Characterization of PrpC from Bacillus subtilis, a member of the PPM phosphatase family.

We cloned the yloO gene and purified a His-tagged form of its product, the putative protein phosphatase YloO, which we now designate PrpC. This closely resembles the human protein phosphatase PP2C, a member of the PPM family, in sequence and predicted secondary structure. PrpC has phosphatase activity in vitro against a synthetic substrate, p-nitrophenol phosphate, and endogenous Bacillus subtilis proteins. The prkC and prpC genes are adjacent on the chromosome, and the phosphorylated form of PrkC is a substrate for PrpC. These findings suggest that PrkC and PrpC may function as a couple in vivo.

The replication checkpoint control in Bacillus subtilis: identification of a novel RTP-binding sequence essential for the replication fork arrest after induction of the stringent response.

We have shown previously that induction of the stringent response in Bacillus subtilis resulted in the arrest of chromosomal replication between 100 and 200 kb either side of oriC at distinct stop sites, designated LSTer and RSTer, left and right stringent terminators respectively. This replication checkpoint was also shown to involve the RTP protein, normally active at the chromosomal terminus. In this study, we show that the replication block is absolutely dependent upon RelA, correlated with high levels of ppGpp, but that efficient arrest at STer sites also requires RTP. DNA-DNA hybridization data indicated that one or more such LSTer sites mapped to gene yxcC (-128 kb from oriC). A 7.75 kb fragment containing this gene was cloned into a theta replicating plasmid, and plasmid replication arrest, requiring both RelA and RTP, was demonstrated. This effect was polar, with plasmid arrest only detected when the fragment was orientated in the same direction with respect to replication, as in the chromosome. This LSTer2 site was further mapped to a 3.65 kb fragment overlapping the next40 probe. Remarkably, this fragment contains a 17 bp sequence (B'-1) showing 76% identity with an RTP binding site (B sequence) present at the chromosomal terminus. This B'-1 sequence, located in the gene yxcC, efficiently binds RTP in vitro, as shown by DNA gel retardation studies and DNase I footprinting. Importantly, precise deletion of this sequence abolished the replication arrest. We propose that this modified B site is an essential constituent of the LSTer2 site. The differences between arrest at the normal chromosomal terminus and arrest at LSTer site are discussed.

Sequencing of regions downstream of addA (98 degrees) and citG (289 degrees) in Bacillus subtilis.

The nucleotide sequence of 17.3 kbp downstream of addA (98 degrees) on the Bacillus subtilis chromosome was determined. Twenty putative ORFs were identified. Three of them coincided with known B. subtilis genes, addA, sbcD and wprA. The product of four other ORFs showed similarity to SbcC of Clostridium perfringens, CotH of B. subtilis, 2-hydroxyhepta-2,4-diene-1,7-diodate isomerase of Methanococcus jannaschi and a putative ORF of Pseudomonas syringae. In addition, a sequence of 7.6 kbp downstream of citG (189 degrees) was analysed. Among 10 putative ORFs identified, two coincided with known genes, citG and mrgA, whilst three showed homology with X86780, a sensory protein kinase of Streptomyces hygroscopicus, an alkaline phosphatase regulatory protein and a hypothetical protease, YyxA, of B. subtilis.

A Bacillus subtilis chromosome segment at the 100 degrees to 102 degrees position encoding 11 membrane proteins.

The 25.9 kbp region upstream of nprB at 100 degrees-102 degrees on the Bacillus subtilis chromosome was sequenced. This revealed a known gene, degA, which was previously mislocated on the genetic map. A total of 29 putative ORFs were identified including a cluster of three ORFs whose products show clear homology with sulphate adenylyl pathway enzymes and, in addition, 11 ORFs whose products have one or more membrane domains, as indicated by their hydropathy profiles.

Cell cycle checkpoints in bacteria.

