suggest that that in gram-negative rods, a control mechanism exists which prevents further septation in the absence of lateral cell wall elongation. The unique behavior of MirM7 is due to the fact that the control mechanism is not active in this strain. This model allows us to explain the preservation of shape in bacterial rods under various conditions of growth and the mechanism of bacterial killing by mecillinam.     

Bacterial cell shape regulation: testing of additional predictions unique to the two-competing-sites model for peptidoglycan assembly and isolation of conditional rod-shaped mutants from some wild-type cocci.

The two-competing-sites model for peptidoglycan assembly for bacterial cell shape regulation suggests that in rods, bacterial cell shape depends on the balance between two reactions (sites), one responsible for lateral wall elongation and the other responsible for septum formation. The two reactions compete with each other so that no lateral wall can be formed during septum formation and vice versa. When the site for lateral wall elongation overcomes that for septum formation, long rods or filaments are formed and cell division may be blocked. When the reaction leading to septum formation is hyperactive compared with the other, coccobacilli or cocci are formed. Other bacteria carry only one site for peptidoglycan assembly and can grow only as cocci. The two-competing-sites model predicts that two different types of cocci exist (among both morphology mutants and wild-type strains); one carries only the site for septum formation, whereas the other also carries the site for lateral wall elongation, the former site predominating over the latter. As a consequence of the inhibition (by antibiotics or by mutations) of septum formation in wild-type cocci of various species and in coccoid morphology mutants, some cocci are expected to undergo transition to rod shape and others are not. We have evaluated these predictions and show that they are in agreement. In fact, we found that among wild-type cocci belonging to 13 species, those of 6 species formed rods, whereas the remaining organisms maintained their coccal shape when septa were inhibited by antibiotics. Some coccoid morphology mutants of rod-shaped bacteria underwent coccus-to-rod transition after septum inhibition by antibiotics, whereas others maintained their coccal shape. When a mutation that causes septum inhibition was expressed in a morphology mutant of Klebsiella pneumoniae grown as a coccus, transition to rod shape was observed. A total of 914 mutants unable to form colonies at 42 degrees C were isolated from the coccoid species mentioned above. Between 75 and 95% of the mutants isolated from the species that formed rods when septum formation was inhibited by antibiotics but none of those isolated from the others underwent coccus-to-rod transition upon incubation at the nonpermissive temperature.     

Early Initiation of Deoxyribonucleic Acid Replication and Shortening of Generation Time Associated with Inhibition of Lateral Wall Formation by Mecillinam

The effects of mecillinam on the growth of rods of the pH-conditional morphology mutant MirM7 was studied. It has been found that mecillinam causes, coincident with transition to coccal shape, a balanced rise in the rate of viable count increase and the rate of macromolecular synthesis which lasts either until the cells enter a stationary growth phase or indefinitely, in the case of continuously diluted cultures. When the antibiotic is removed from cells which have already become coccoid, cells continue to grow at a faster rate until they resume the rod shape. No change in the per-cell rate of protein synthesis has been seen in untreated or mecillinam-treated cells before or after the change in growth rate. Studies with synchronously growing cells have shown that the antibiotic causes a shortening in the I period (initiation of deoxyribonucleic acid replication). Evaluation of the residual divisions in nalidixic acid-treated, exponential-phase cells has shown that mecillinam also shortens the D period (cell division). It is proposed that, in strain MirM7, inhibition of lateral wall elongation by the antibiotic allows the initiation of a new septum, though inhibition is still in progress. The initiation of a new septum is, in turn, responsible for both the early inibition of deoxyribonucleic acid replication and accelerated division. In the parental strain, MirA12, as well as in other sensitive gram-negative rods which divide, become cocci, and stop dividing after addition of the antibiotic, inhibition of lateral wall formation activates a feedback mechanism which prevents insertion of new septa (Satta et al., J. Bacteriol. 142:43-51, 1980). Consequently, no early initiation of deoxyribonucleic acid replication is observed, and the last division allowed by the antibiotic occurs in due time. This negative control is missing in MirM7.     

