Cyclic AMP and cell division in Escherichia coli.

We examined several aspects of cell division regulation in Escherichia coli which have been thought to be controlled by cyclic AMP (cAMP) and its receptor protein (CAP). Mutants lacking adenyl cyclase (cya) or CAP (crp) were rod shaped, not spherical, during exponential growth in LB broth or glucose-Casamino Acids medium, and lateral wall elongation was normal; in broth, stationary-phase cells became ovoid. Cell mass was smaller for the mutants than for the wild type, but it remained appropriate for their slower growth rate and thus probably does not reflect early (uncontrolled) septation. The slow growth did not seem to reflect a gross metabolic disorder, since the mutants gave a normal yield on limiting glucose; surprisingly, however, the cya mutant (unlike crp) was unable to grow anaerobically on glucose, suggesting a role for cAMP (but not for CAP) in the expression of some fermentation enzyme. Both cya and crp mutants are known to be resistant to mecillinam, an antibiotic which inhibits penicillin-binding protein 2 (involved in lateral wall elongation) and also affects septation. This resistance does not reflect a lack of PBP2. Furthermore, it was not simply the result of slow growth and small cell mass, since small wild-type cells growing in acetate remained sensitive. The cAMP-CAP complex may regulate the synthesis of some link between PBP2 and the septation apparatus. The ftsZ gene, coding for a cell division protein, was expressed at a higher level in the absence of cAMP, as measured with an ftsZ::lacZ fusion, but the amount of protein per cell, shown by others to be invariable over a 10-fold range of cell mass, was independent of cAMP, suggesting that ftsZ expression is not regulated by the cAMP-CAP complex.     

Iron limitation induces SpoT-dependent accumulation of ppGpp in Escherichia coli

In Escherichia coli the beta-lactam mecillinam specifically inhibits penicillin-binding protein 2 (PBP2), a peptidoglycan transpeptidase essential for maintaining rod shape. We have previously shown that PBP2 inactivation results in a cell division block and that an increased concentration of the nucleotide ppGpp, effector of the RelA-dependent stringent response, confers mecillinam resistance and allows cells to divide as spheres in the absence of PBP2 activity. In this study we have characterized an insertion mutation which confers mecillinam resistance in wild-type and DeltarelA strains but not in DeltarelADeltaspoT strains, devoid of ppGpp. The mutant has an insertion in the fes gene, coding for enterochelin esterase. This cytoplasmic enzyme hydrolyses enterochelin-Fe(3+) complexes, making the scavenged iron available to the cells. We show that inactivation of the fes gene causes iron limitation on rich medium plates and a parallel SpoT-dependent increase of the ppGpp pool, as judged by the induction of the iron-regulated fiu::lacZ fusion and the repression of the stringently controlled P1(rrnB)::lacZ fusion respectively. We further show, by direct ppGpp assays, that iron starvation in liquid medium produces a SpoT-dependent increase of the ppGpp pool, strongly suggesting a role for iron in the balance of the two activities of SpoT, synthesis and hydrolysis of (p)ppGpp. Finally, we present evidence that ppGpp exerts direct or indirect positive control on iron uptake, suggesting a simple homeostatic regulatory circuit: iron limitation leads to an increased ppGpp pool, which increases the expression of iron uptake genes, thereby alleviating the limitation.     

Selected amplification of the cell division genes ftsQ-ftsA-ftsZ in Escherichia coli

Rapidly growing Escherichia coli is unable to divide in the presence of the antibiotic mecillinam, whose direct target is penicillin-binding protein 2 (PBP2), responsible for the elongation of the cylindrical portion of the cell wall. Division can be restored in the absence of PBP2 activity by increasing the concentration of the cell division proteins FtsQ, FtsA, and FtsZ. We tried to identify regulators of the ftsQ-ftsA-ftsZ operon among mecillinam-resistant mutants, which include strains overexpressing these genes. By insertional mutagenesis with mini-Tn10 elements, we selected for insertions that conferred mecillinam resistance. Among 15 such mutants, 7 suppressed the thermosensitivity of the ftsZ84(Ts) mutant, strongly suggesting that they had increased FtsZ activity. In all 7 cases, however, the mutants resulted from a duplication of the ftsQAZ region. These duplications seemed to result from multiple events, suggesting that no simple insertional inactivation can result in a mutant with sufficiently amplified ftsQAZ expression to confer mecillinam resistance. The structure of the duplications suggests a general method for constructing directed duplications of precise sequences.     