When DNA replication is interrupted in bacteria, a specific inhibitor (SfiA), a component of the SOS system, is synthesised which transiently blocks cell division. This is the prototype, dispensable, cell cycle checkpoint, essential for maximal survival under a particular stress. In contrast, no process specifically signalling the termination of chromosomal replication to activate the subsequent division event, which might be termed an essential checkpoint, has yet been demonstrated. In E coli, a specific mechanism is apparently required to reactivate replication forks blocked by damage, but its molecular basis is unclear. Induction of the stringent response, mediated by RelA via the level of ppGpp, presumably to optimise macromolecular synthesis according to the availability of nutrients, activates a control system which inhibits DNA replication in both E coli and B subtilis. In E coli, this blocks new rounds of initiation at oriC, although the mechanism is not clear. Conversely, initiation is not blocked in B subtilis, but replication is blocked apparently at a number of distinct sites 100-200 kb downstream and either side of oriC. This nutrient-dependent replicating checkpoint specifically requires RTP, the chromosomal terminator protein, and new evidence indicates that specific RTP binding sites may be involved in this post-initiation control mechanism. A similar post-initiation control mechanism appears to block replication reversibly after premature initiation in B subtilis, indicating that this system may have a dual function, limiting replication in starvation conditions and as a mechanism to compensate for premature initiations.

Characterization of an Escherichia coli mutant, feeA, displaying resistance to the calmodulin inhibitor 48/80 and reduced expression of the rare tRNA3Leu.

We previously described a mutation feeB1 conferring a temperature-sensitive filamentation phenotype and resistance to the calmodulin inhibitor 48/80 in Escherichia coli, which constitutes a single base change in the acceptor stem of the rare tRNA3Leu recognizing CUA codons. We now describe a second mutant, feeA1, unlinked to feeB, but displaying a similar phenotype, 48/80 resistance and a reduced growth rate at the permissive temperature, 30 degrees C, and temperature-sensitive, forming short filaments at 42 degrees C. In the feeA mutant, tRNA3Leu expression (but not that of tRNA1Leu) was reduced approximately fivefold relative to the wild type. We previously showed that the synthesis of beta-galactosidase, which unusually requires the translation of 6-CUA codons, was substantially reduced, particularly at 42 degrees C, in feeB mutants. The feeA mutant also shows drastically reduced synthesis of beta-galactosidase at the non-permissive temperature and reduced levels even at the permissive temperature. We also show that increased copy numbers of the abundant tRNA1Leu, which can also read CUA codons at low efficiency, suppressed the effects of feeA1 under some conditions, providing further evidence that the mutant was deficient in CUA translation. This, and the previous study, demonstrates that mutations which either reduce the activity of tRNA3Leu or the cellular amount of tRNA3Leu confer resistance to the drug 48/80, with concomitant inhibition of cell division at 42 degrees C.

Resistance to trifluoroperazine, a calmodulin inhibitor, maps to the fabD locus in Escherichia coli.

A mutant, tfpA1, resistant to the calmodulin inhibitor trifluoroperazine (TFP) at 30 degrees C, was isolated in Escherichia coli. The mutant showed a reduced growth rate at 30 degrees C and was temperature sensitive (ts) at 42 degrees C for growth, forming short filaments. The mutation was mapped to the 24 min region of the chromosome and the gene was cloned by complementation of the ts defect. Subsequent subcloning, complementation analysis, marker rescue mapping and sequencing, identified tfpA as fabD, encoding the 35 kDa, malonyl-coenzyme A transacylase (MCT) enzyme, required for the initial step in the elongation cycle for fatty acid biosynthesis. Resistance to TFP may result from altered permeability of the cell envelope, although the mutant remained sensitive to other calmodulin inhibitors and to other antibacterial agents. Alternatively, resistance may be more indirect, resulting from alterations in intracellular Ca++ levels which affect the activity of the TFP target in some way.

A checkpoint involving RTP, the replication terminator protein, arrests replication downstream of the origin during the Stringent Response in Bacillus subtilis.

