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

Emerging and divergent roles of pyrophosphorylated nucleotides in bacterial physiology and pathogenesis

Bacteria inhabit diverse environmental niches and consequently must modulate their metabolism to adapt to stress. The nucleotide second messengers guanosine tetraphosphate (ppGpp) and guanosine pentaphosphate (pppGpp) (collectively referred to as (p)ppGpp) are essential for survival during nutrient starvation. (p)ppGpp is synthesized by the RelA-SpoT homologue (RSH) protein family and coordinates the control of cellular metabolism through its combined effect on over 50 proteins. While the role of (p)ppGpp has largely been associated with nutrient limitation, recent studies have shown that (p)ppGpp and related nucleotides have a previously underappreciated effect on different aspects of bacterial physiology, such as maintaining cellular homeostasis and regulating bacterial interactions with a host, other bacteria, or phages. (p)ppGpp produced by pathogenic bacteria facilitates the evasion of host defenses such as reactive nitrogen intermediates, acidic pH, and the complement system. Additionally, (p)ppGpp and pyrophosphorylated derivatives of canonical adenosine nucleotides called (p)ppApp are emerging as effectors of bacterial toxin proteins. Here, we review the RSH protein family with a focus on its unconventional roles during host infection and bacterial competition.

Single-Molecule Dynamics at a Bacterial Replication Fork after Nutritional Downshift or Chemically Induced Block in Replication

Replication forks must respond to changes in nutrient conditions, especially in bacterial cells. By investigating the single-molecule dynamics of replicative helicase DnaC, DNA primase DnaG, and lagging-strand polymerase DnaE in the model bacterium Bacillus subtilis, we show that proteins react differently to stress conditions in response to transient replication blocks due to DNA damage, to inhibition of the replicative polymerase, or to downshift of serine availability. DnaG appears to be recruited to the forks by a diffusion and capture mechanism, becomes more statically associated after the arrest of polymerase, but binds less frequently after fork blocks due to DNA damage or to nutritional downshift. These results indicate that binding of the alarmone (p)ppGpp due to stringent response prevents DnaG from binding to forks rather than blocking bound primase. Dissimilar behavior of DnaG and DnaE suggests that both proteins are recruited independently to the forks rather than jointly. Turnover of all three proteins was increased during replication block after nutritional downshift, different from the situation due to DNA damage or polymerase inhibition, showing high plasticity of forks in response to different stress conditions. Forks persisted during all stress conditions, apparently ensuring rapid return to replication extension.IMPORTANCE All cells need to adjust DNA replication, which is achieved by a well-orchestrated multiprotein complex, in response to changes in physiological and environmental conditions. For replication forks, it is extremely challenging to meet with conditions where amino acids are rapidly depleted from cells, called the stringent response, to deal with the inhibition of one of the centrally involved proteins or with DNA modifications that arrest the progression of forks. By tracking helicase (DnaC), primase (DnaG), and polymerase (DnaE), central proteins of Bacillus subtilis replication forks, at a single molecule level in real time, we found that interactions of the three proteins with replication forks change in different manners under different stress conditions, revealing an intriguing plasticity of replication forks in dealing with replication obstacles. We have devised a new tool to determine rates of exchange between static movement (binding to a much larger complex) and free diffusion, showing that during stringent response, all proteins have highly increased exchange rates, slowing down overall replication, while inactivation of polymerase or replication roadblocks leaves forks largely intact, allowing rapid restart once obstacles are removed.

(p)ppGpp and the bacterial cell cycle

Genes of the Rel/Spo homolog (RSH) superfamily synthesize and/or hydrolyse the modified nucleotides pppGpp/ ppGpp (collectively referred to as (p)ppGpp) and are prevalent across diverse bacteria and in plant chloroplasts. Bacteria accumulate (p)ppGpp in response to nutrient deprivation (generically called the stringent response) and elicit appropriate adaptive responses mainly through the regulation of transcription. Although at different concentrations (p)ppGpp affect the expression of distinct set of genes, the two well-characterized responses are reduction in expression of the protein synthesis machinery and increase in the expression of genes coding for amino acid biosynthesis. In Escherichia coli, the cellular (p)ppGpp level inversely correlates with the growth rate and increasing its concentration decreases the steady state growth rate in a defined growth medium. Since change in growth rate must be accompanied by changes in cell cycle parameters set through the activities of the DNA replication and cell division apparatus, (p)ppGpp could coordinate protein synthesis (cell mass increase) with these processes. Here we review the role of (p)ppGpp in bacterial cell cycle regulation.