Mecillinam resistance in Escherichia coli is conferred by loss of a second activity of the AroK protein.

Mecillinam, a beta-lactam antibiotic specific to penicillin-binding protein 2 (PBP 2) in Escherichia coli, blocks cell wall elongation and, indirectly, cell division, but its lethality can be overcome by increased levels of ppGpp, the nucleotide effector of the stringent response. We have subjected an E. coli K-12 strain to random insertional mutagenesis with a mini-Tn10 element. One insertion, which was found to confer resistance to mecillinam in relA+ and relA strains, was mapped at 75.5 min on the E. coli map and was located between the promoters and the coding sequence of the aroK gene, which codes for shikimate kinase 1, one of two E. coli shikimate kinases, both of which are involved in aromatic amino acid biosynthesis. The mecillinam resistance conferred by the insertion was abolished in a delta relA delta spoT strain completely lacking ppGpp, and it thus depends on the presence of ppGpp. Furthermore, the insertion increased the ppGpp pool approximately twofold in a relA+ strain. However, this increase was not observed in relA strains, although the insertion still conferred mecillinam resistance in these backgrounds, showing that mecillinam resistance is not due to an increased ppGpp pool. The resistance was also abolished in an ftsZ84(Ts) strain under semipermissive conditions, and the aroK::mini-Tn10 allele partially suppressed ftsZ84(Ts); however, it did not increase the concentration of the FtsZ cell division protein. The insertion greatly decreased or abolished the shikimate kinase activity of AroK in vivo and in vitro. The two shikimate kinases of E. coli are not equivalent; the loss of AroK confers mecillinam resistance, whereas the loss of Arol, does not. Furthermore, the ability of the aroK mutation to confer mecillinam resistance is shown to be independent of polar effects on operon expression and of effects on the availability of aromatic amino acids or shikimic acid. Instead, we conclude that the AroK protein has a second activity, possibly related to cell division regulation, which confers mecillinam sensitivity. We were able to separate the AroK activities mutationally with an aroK mutant allele lacking shikimate kinase activity but still able to confer mecillinam sensitivity.     

Buoyant density studies of several mecillinam-resistant and division mutants of Escherichia coli.

The buoyant density of wild-type Escherichia coli cells has previously been reported not to vary with growth rate and cell size or age. In the present report we confirm these findings, using Percoll gradients, and analyze the recently described lov mutant, which was selected for its resistance to mecillinam and has been suggested to be affected in the coordination between mass growth and envelope synthesis. The average buoyant density of lov mutant cells was significantly lower than that of wild-type cells. Similarly, the buoyant density of wild-type cells decreased in the presence of mecillinam. The density of the lov mutant, like that of the wild type, was invariant over a 2.8-fold range in growth rate. In this range, however, the average cell volume was also constant. Analysis of buoyant density as a function of cell volume in individual cultures revealed that smaller (newborn) lov mutant cells had higher density than larger (old) cells; however, the density of the small cells never approached that of the wild-type cells, whose density was independent of cell size (age). A pattern similar to that of lov mutant cells was observed in cells carrying the mecillinam-resistant mutations pbpA(Ts) and rodA(Ts) and the division mutation ftsI(Ts) at nonpermissive temperatures as well as in wild-type cells treated with mecillinam, but not in mecillinam-resistant crp or cya mutants.     

The Escherichia coli lov gene product connects peptidoglycan synthesis, ribosomes and growth rate.