Regulation of DNA replication in Bacillus subtilis involves a post-initiation mechanism which is subject to control by the Stringent System, an essential regulatory network, mediated by the alarmone, ppGpp. In detailed studies using DNA-DNA hybridization procedures, we have now shown that, following the induction of the Stringent Response, replication is blocked downstream of the origin, on the left, close to the hut marker (-175 kb) and on the right, beyond the soft10 marker (+199 kb). In addition, we provide evidence that inhibition of replication under these conditions requires the replication terminator protein (RTP). In a mutant lacking RTP, a protein normally involved in termination of chromosomal replication through recognition of specific terminator sequences, replication continues past the sites normally blocked by the Stringent Response. These data strengthen the argument that this second level of control of DNA replication occurs at specific sites, the Strigent Terminus (STer) sites, either side of orlC. Such sites are presumably related to the sequence involved in RTP recognition at the terminus, terC. We propose that the binding of RTP must be modulated, perhaps through the action of ppGpp, to recognize post-initiation control sequences during the Stringent Response, in order to block replisome movement. This, therefore, acts as a checkpoint in chromosome elongation.

Identification and preliminary characterization of temperature-sensitive mutations affecting HlyB, the translocator required for the secretion of haemolysin (HlyA) from Escherichia coli.

We have carried out a genetic analysis of Escherichia coli HlyB using in vitro(hydroxylamine) mutagenesis and regionally directed mutagenesis. From random mutagenesis, three mutants, temperature sensitive (Ts) for secretion, were isolated and the DNA sequenced: Gly10Arg close to the N-terminus, Gly408Asp in a highly conserved small periplasmic loop region PIV, and Pro624Leu in another highly conserved region, within the ATP-binding region. Despite the Ts character of the Gly10 substitution, a derivative of HlyB, in which the first 25 amino acids were replaced by 21 amino acids of the lambda Cro protein, was still active in secretion of HlyA. This indicates that this region of HlyB is dispensable for function. Interestingly, the Gly408Asp substitution was toxic at high temperature and this is the first reported example of a conditional lethal mutation in HlyB. We have isolated 4 additional mutations in PIV by directed mutagenesis, giving a total of 5 out of 12 residues substituted in this region, with 4 mutations rendering HlyB defective in secretion. The Pro624 mutation, close to the Walker B-site for ATP binding in the cytoplasmic domain is identical to a mutation in HisP that leads to uncoupling of ATP hydrolysis from the transport of histidine. The expression of a fully functional haemolysin translocation system comprising HlyC,A,B and D increases the sensitivity of E. coli to vancomycin 2.5-fold, compared with cells expressing HlyB and HlyD alone. Thus, active translocation of HlyA renders the cells hyperpermeable to the drug. Mutations in hlyB affecting secretion could be assigned to two classes: those that restore the level of vancomycin resistance to that of E. coli not secreting HlyA and those that still confer hypersensitivity to the drug in the presence of HlyA. We propose that mutations that promote vancomycin resistance will include mutations affecting initial recognition of the secretion signal and therefore activation of a functional transport channel. Mutations that do not alter HlyA-dependent vancomycin sensitivity may, in contrast, affect later steps in the transport process.

A mutant cysteinyl-tRNA synthetase affecting timing of chromosomal replication initiation in B. subtilis and conferring resistance to a protein kinase C inhibitor.

A Bacillus subtilis mutant spnA95 was isolated as resistant at 30 degrees C to the protein kinase C (PKC) inhibitor, sphinganine, and temperature sensitive for growth. As deduced by flow cytometry measurements, the mutant has a 35% reduced initiation mass at permissive temperature, resulting in initiation of DNA replication much earlier in the cell cycle than in the wild type. This modification is accompanied by a change in cell size, as determined by phase-contrast microscopy and flow cytometry. Therefore, this strain displays the characteristics of a novel cell clock mutant. spnA is a newly identified gene in B.subtilis and was shown to encode a cysteinyl-tRNA synthetase. At non-permissive temperature, the mutant was defective in the synthesis of P70, a protein with several characteristics of PKC (a cysteine-rich protein). As one possibility, we propose that the altered timing of replication may be due to the reduced synthesis of specific cysteine-rich proteins normally involved in controlling chromosomal replication initiation in B. subtilis.

A single base change in the acceptor stem of tRNA(3Leu) confers resistance upon Escherichia coli to the calmodulin inhibitor, 48/80.