The rate and topography of cell wall synthesis during the division cycle of Escherichia coli using N-acetylglucosamine as a peptidoglycan label

The rates of synthesis of peptidoglycan and protein during the division cycle of Escherichia coli were measured by the membrane elution technique using cells differentially labelled with N-acetylglucosamine and leucine. During the first part of the division cycle the ratio of the rates of protein and peptidoglycan synthesis was constant. The rate of peptidoglycan synthesis, relative to the rate of protein synthesis, increased during the latter part of the division cycle. These results support a simple, bipartite model of cell surface increase in rod-shaped cells. Prior to the start of constriction the cell surface increases only by lateral wall extension. After cell constriction starts, the cell surface increases by both lateral wall and pole growth. The increase in surface area is partitioned between the lateral wall and the pole so that the volume of the cell increases exponentially. No variation in cell density occurs, because the increase in surface allows a continuous exponential increase in cell volume that accommodates the exponential increase in cell mass. The results are consistent with the constant density of the growing cell and the surface stress model for the regulation of cell surface synthesis. In addition, the elution pattern suggests that the membrane elution method does work by having the cells effectively bound to the membrane by their poles.     

Bacterial morphogenesis: learning how cells make cells

Bacteria furnish tractable models for complex biological processes, and morphogenesis is now taking its turn. We can already explain in general terms how such elementary forms as rods and cocci are produced, and the shapes of several individual organisms are coming into focus. In most bacteria shape is maintained by the cell wall, specifically the peptidoglycan layer, which has the attributes of a strong stiff fabric. Compliance of that fabric with turgor pressure is an important aspect of morphogenesis. The shape of the wall sacculus is determined by the way it is deposited, which is controlled by a cytoskeleton made up of two molecular families. One, related to the eukaryotic tubulins, is responsible for the construction of the septum and the poles. The other, related to eukaryotic actins, localizes peptidoglycan synthesis in the lateral walls of rod-shaped cells. Just how the cytoskeleton itself is organized remains to be discovered, but it seems likely that, as in eukaryotes, the cytoskeleton is produced by self-organized assembly, guided by the fabric of the cell.     

<Emphasis Type="Italic">Escherichia coli</Emphasis> cold shock protein CsdA effects an increase in septation and the resultant formation of coccobacilli at low temperature

Bacterial shape is controlled by peptidoglycan assembly along the lateral wall and at the septum site. In contrast to rods at 37°C, the wild-type strain formed coccobacilli at 12°C, indicating a prevailing shift toward septal peptidoglycan synthesis at low temperature. Escherichia coli cold shock protein CsdA is a DEAD-box RNA helicase with an extended variable region at the carboxyl terminus. The csdA null mutant formed elongated cells indicating that CsdA, directly or indirectly, effects an increase in septation and the resultant coccobacillus morphology. Lipoprotein NlpI is suggested for a role in cell division. The presence of a plasmid encoding CsdA or NlpI increased septation and coccobacillus morphology of the csdA null mutant cells. Plasmid-encoded CsdAΔ445 (lacking the C-terminal extension) in the mutant complemented the growth and resulted in the appearance of coccobacillus- and rod-shaped cells. In contrast, a plasmid encoding both NlpI and CsdAΔ445 in the wild-type or mutant resulted in inhibition of growth accompanied with the formation of elongated and misshapen cells. However, a plasmid encoding both NlpI and CsdA resulted in normal growth and coccobacilli. The data indicate that the addition of the C-terminal extension yields an increase in septation and the resultant increased formation of coccobacilli.     

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.     

The bactericidal action of beta-lactam antibiotics on an autolysin-deficient strain of Bacillus subtilis

An autolysin-deficient mutant of Bacillus subtilis was completely tolerant to 5 h incubation with 50-100 micrograms cycloserine ml-1 whereas the wild-type was rapidly lysed and killed by 12 micrograms ml-1. Lysis also did not occur when low concentrations of beta-lactams were added to exponentially growing cultures of the mutant, but over 90% of the bacteria were killed within 90-120 min. Protein, lipid and peptidoglycan synthesis as well as growth were inhibited after about 60 min. At this time, but not earlier, small amounts of these three cell components appeared in culture supernatants. Earlier, at about 20-30 min, the intracellular pools of amino acids started to decline rapidly and there was a temporary apparent increase in the rate of lipid synthesis. Neither of the latter phenomena occurred with cycloserine, with which protein and lipid synthesis declined only slowly and the rate of peptidoglycan synthesis was 80% inhibited within 30 min. Only occasional cells with damaged walls were seen 30-90 min after addition of either beta-lactams or cycloserine to the cultures. It thus seems unlikely that wall hydrolysis or penetration by residual autolysins in the mutant are responsible for mass cell death caused by the beta-lactams.     