Stringent response processes suppress DNA damage sensitivity caused by deficiency in full-length translation initiation factor 2 or PriA helicase

When Escherichia coli grows in the presence of DNA-damaging agents such as methyl methanesulphonate (MMS), absence of the full-length form of Translation Initiation Factor 2 (IF2-1) or deficiency in helicase activity of replication restart protein PriA leads to a considerable loss of viability. MMS sensitivity of these mutants was contingent on the stringent response alarmone (p)ppGpp being at low levels. While zero levels (ppGpp°) greatly aggravated sensitivity, high levels promoted resistance. Moreover, M+ mutations, which suppress amino acid auxotrophy of ppGpp° strains and which have been found to map to RNA polymerase subunits, largely restored resistance to IF2-1- and PriA helicase-deficient mutants. The truncated forms IF2-2/3 played a key part in inducing especially severe negative effects in ppGpp° cells when restart function priB was knocked out, causing loss of viability and severe cell filamentation, indicative of SOS induction. Even a strain with the wild-type infB allele exhibited significant filamentation and MMS sensitivity in this background whereas mutations that prevent expression of IF2-2/3 essentially eliminated filamentation and largely restored MMS resistance. The results suggest different influences of IF2-1 and IF2-2/3 on the replication restart system depending on (p)ppGpp levels, each having the capacity to maximize survival under differing growth conditions.

Different effects of ppGpp on Escherichia coli DNA replication in vivo and in vitro

Inhibition of Escherichia coli DNA replication by guanosine tetraphosphate (ppGpp) is demonstrated in vitro. This finding is compatible with impairment of the DnaG primase activity by this nucleotide. However, in agreement to previous reports, we were not able to detect a rapid inhibition of DNA synthesis in E. coli cells under the stringent control conditions, when intracellular ppGpp levels increase dramatically. We suggest that the process of ppGpp-mediated inhibition of DnaG activity may be masked in E. coli cells, which could provide a rationale for explanation of differences between ppGpp effects on DNA replication in E. coli and Bacillus subtilis.

ppGpp inhibits the activity of Escherichia coli DnaG primase

DNA primase is an enzyme required for replication of both chromosomes and vast majority of plasmids. Guanosine tetra- and penta-phosphate (ppGpp and pppGpp, respectively) are alarmones of the bacterial stringent response to starvation and stress conditions, and act by modulation of the RNA polymerase activity. Recent studies indicated that the primase-catalyzed reaction is also inhibited by (p)ppGpp in Bacillus subtilis, where a specific regulation of DNA replication elongation, the replication fork arrest, was discovered. Although in Escherichia coli such a replication regulation was not reported to date, here we show that E. coli DnaG primase is directly inhibited by ppGpp and pppGpp. However, contrary to the B. subtilis primase response to the stringent control alarmones, the E, coli DnaG was inhibited more efficiently by ppGpp than by pppGpp.

When DNA replication and protein synthesis come together

In all organisms, DNA and protein are synthesized by dedicated, but unrelated, machineries that move along distinct templates with no apparent coordination. Therefore, connections between DNA replication and translation are a priori unexpected. However, recent findings support the existence of such connections throughout the three domains of life. In particular, we recently identified in archaeal genomes a conserved association between genes encoding DNA replication and ribosome-related proteins which all have eukaryotic homologs. We believe that this gene organization is biologically relevant and, moreover, that it suggests the existence of a mechanism coupling DNA replication and translation in Archaea and Eukarya.

Effects of oriC relocation on control of replication initiation in Bacillus subtilis

In bacteria, DNA replication initiation is tightly regulated in order to coordinate chromosome replication with cell growth. InEscherichia coli, positive factors and negative regulatory mechanisms playing important roles in the strict control of DNA replication initiation have been reported. However, it remains unclear how bacterial cells recognize the right time for replication initiation during the cell cycle. In the Gram-positive bacteriumBacillus subtilis, much less is known about the regulation of replication initiation, specifically, regarding negative control mechanisms which ensure replication initiation only once per cell cycle. Here we report that replication initiation was greatly enhanced in strains that had the origin of replication (oriC) relocated to various loci on the chromosome. WhenoriCwas relocated to new loci further than 250 kb counterclockwise from the native locus, replication initiation became asynchronous and earlier than in the wild-type cells. In twooriC-relocated strains (oriCatargGorpnbA, 25 ° or 30 ° on the 36 ° chromosome map, respectively), DnaA levels were higher than in the wild-type but not enough to cause earlier initiation of replication. Our results suggest that the initiation capacity of replication is accumulated well before the actual time of initiation, and its release may be suppressed by a unique DNA structure formed near the nativeoriClocus.