Mecillinam, a beta-lactam antibiotic which binds specifically to penicillin-binding protein 2 (PBP2), blocks lateral cell-wall elongation, induces spherical morphology and ultimately kills bacteria. We describe here a new mecillinam-resistant mutant of Escherichia coli, the lov mutant. It possesses active PBP2, as evidenced by its rod shape in the absence of mecillinam (but not in its presence), its ability to filament when septation is inhibited, and its penicillin-binding ability. The lov mutant grows slowly but seems to regulate its macromolecular parameters properly: cell volume, RNA content (ribosome concentration), and DNA content are appropriate for the growth rate, and the growth yield is identical to that of wild type. The lov mutation is located at 41 min on the E.coli genetic map and is recessive. Certain rpsL (StrR) mutations suppress the lov mutant's mecillinam resistance. The allele specificity of the suppression suggests that the lov gene product may interact directly with the ribosomes. The lov gene product thus seems to define a link between PBP2 (the mecillinam target) and the ribosomes; we propose that this link is involved in transmitting information on the growth rate (ribosome concentration) to the peptidoglycan synthesizing apparatus.     

Thermoinducible filamentation in Escherichia coli due to an altered RNA polymerase beta subunit is suppressed by high levels of ppGpp.

The Escherichia coli strain known as GC2553, FB8, UTH1038, or K12S (Luria), considered an F- lambda- wild-type strain, is shown here to carry a cryptic mutation, ftsR1, causing nonlethal filamentation during exponential growth in Luria-Bertani (LB) broth at 42 degrees C and the inability to grow in salt-free LB broth at 42 degrees C. The ftsR1 mutation is completely suppressed in genetic backgrounds which increase RelA-dependent synthesis of the nucleotide ppGpp, i.e., argS201 (Mecr) and alaS21 (Mecr) mutations, affecting aminoacyl-tRNA synthetases, or the presence of a plac-relA' plasmid. These backgrounds also confer resistance in LB broth to the beta-lactam mecillinam, an antibiotic which specifically inhibits penicillin-binding protein 2 and, in wild-type cells, causes an indirect block in cell division. Furthermore, the ftsR1 mutant (but not an isogenic ftsR+ strain) is sensitive to mecillinam in minimal glucose medium at 37 degrees C. Since the division block caused by mecillinam can be overcome by overproduction of the cell division protein FtsZ, we tested the effect of plasmid pZAQ (carrying the ftsZ, ftsA, and ftsQ genes) on the ftsR1 mutant; it suppressed the filamentation in LB broth and the mecillinam sensitivity on minimal glucose medium at 37 degrees C but not the growth defect in salt-free LB broth at 42 degrees C. Genetic analysis indicated that the full phenotype of the ftsR1 mutant is due to a single mutation in the rpoB gene (90 min), coding for the beta subunit of RNA polymerase; we call this allele rpoB369(Fts). We propose that the rpoB369(Fts) mutation alters the specificity of the polymerase and that the mutant enzyme can recover normal activity in the presence of high salt concentrations or via interaction with the nucleotide ppGpp.     

Functional redundancy of division specific penicillin‐binding proteins in Bacillus subtilis

Bacterial cell division involves the dynamic assembly of a diverse set of proteins that coordinate the invagination of the cell membrane and synthesis of cell wall material to create the new cell poles of the separated daughter cells. Penicillin‐binding protein PBP 2B is a key cell division protein in Bacillus subtilis proposed to have a specific catalytic role in septal wall synthesis. Unexpectedly, we find that a catalytically inactive mutant of PBP 2B supports cell division, but in this background the normally dispensable PBP 3 becomes essential. Phenotypic analysis of pbpC mutants (encoding PBP 3) shows that PBP 2B has a crucial structural role in assembly of the division complex, independent of catalysis, and that its biochemical activity in septum formation can be provided by PBP 3. Bioinformatic analysis revealed a close sequence relationship between PBP 3 and Staphylococcus aureus PBP 2A, which is responsible for methicillin resistance. These findings suggest that mechanisms for rescuing cell division when the biochemical activity of PBP 2B is perturbed evolved prior to the clinical use of β‐lactams.     