Temperature-sensitive nature of the rodB maturation in Bacillus subtilis.

The Mg2+ requirement of a morphological mutant of Bacillus subtlis, rodB strain 104 was highly temperature sensitive in the presence of halide or nitrate anions. Likewise the morphological change from rod shapes to spheres was dependent upon temperature, the same anions, and the Mg2+ concentration. The three factors interacted. Other rodB mutants behaved similarly. If the rodB strain 104 in its rod form was treated at high temperatures in the absence of either protein or peptidoglycan synthesis and restored to lower temperatures with the syntheses restarted, a partial temporary change toward cocci occurred. In the absence of halides or in the presence of Cl- but not Br-, the cells increased in volume when they changed from rods to cocci.     

Taking shape: control of bacterial cell wall biosynthesis

The characteristic shape of a bacterial cell is a function of the three dimensional architectures of the cell envelope and is determined by the balance between lateral wall extension and synthesis of peptidoglycan at the division septum. The three dimensional patterns of cell wall synthesis in the bacterium Bacillus subtilis is influenced by actin-like proteins that form helical coils in the cell and by the MreCD membrane proteins that link the cytoskeletal elements with the penicillin-binding proteins that carry out peptidoglycan synthesis. Recent genetic studies have provided important clues as to how these proteins are arranged in the cell and how they function to regulate cell shape.     

Differential methicillin susceptibilities of peptidoglycan syntheses in methicillin-resistant Staphylococcus aureus.

The mechanism of staphylococcal resistance to methicillin is unknown. Peptidoglycan synthesis was studied in a methicillin-resistant and a derived methicillin-sensitive Staphylococcus aureus strain. Although the methicillin minimum inhibitory concentration for growth of the methicillin-resistant strain was 1,600 micrograms/ml, peptidoglycan synthesis by the organism incubated in a wall synthesis solution was inhibited about 90% by 5 micrograms of methicillin per ml. In contrast, high concentrations of methicillin added to actively growing cultures of the methicillin-resistant strain had little effect on growth or peptidoglycan synthesis. Peptidoglycan synthesis in chloramphenicol-treated cultures was more susceptible to methicillin than it was in actively growing cultures of the methicillin-resistant strain. It is proposed that in this strain cell wall thickening peptidoglycan synthesis which predominates in cell wall synthesis solution and chloramphenicol-treated cultures is methicillin sensitive, whereas peptidoglycan synthesis involved in cell division, primarily in the region of the septum, which predominates in actively growing cultures is methicillin resistant. Both cell wall thickening and septal peptidoglycan syntheses are methicillin sensitive in the methicillin-sensitive strain.     

Unidirectional Growth and Branch Formation of a Morphological Mutant, Agrobacterium tumefaciens

Morphological characteristics of thermoconditional mutant Agrobacterium tumefaciens F-502 were investigated in relation to growth, division, and synthesis of cellular components. As a result of a shift from 27 to 37 C, mutant cells altered their morphology from short rods to elongated and branched forms; in addition, division and deoxyribonucleic acid synthesis were inhibited at 37 C. At 37 C unidirectional cell growth and branch formation occurred at one end of a cell, and the elongation rate of a cell was proportional to cell length. A hypothetical model for branch formation is presented in which the maximal elongation rate, 1.8 mum/h, at one end of a cell is an essential factor for initiation of branch formation.     

Synthesis of peptidoglycan and membrane during the division cycle of rod-shaped, gram-negative bacteria.