The stringent response and cell cycle arrest in Escherichia coli

The bacterial stringent response, triggered by nutritional deprivation, causes an accumulation of the signaling nucleotides pppGpp and ppGpp. We characterize the replication arrest that occurs during the stringent response in Escherichia coli. Wild type cells undergo a RelA-dependent arrest after treatment with serine hydroxamate to contain an integer number of chromosomes and a replication origin-to-terminus ratio of 1. The growth rate prior to starvation determines the number of chromosomes upon arrest. Nucleoids of these cells are decondensed; in the absence of the ability to synthesize ppGpp, nucleoids become highly condensed, similar to that seen after treatment with the translational inhibitor chloramphenicol. After induction of the stringent response, while regions corresponding to the origins of replication segregate, the termini remain colocalized in wild-type cells. In contrast, cells arrested by rifampicin and cephalexin do not show colocalized termini, suggesting that the stringent response arrests chromosome segregation at a specific point. Release from starvation causes rapid nucleoid reorganization, chromosome segregation, and resumption of replication. Arrest of replication and inhibition of colony formation by ppGpp accumulation is relieved in seqA and dam mutants, although other aspects of the stringent response appear to be intact. We propose that DNA methylation and SeqA binding to non-origin loci is necessary to enforce a full stringent arrest, affecting both initiation of replication and chromosome segregation. This is the first indication that bacterial chromosome segregation, whose mechanism is not understood, is a step that may be regulated in response to environmental conditions.

Mechanisms of physiological regulation of RNA synthesis in bacteria: new discoveries breaking old schemes

Although in bacterial cells all genes are transcribed by RNA polymerase, there are 2 additional enzymes capable of catalyzing RNA synthesis: poly(A) polymerase I, which adds poly(A) residues to transcripts, and primase, which produces primers for DNA replication. Mechanisms of actions of these 3 RNA-synthesizing enzymes were investigated for many years, and schemes of their regulations have been proposed and generally accepted. Nevertheless, recent discoveries indicated that apart from well-understood mechanisms, there are additional regulatory processes, beyond the established schemes, which allow bacterial cells to respond to changing environmental and physiological conditions. These newly discovered mechanisms, which are discussed in this review, include: (i) specific regulation of gene expression by RNA polyadenylation, (ii) control of DNA replication by interactions of the starvation alarmones, guanosine pentaphosphate and guanosine tetraphosphate, (p)ppGpp, with DnaG primase, (iii) a role for the DksA protein in ppGpp-mediated regulation of transcription, (iv) allosteric modulation of the RNA polymerase catalytic reaction by specific inhibitors of transcription, rifamycins, (v) stimulation of transcription initiation by proteins binding downstream of the promoter sequences, and (vi) promoter-dependent control of transcription antitermination efficiency.

Replication fork stalling at natural impediments

Accurate and complete replication of the genome in every cell division is a prerequisite of genomic stability. Thus, both prokaryotic and eukaryotic replication forks are extremely precise and robust molecular machines that have evolved to be up to the task. However, it has recently become clear that the replication fork is more of a hurdler than a runner: it must overcome various obstacles present on its way. Such obstacles can be called natural impediments to DNA replication, as opposed to external and genetic factors. Natural impediments to DNA replication are particular DNA binding proteins, unusual secondary structures in DNA, and transcription complexes that occasionally (in eukaryotes) or constantly (in prokaryotes) operate on replicating templates. This review describes the mechanisms and consequences of replication stalling at various natural impediments, with an emphasis on the role of replication stalling in genomic instability.

Nutritional control of elongation of DNA replication by (p)ppGpp

DNA replication is highly regulated in most organisms. Although much research has focused on mechanisms that regulate initiation of replication, mechanisms that regulate elongation of replication are less well understood. We characterized a mechanism that regulates replication elongation in the bacterium Bacillus subtilis. Replication elongation was inhibited within minutes after amino acid starvation, regardless of where the replication forks were located on the chromosome. We found that small nucleotides ppGpp and pppGpp, which are induced upon starvation, appeared to inhibit replication directly by inhibiting primase, an essential component of the replication machinery. The replication forks arrested with (p)ppGpp did not recruit the recombination protein RecA, indicating that the forks are not disrupted. (p)ppGpp appear to be part of a surveillance mechanism that links nutrient availability to replication by rapidly inhibiting replication in starved cells, thereby preventing replication-fork disruption. This control may be important for cells to maintain genomic integrity.