Penicillin-binding protein PBP2 of Escherichia coli localizes preferentially in the lateral wall and at mid-cell in comparison with the old cell pole

The localization of penicillin-binding protein 2 (PBP2) in Escherichia coli has been studied using a functional green fluorescent protein (GFP)-PBP2 fusion protein. PBP2 localized in the bacterial envelope in a spot-like pattern and also at mid-cell during cell division. PBP2 disappeared from mid-cell just before separation of the two daughter cells. It localized with a preference for the cylindrical part of the bacterium in comparison with the old cell poles, which are known to be inert with respect to peptidoglycan synthesis. In contrast to subunits of the divisome, PBP2 failed to localize at mid-cell when PBP3 was inhibited by the specific antibiotic aztreonam. Therefore, despite its dependency on active PBP3 for localization at mid-cell, it seems not to be an integral part of the divisome. Cells grown for approximately half a mass doubling time in the presence of the PBP2 inhibitor mecillinam synthesized nascent cell poles with an increased diameter, indicating that PBP2 is required for the maintenance of the correct diameter of the new cell pole.     

Penicillin-binding protein 2 inactivation in Escherichia coli results in cell division inhibition, which is relieved by FtsZ overexpression.

Aminoacyl-tRNA synthetase mutants of Escherichia coli are resistant to amdinocillin (mecillinam), a beta-lactam antibiotic which specifically binds penicillin-binding protein 2 (PBP2) and prevents cell wall elongation with concomitant cell death. The leuS(Ts) strain, in which leucyl-tRNA synthetase is temperature sensitive, was resistant to amdinocillin at 37 degrees C because of an increased guanosine 5'-diphosphate 3'-diphosphate (ppGpp) pool resulting from partial induction of the stringent response, but it was sensitive to amdinocillin at 25 degrees C. We constructed a leuS(Ts) delta (rodA-pbpA)::Kmr strain, in which the PBP2 structural gene is deleted. This strain grew as spherical cells at 37 degrees C but was not viable at 25 degrees C. After a shift from 37 to 25 degrees C, the ppGpp pool decreased and cell division was inhibited; the cells slowly carried out a single division, increased considerably in volume, and gradually lost viability. The cell division inhibition was reversible when the ppGpp pool increased at high temperature, but reversion required de novo protein synthesis, possibly of septation proteins. The multicopy plasmid pZAQ, overproducing the septation proteins FtsZ, FtsA, and FtsQ, conferred amdinocillin resistance on a wild-type strain and suppressed the cell division inhibition in the leuS(Ts) delta (rodA-pbpA)::Kmr strain at 25 degrees C. The plasmid pAQ, in which the ftsZ gene is inactivated, did not confer amdinocillin resistance. These results lead us to hypothesize that the nucleotide ppGpp activates ftsZ expression and thus couples cell division to protein synthesis.     

High and selective resistance to mecillinam in adenylate cyclase-deficient or cyclic adenosine 3'',5''-monophosphate receptor protein-deficient mutants of Escherichia coli.

Adenylate cyclase-deficient (cya) mutants of Escherichia coli K-12 were selectively and highly resistant to mecillinam (FL1060) among several beta-lactam antibiotics in the absence of cyclic adenosine 3',5'-monophosphate (cAMP). They became sensitive to the drug in the presence of cAMP. Also, cAMP receptor protein-negative (crp) mutants, with the exception of strain 5333, were highly resistant to mecillinam in the presence and in the absence of cAMP. Mecillinam exerted two distinct and sequential effects in both cya+ strains and cya strains supplemented with cAMP: (i) rounding of cells and (ii) cessation of cell division. The first effect was accompanied by a decrease in growth rate, whereas the second effect was accompanied by enlargement and lysis of the rounded cells. The second effect of mecillinam was dependent on inoculum size and cAMP. When the cell density was above about 10(6) cells per ml, the rounded cells stopped dividing but did not lyse. In the absence of cAMP, cya strains neither stopped dividing nor lysed; they were resistant to the second, lethal effect of mecillinam.     