A modified procedure for determining the pattern of peptidoglycan synthesis during the division cycle has allowed the measurement of the rate of side wall synthesis during the division cycle without the contribution due to pole formation. As predicted by a model proposing that the surface growth of the cell is regulated by mass increase, we find a decrease in side wall synthesis in the latter half of the division cycle. This supports the proposal that, upon invagination, pole growth accommodates a significant proportion of the increasing cell mass and that residual side wall growth occurs in response to the residual mass increase not accommodated by pole volume. The observed side wall synthesis patterns support the proposal that mass increase is a major, and possibly sole, regulator of bacterial surface increase. Membrane synthesis during the division cycle of the gram-negative, rod-shaped bacteria Escherichia coli and Salmonella typhimurium has also been measured with similar methods. The rate of membrane synthesis--measured by incorporation of radioactive glycerol or palmitate relative to simultaneous labeling with radioactive leucine--exhibits the same pattern as peptidoglycan synthesis. The results are compatible with a model of cell surface growth containing the following elements. (i) During the period of the division cycle prior to invagination, growth of the cell occurs predominantly in the side wall and the cell grows only in length. (ii) When invagination begins, pole growth accommodates some cytoplasmic increase, leading to a concomitant decrease in side wall synthesis. (iii) Surface synthesis increases relative to mass synthesis during the last part of the division cycle because of pole formation. It is proposed here that membrane synthesis passively follows the pattern of peptidoglycan synthesis during the division cycle.     

Unstable Escherichia coli L forms revisited: growth requires peptidoglycan synthesis

Growing bacterial L forms are reputed to lack peptidoglycan, although cell division is normally inseparable from septal peptidoglycan synthesis. To explore which cell division functions L forms use, we established a protocol for quantitatively converting a culture of a wild-type Escherichia coli K-12 strain overnight to a growing L-form-like state by use of the beta-lactam cefsulodin, a specific inhibitor of penicillin-binding proteins (PBPs) 1A and 1B. In rich hypertonic medium containing cefsulodin, all cells are spherical and osmosensitive, like classical L forms. Surprisingly, however, mutant studies showed that colony formation requires d-glutamate, diaminopimelate, and MurA activity, all of which are specific to peptidoglycan synthesis. High-performance liquid chromatography analysis confirmed that these L-form-like cells contain peptidoglycan, with 7% of the normal amount. Moreover, the beta-lactam piperacillin, a specific inhibitor of the cell division protein PBP 3, rapidly blocks the cell division of these L-form-like cells. Similarly, penicillin-induced L-form-like cells, which grow only within the agar layers of rich hypertonic plates, also require d-glutamate, diaminopimelate, and MurA activity. These results strongly suggest that cefsulodin- and penicillin-induced L-form-like cells of E. coli-and possibly all L forms-have residual peptidoglycan synthesis which is essential for their growth, probably being required for cell division.     

Genomic channeling in bacterial cell division

The bacterial dcw cluster is a group of genes involved in cell division and peptidoglycan synthesis. Comparison of the cluster across several bacterial genomes shows that its gene content and its gene order are conserved in distant bacterial lineages and, moreover, that, being most conserved in rod-shaped bacteria, the degree of conservation relates to bacterial morphology. We propose a model in which the selective pressure to maintain the cluster arises from the need to efficiently coordinate the processes of elongation and septation in rod-shaped bacteria. Gene order in the dcw cluster would be conserved as a result of mechanisms comprising: (i) a limited amount of peptidoglycan precursors required both for septation and elongation of the wall; (ii) co-translational assembly of the protein complexes involved in cell division and in the synthesis of the peptidoglycan precursors; and (iii) alternation in the cellular localization of the assembled complexes to participate either in the synthesis of the septal peptidoglycan and division, or in the synthesis of the lateral wall. The name genomic channeling is proposed for this model as it involves a genomic arrangement that could facilitate the assembly of specific protein complexes and their subsequent conveyance to specific locations in the crowded cytoplasm and the envelope.     

Effect of growth rate and cell shape on the peptidoglycan composition in Escherichia coli.