Subcellular localization of the Bacillus subtilis structural maintenance of chromosomes (SMC) protein

The Bacillus subtilis structural maintenance of chromosomes (SMC) protein is a member of a large family of proteins involved in chromosome organization. We found that SMC is a moderately abundant protein ( approximately 1000 dimers per cell). In vivo cross-linking and immunoprecipitation assays revealed that SMC binds to many regions on the chromosome. Visualization of SMC in live cells using a fusion to the green fluorescent protein (GFP) and in fixed cells using immunofluorescence microscopy indicated that a portion of SMC localizes as discrete foci in positions similar to that of the DNA replication machinery (replisome). When visualized simultaneously, SMC and the replisome were often in similar regions of the cell but did not always co-localize. Persistence of SMC foci did not depend on ongoing replication, but did depend on ScpA and ScpB, two proteins thought to interact with SMC. Our results indicate that SMC is bound to many sites on the chromosome and a concentration of SMC is localized near replication forks, perhaps there to bind and organize newly replicated DNA.

Does RNA polymerase help drive chromosome segregation in bacteria?

In contrast to eukaryotic cells, bacteria segregate their chromosomes without a conspicuous mitotic apparatus. Replication of bacterial chromosomes initiates bidirectionally from a single site (oriC), and visualization of the region of the chromosome containing oriC in living cells reveals that origins rapidly move apart toward opposite poles of the cell during the cell cycle. The motor that drives this poleward movement is unknown. An attractive candidate is RNA polymerase, which is a powerful and abundant molecular motor. If, as has been suggested for other macromolecular complexes, the movement of RNA polymerase is restricted in the cell, then transcription would translocate the DNA template, thereby providing the motive force to separate replicating chromosomes. A coordinated effect of many transcribing RNA polymerases could result from the widely conserved global bias of gene orientation away from oriC. By using fluorescence microscopy of living Bacillus subtilis cells, we demonstrate that an inhibitor of RNA polymerase acts to inhibit separation of newly duplicated DNAs near the origin of replication. We propose that the force exerted by RNA polymerase contributes to chromosome movement in bacteria, and that this force, coupled with the biased orientation of transcription units, helps to drive chromosome segregation.

A replication terminus located at or near a replication checkpoint of Bacillus subtilis functions independently of stringent control

We have examined a replication terminus (psiL1) located on the left arm of the chromosome of Bacillus subtilis and within the yxcC gene and at or near the left replication checkpoint that is activated under stringent conditions. The psiL1 sequence appears to bind to two dimers of the replication terminator protein (RTP) rather weakly and seems to possess overlapping core and auxiliary sites that have some sequence similarities with normal Ter sites. Surprisingly, the asymmetrical, isolated psiL1 site arrested replication forks in vivo in both orientations and independent of stringent control. In vitro, the sequence arrested DnaB helicase in both orientations, albeit more weakly than the normal Ter1 terminus. The key points of mechanistic interest that emerge from the present work are: (i) strong binding of a Ter (psiL1) sequence to RTP did not appear to be essential for fork arrest and (ii) polarity of fork arrest could not be correlated in this case with just symmetrical protein-DNA interaction at the core and auxiliary sites of psiL1. On the basis of the result it would appear that the weak RTP-L1Ter interaction cannot by itself account for fork arrest, thus suggesting a role for DnaB-RTP interaction.

Movement of replicating DNA through a stationary replisome

We found that DNA is replicated at a central stationary polymerase, and each replicated region moves away from the replisome. In Bacillus subtilis, DNA polymerase is predominantly located at or near midcell. When replication was blocked in a specific chromosomal region, that region was centrally located with DNA polymerase. Upon release of the block, each copy of the duplicated region was located toward opposite cell poles, away from the central replisome. In a roughly synchronous population of cells, a region of chromosome between origin and terminus moved to the replisome prior to duplication. Thus, the polymerase at the replication forks is stationary, and the template is pulled in and released outward during duplication. We propose that B. subtilis, and probably many bacteria, harness energy released during nucleotide condensation by a stationary replisome to facilitate chromosome partitioning.