We have isolated several classes of spontaneous mutants resistant to the calmodulin inhibitor 48/80 which inhibits cell division in Escherichia coli K12. Several mutants were also temperature sensitive for growth and this property was exploited to clone a DNA fragment from an E. coli gene library restoring growth at 42 degrees C and drug sensitivity at 30 degrees C in one such mutant. Physical and genetic mapping confirmed that both the mutation and the cloned DNA were located at 15.5 min on the E. coli chromosome at a locus designated feeB. By subcloning, complementation analysis and sequencing, the feeB locus was identified as identical to the tRNA(CUALEU) gene. When the mutant locus was isolated and sequenced, the mutation was confirmed as a single base change, C to A, at position 77 in the acceptor stem of this rare Leu tRNA. In other studies we obtained evidence that this mutant tRNA, recognizing the rare Leu codon, CUA, was defective in translation at both permissive and non-permissive temperatures. The feeB1 mutant is defective in division and shows a reduced growth rate at non-permissive temperature. We discuss the possibility that the mutant tRNA(3Leu) is limiting for the synthesis of a polypeptide(s), requiring several CUA codons for translation which in turn regulates in some way the level or activity of the drug target, a putative cell cycle protein.

Post-initiation control of chromosomal replication in Bacillus subtilis: a mechanism for limiting over-replication or for duplicating key growth and sporulation genes?

We used the Bacillus subtilis dnaB37 mutant, which is defective in initiation, to synchronize DNA replication in order to identify the first fragments to be replicated following initiation and to study the control of this process under various conditions. We show by DNA/DNA hybridization analysis that, after returning the mutant from 45 degrees C to the permissive temperature (30 degrees C), the origin region relative to other sequences is over-replicated (approximately 2-fold) during the first round. This was confirmed by autoradiographic analysis. The over-replicated region is however limited to about 190 kb on the left and right arms. Replication apparently resumes from these positions during the following round of replication. We propose that, in B. subtilis, in addition to the first level of control at the origin, there is a second level or post-initiation control downstream of the origin which limits DNA replication resulting from premature initiation. We believe that these two levels of control are tightly coupled under conditions of balanced growth. Using the same system, we have now shown that DNA replication is subject to "stringent control", an important regulatory network in bacteria. These studies demonstrate that the inhibition of replication induced during the "stringent response" does not occur at the primary origin. In fact, by DNA/DNA hybridization, replication forks were found to be blocked at similar positions to the post-initiation control sites described above. Moreover, replication appears to resume from regions close to the stalled replisomes upon removal of the stringent response.(ABSTRACT TRUNCATED AT 250 WORDS)

The stringent response blocks DNA replication outside the ori region in Bacillus subtilis and at the origin in Escherichia coli.

When the Bacillus subtilis dnaB37 mutant, defective in initiation, is returned to permissive temperature after growth at 45 degrees C, DNA replication is synchronized. Under these conditions, we have shown previously that DNA replication is inhibited when the Stringent Response is induced by the amino acid analogue, arginine hydroxamate. We have now shown, using DNA-DNA hybridization analysis, that substantial replication of the oriC region nevertheless occurs during the Stringent Response, and that replication inhibition is therefore implemented downstream from the origin. On the left arm, replication continues for at least 190 x 10(3) base-pairs to the gnt gene and for a similar distance on the right arm to the gerD gene. When the Stringent Response is lifted, DNA replication resumed downstream from oriC on both arms, confirming that DNA replication is regulated at a post-initiation level during the Stringent Response in B. subtilis. Resumption of DNA synthesis following the lifting of the Stringent Response did not require protein or RNA synthesis or the initiation protein DnaB. We suggest, therefore, that a specific control region, involving Stringent Control sites, facilitate reversible inhibition of fork movement downstream from the origin via modifications of a replisome component during the Stringent Response. In contrast, in Escherichia coli, induction of the Stringent Response appears to block initiation of DNA replication at oriC itself. No DNA synthesis was detected in the oriC region and, upon lifting the Stringent Response, replication occurred from oriC. Post-initiation control in B. subtilis therefore results in duplication of many key genes involved in growth and sporulation. We discuss the possibility that such a control might be linked to differentiation in this organism.