The muropeptide composition of peptidoglycan from Escherichia coli W7 cultivated at different growth rates in chemostat cultures was compared by using high-pressure liquid chromatography. At a low growth rate (D = 0.1 h-1), about 40% more covalently bound lipoprotein and at least twofold more diaminopimelyl-diaminopimelic acid cross-bridges were found than at a high growth rate (D = 0.8 h-1). The total degree of cross-linkage was only slightly increased, and the fraction of trimeric muropeptides and the average length of the glycan chains were not changed significantly. Analysis of the peptidoglycan from a morphological variant strain of W7 revealed that the altered peptidoglycan composition in slowly growing W7 cells was not correlated with the observation that these cells, due to their decreased cell length, were relatively enriched in polar material. In fact, our results suggested that peptidoglycan forming cell poles is chemically identical to that forming lateral wall.     

Peptidoglycan synthesis and turnover in cell division mutants of Agmenellum.

The synthesis and turnover of peptidoglycan in Agmenellum quadruplicatum was investigated using D-[U-14C]alanine followed by proteolytic digestion. The rate of turnover of alanine in the peptide portion of the peptidoglycan was measured in strain BG-1 and in two division mutants of this strain: one was blocked in cell separation; and the other was a low-temperature, conditional cell division mutant. The peptide portion of peptidoglycan turned over in all three strains tested, but no correlation was observed between septum formation or cell separation and the rate of turnover. Peptidoglycan synthesis was measured during induced division in snake forms of strain SN-29. A stimulation of peptidoglycan synthesis was observed during the period of cross-wall formation, even in the absence of new protein synthesis. Thus in A. quadruplicatum, cross-wall synthesis is accompanied by a stimulation of peptidoglycan synthesis.     

Properties of cell wall peptidoglycan synthesized by amino acid deprived re1A mutants of Escherichia coli

Cell wall peptidoglycan synthesis in Escherichia coli is under stringent control. During amino acid deprivation, peptidoglycan synthesis is inhibited in re1A+ bacteria but not in re1A mutants. The relaxed synthesis of peptidoglycan by amino acid deprived re1A bacteria was inhibited by several beta-lactam antibiotics at concentrations which inhibited cell elongation in growing cultures suggesting that the transpeptidase activity of penicillin-binding protein (PBP-1B) was involved in this process. Structural studies on the peptidoglycan also indicated the involvement of transpeptidation in relaxed peptidoglycan synthesis. The peptidoglycan synthesized during amino acid deprivation was cross-linked to the existing cell wall peptidoglycan, and the degree of cross-linkage was the same as that of peptidoglycan synthesized by growing control cells. The relaxed synthesis of peptidoglycan was also inhibited by moenomycin, an inhibitor of the in vitro transglycosylase activities of PBPs, but the interpretation of this result depends on whether the transglycosylases are the sole targets of moenomycin in vivo. Most of the peptidoglycan lipoprotein synthesized by histidine-deprived re1A+ bacteria was in the free form as previously reported, possibly because of the restriction in peptidoglycan synthesis. In support of this proposal, most of the lipoprotein synthesized during histidine deprivation of re1A mutants was found to be covalently linked to peptidoglycan. Nevertheless, the peptidoglycan synthesized by amino acid deprived re1A bacteria was apparently deficient in bound lipoprotein as compared with peptidoglycan synthesized by normal growing control bacteria suggesting that the rate of lipoprotein synthesis during amino acid deprivation may be limiting.     

Cell division and peptidoglycan assembly in Eschenchia coli

Research on bacterial cell division has recently gained renewed impetus because of new information about peptidoglycan assembly and about specific cell-division genes and their products. This paper concerns aspects of cell division that specifically concern the peptidoglycan. It is shown that upon division, peptidoglycan assembly switches from lateral wall location to the cell centre, that assembly takes place at the leading edge of the invaginating constriction, that the mode of glycan strand insertion changes from a single-stranded mode to a multi-stranded mode, and that the initiation of division (in contrast to its continuation) requires penicillin-insensitive peptidoglycan synthesis (PIPS). A membrane component X (possibly FtsQ) is proposed to coordinate PIPS with the cell division-initiating protein FtsZ. It is suggested that a largely proteinaceous macromolecular complex (divisome) at the leading edge of constriction encompasses three compartments (cytoplasm, membrane and periplasm). The composition of this complex is proposed to vary depending on whether division is being initiated or completed.