Mechanisms and consequences of replication fork arrest

Chromosome replication is not a uniform and continuous process. Replication forks can be slowed down or arrested by DNA secondary structures, specific protein-DNA complexes, specific DNA-RNA hybrids, or interactions between the replication and transcription machineries. Replication arrest has important implications for the topology of replication intermediates and can trigger homologous and illegitimate recombination. Thus, replication arrest may be a key factor in genome instability. Several examples of these phenomena are reviewed here.

Evolution of the linear chromosomal DNA in Streptomyces: is genomic variability developmentally modulated?

Genome rearrangements are responsible for the variability observed at the ends of the chromosome among Streptomyces species. The characterization of mutators, which are stimulated for genome plasticity, and of mutants produced at different stages of development support the idea that genome instability is developmentally modulated.

Developmental regulation of replication fork pausing in Xenopus laevis ribosomal RNA genes

In early Xenopus embryos, replication forks move along the rRNA genes (rDNA) at a uniform rate and terminate at multiple, apparently random sites. In contrast, a polar replication fork barrier (RFB) is found at the 3' end of the rRNA genes in Xenopus cultured cells. We have now analysed the replication intermediates of Xenopus rDNA from a wide range of developmental stages by 2D gel electrophoresis. Surprisingly, up to 15 different replication fork pausing sites (RFPs) simultaneously appear in the rDNA at the midgastrula stage, when rRNA transcription abruptly increases. They disappear during the neurula stage, except for a polar RFP at the 3' end of Xthe transcription unit, which persists to the tadpole stage. The latter RFP is found at the same location as the RFB in cultured cells; however the arrest of replication forks at this RFP is not absolute, since termination occurs at multiple positions throughout the rDNA repeat. The efficiency of fork arrest at this RFP remains constant from midgastrula to early tadpole, and decreases around hatching. The transient appearance of multiple RFPs at midgastrula may reflect some chromatin remodeling associated with developmental activation of rRNA transcription.

Termination of DNA replication of bacterial and plasmid chromosomes

Sequence-specific replication termini occur in many bacterial and plasmid chromosomes and consist of two components: a cis-acting ter site and a trans-acting replication terminator protein. The interaction of a terminator protein with the ter site creates a protein-DNA complex that arrests replication forks in a polar fashion by antagonizing the action of the replicative helicase (thereby exhibiting a contrahelicase activity). Terminator proteins also arrest RNA polymerases in a polar fashion. Passage of an RNA transcript through a terminus from the non-blocking direction abrogates replication termination function, a mechanism that is likely to be used in conditional termini or replication check points.

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.

Replication of plasmids during bacterial response to amino acid starvation

Amino acid starvation of bacterial cells leads to expression of the stringent (in wild-type strains) or relaxed (in relA mutants) response (also called the stringent or relaxed control, respectively). The stringent control is a pleiotropic response which changes drastically almost the entire cell physiology. Although starvation is a rule rather than an exception in natural environments of bacteria, and DNA replication is a fundamental cell process, until recently our knowledge about regulation of DNA replication in amino acid-starved cells has been unexpectedly poor. Within recent years the stringent control of DNA replication has been investigated mainly on plasmid models. Several plasmid replicons have been studied, including oriC plasmids, ColE1-like replicons, pSC101, F, R1, RK2, and R6K, and plasmids derived from bacteriophages lambda and P1. However, molecular models of replication regulation in amino acid-starved cells have been proposed to date only for lambda plasmids and ColE1-like replicons. Although further extensive studies are necessary in the understanding of molecular mechanisms of the stringent and relaxed control of replication of other plasmids, the results obtained to date (summarized and discussed in this review) show that studies on DNA replication in amino acid-starved cells may provide new insights into the regulatory mechanisms and lead to more general conclusions.

DNA polymerase template switching at specific sites on the phi29 genome causes the in vivo accumulation of subgenomic phi29 DNA molecules