Analysis of the membrane organization of an Escherichia coli protein translocator, HlyB, a member of a large family of prokaryote and eukaryote surface transport proteins.

Haemolysin B (HlyB) is essential for secretion of the 107 x 10(3) Mr haemolysin A protein from Escherichia coli and is a member of a family of highly conserved, apparently ATP-dependent surface proteins in many organisms. We have shown in this study that both HlyB and HlyD fractionate primarily with the cytoplasmic membrane of E. coli and are accessible to proteases after removal of the outer membrane. We have measured experimentally the topological organization of HlyB within the membrane by construction of fusions to beta-lactamase as a reporter. The predicted folding of HlyB, with a minimum of six transmembrane segments, does not always coincide with regions of highest average hydrophobicity. This suggests that HlyB may have a novel organization within the bilayer. From our data and comparative sequence analysis, we have been able to predict very similar topological models for the other members of the HlyB family.

Overreplication of the origin region in the dnaB37 mutant of Bacillus subtilis: postinitiation control of chromosomal replication.

When the Bacillus subtilis dnaB37 mutant, defective in initiation, is returned to permissive temperature after accumulation of initiation proteins at 45 degrees C, we have shown, by extensive DNA.DNA hybridization analysis, that the origin region is replicated in excess (approximately 2-fold). However, this replication is limited to a region of about 120-175 kilobases on either side of the origin. This has been confirmed by autoradiographic analysis of the overreplicated region. During the second round of synchronized replication at 30 degrees C, replication in fact appears to resume from the stalled forks on either side of the origin. We propose that in B. subtilis, in addition to a first level of control at the origin, a second level of control exists downstream of the origin in order to limit overreplication of the chromosome. These two controls might normally be tightly coupled. We suggest that the second level of control is exerted through the reversible inhibition of replisome movement at specific regions on either side of the origin.

A single calcium flux triggers chromosome replication, segregation and septation in bacteria: a model.

Abrupt changes in the concentration of intracellular calcium, through the mediation of calmodulin, is presumed to play an essential role in many molecular processes in eukaryotes including triggering cell cycle events. Although early studies failed to establish any role for calcium in the growth of bacteria, recent studies have demonstrated that bacteria have several calcium transport systems, and an intracellular concentration of free calcium identical to that of higher organisms, which appears to fluctuate during the cell cycle. Moreover, calmodulin-like proteins have been reported in bacteria, and the growth of E. coli is sensitive to calmodulin inhibitors. In this article we propose that a single flux of calcium, abruptly raising the intracellular concentration of free calcium, is responsible for the triggering in bacteria of the major cell cycle events, initiation of DNA replication, chromosome partition and cell division. We predict that major roles in this process will involve a bacterial calmodulin-like protein and a primitive cytoskeleton. The mechanism of triggering different cell cycle events by a single calcium flux is discussed.

Chromosomal initiation in Bacillus subtilis may involve two closely linked origins.

When the dnaB37 initiation mutant of Bacillus subtilis is returned to a permissive temperature following a period at 45 degrees C, a synchronous round of DNA replication immediately ensues. Using this system we have been able to analyse the first fragments to be replicated while avoiding the use of thymine starvation or inhibitors of DNA replication. Such treatments are necessary to achieve even modest synchrony in germinating spores. Our results showed that the first fragment to be replicated was a 4 kb BamHI-SalI restriction fragment, BS6. In contrast, when the analysis was performed out in the presence of novobiocin, an inhibitor of DNA gyrase, replication from BS6 was inhibited and the first fragment to be replicated was BS5, a 5.6 kb fragment located 1.7 kb to the right of BS6. Replication from both putative origins was suppressed by rifamycin and was dependent upon dnaB. The results are discussed in relation to previous attempts to identify the first replicating fragment in germinating spores. We also discuss the possibility that B. subtilis contains two origins and suggest that either can act as the primary origin under certain conditions, or alternatively that both origins may act in concert in normal bidirectional replication, each site being required for the leading strand in each direction.