A mecillinam-sensitive peptidoglycan crosslinking reaction in Escherichia coli

The amidinopenicillin, mecillinam, induces the formation of spherical cells of Escherichia coli by inactivation of penicillin-binding protein 2 (PBP2). A mecillinam-sensitive peptidoglycan crosslinking reaction has been demonstrated in particulate membrane preparations from this organism. The activity was detected in membranes that contained elevated levels of PBP2 and in which crosslinking reactions due to all other PBPs had been inactivated with the cephamycin antibiotic, cefmetazole. The particulate membrane preparation catalyzed synthesis of peptidoglycan that was up to 20% crosslinked from nucleotide precursors. Crosslinkage of the peptidoglycan was inhibited 50% by 0.2 μg mecillinam per ml but was not inhibited by much higher concentrations of cephamycins, which have very low affinity for PBP2. The crosslinking reaction appears to be due to the transpeptidase activity of PBP2, which is implicated in the mechanism of cell shape determination, and is the killing target for mecillinam.     

Septal localization of penicillin-binding protein 1 in Bacillus subtilis.

Previous studies have shown that Bacillus subtilis cells lacking penicillin-binding protein 1 (PBP1), encoded by ponA, have a reduced growth rate in a variety of growth media and are longer, thinner, and more bent than wild-type cells. It was also recently shown that cells lacking PBP1 require increased levels of divalent cations for growth and are either unable to grow or grow as filaments in media low in Mg2+, suggesting a possible involvement of PBP1 in septum formation under these conditions. Using epitope-tagging and immunofluorescence microscopy, we have now shown that PBP1 is localized at division sites in vegetative cells of B. subtilis. In addition, we have used fluorescence and electron microscopy to show that growing ponA mutant cells display a significant septation defect, and finally by immunofluorescence microscopy we have found that while FtsZ localizes normally in most ponA mutant cells, a significant proportion of ponA mutant cells display FtsZ rings with aberrant structure or improper localization, suggesting that lack of PBP1 affects FtsZ ring stability or assembly. These results provide strong evidence that PBP1 is localized to and has an important function in the division septum in B. subtilis. This is the first example of a high-molecular-weight class A PBP that is localized to the bacterial division septum.     

A cya deletion mutant of Escherichia coli develops thermotolerance but does not exhibit a heat-shock response

An adenyl cyclase deletion mutant (cya) of E. coli failed to exhibit a heat-shock response even after 30 min at 42 degrees C. Under these conditions, heat-shock protein synthesis was induced by 10 min in the wild-type strain. These results suggest that synthesis of heat-shock proteins in E. coli requires the cya gene. This hypothesis is supported by the finding that a presumptive cyclic AMP receptor protein (CRP) binding site exists within the promoter region of the E. coli htpR gene. In spite of the absence of heat-shock protein synthesis, when treated at 50 degrees C, the cya mutant is relatively more heat resistant than wild type. Furthermore, when heat shocked at 42 degrees C prior to exposure at 50 degrees C, the cya mutant developed thermotolerance. These results suggest that heat-shock protein synthesis is not essential for development of thermotolerance in E. coli.     

Regulation of cell wall morphogenesis in Bacillus subtilis by recruitment of PBP1 to the MreB helix

The bacterial actin homologue MreB plays a key role in cell morphogenesis. In Bacillus subtilis MreB is essential under normal growth conditions and mreB mutants are defective in the control of cell diameter. However, the precise role of MreB is still unclear. Analysis of the lethal phenotypic consequences of mreB disruption revealed an unusual bulging phenotype that precedes cell death. A similar phenotype was seen in wild-type cells at very low Mg²⁺ concentrations. We found that inactivation of the major bi-functional penicillin-binding protein (PBP) PBP1 of B. subtilis restored the viability of an mreB null mutant as well as preventing bulging in both mutant and wild-type backgrounds. Bulging was associated with delocalization of PBP1. We show that the normal pattern of localization of PBP1 is dependent on MreB and that the proteins can physically interact using in vivo pull-down and bacterial two-hybrid approaches. Interactions between MreB and several other PBPs were also detected. Our results suggest that MreB filaments associate directly with the peptidoglycan biosynthetic machinery in B. subtilis as part of the mechanism that brings about controlled cell elongation.     

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.