The accumulation of subgenomic phage phi29 DNA molecules with specific sizes was observed after prolonged infection times with delayed lysis phage mutants. Whereas the majority of the molecules had a size of 4 kb, additional DNA species were observed with sizes of 8.2, 6.5, 2.3, 2 and 1 kb. Most of the molecules were shown to originate from the right end of the linear Bacillus subtilis phage phi29 genome. The nature of the 4, 2.3, 2 and 1 kb molecules was studied. The 2 kb molecules were shown to be single-stranded self-complementary strands forming hairpin structures. The other molecules consisted of palindromic linear double-stranded DNA molecules. Most probably, the subgenomic DNA molecules were formed when the moving phage replication fork from the right origin encountered a block that induces the DNA polymerase to switch template. Once formed, the subgenomic molecules are then amplified in vivo. Determination of the centres of symmetry of the 4 and 1 kb molecules revealed that both contained the almost 16 bp perfect dyad symmetry element (DSE): 5'-TGTTtCAC-GTGg-AACA-3' being a likely candidate for a protein binding site. Database analysis showed that this sequence occurs four times in the phi29 genome. In addition, the almost identical sequence 5'-TgGTTTCAC-GTGGAAtCA-3' was found once. These five DSEs are all located in the right half of the phi29 genome, and the same sequences are also present in the linear DNA of related B. subtilis phages. Most interestingly, this sequence is also found in the spoOJ gene of the B. subtilis chromosome. Recently, it has been shown that the SpoOJ protein is associated in vivo with the same DSE. As the same subgenomic phi29 DNA molecules accumulate after infection of B. subtilis spoOJ deletion strains, it is likely that, in addition to and/or independently of SpoOJ, other protein(s) bind to DSE.

A fixed distance for separation of newly replicated copies of oriC in Bacillus subtilis: implications for co-ordination of chromosome segregation and cell division

The Spo0J protein of Bacillus subtilis is required for normal chromosome segregation and forms discrete subcellular assemblies closely associated with the oriC region of the chromosome. Here we show that duplication of Spo0J foci occurs early in the DNA replication cycle and that this requires the initiation of DNA replication at oriC but not elongation beyond the nearby STer sites. Soon after duplication, sister oriC/Spo0J foci move rapidly apart to achieve a fixed separation of about 0.7 microm, reminiscent of the segregation of eukaryotic chromosomes on the mitotic spindle. The magnitude of the fixed separation distance may explain how chromosome segregation is kept in close register with cell growth and the initiation mass for DNA replication. It could also explain how segregation can proceed accurately in the absence of cell division. The kinetics of focal separation suggest that one role of Spo0J protein may be to facilitate formation of separate sister oriC complexes that can be segregated.

Mechanistic studies on the impact of transcription on sequence-specific termination of DNA replication and vice versa

Since DNA replication and transcription often temporally and spatially overlap each other, the impact of one process on the other is of considerable interest. We have reported previously that transcription is impeded at the replication termini of Escherichia coli and Bacillus subtilis in a polar mode and that, when transcription is allowed to invade a replication terminus from the permissive direction, arrest of replication fork at the terminus is abrogated. In the present report, we have addressed four significant questions pertaining to the mechanism of transcription impedance by the replication terminator proteins. Is transcription arrested at the replication terminus or does RNA polymerase dissociate from the DNA causing authentic transcription termination? How does transcription cause abrogation of replication fork arrest at the terminus? Are the points of arrest of the replication fork and transcription the same or are these different? Are eukaryotic RNA polymerases also arrested at prokaryotic replication termini? Our results show that replication terminator proteins of E. coli and B. subtilis arrest but do not terminate transcription. Passage of an RNA transcript through the replication terminus causes the dissociation of the terminator protein from the terminus DNA, thus causing abrogation of replication fork arrest. DNA and RNA chain elongation are arrested at different locations on the terminator sites. Finally, although bacterial replication terminator proteins blocked yeast RNA polymerases in a polar fashion, a yeast transcription terminator protein (Reb1p) was unable to block T7 RNA polymerase and E. coli DnaB helicase.

Cell membrane and chromosome replication in Bacillus subtilis

This review covers studies of the structural and functional roles of the cell membrane on the replication of the Bacillus subtillis chromosome. A particular emphasis is placed on the essential roles of the membrane complex for the in vivo initiation and termination of the chromosome replication. A critical gene complex in B. subtillis for the role of membrane complex is the dnaB operon that most likely consists of four genes (dnaB, dnaI, ORFZ/ORF213, and ORF omega/ORF281). Detailed studies of these genes are currently available only for the dnaB and dnaI genes. The unique feature of the dnaB gene is that temperature-sensitive mutants of this gene simultaneously lose, at the nonpermissive temperature, chromosome attachment at oriC to the membrane as well as the new round of replication initiation at oriC. Further studies on the genes and their products of the dnaB operon are therefore essential for our understanding of the in vivo mechanism of the initiation of chromosome replication and its regulation. The role of the membrane on the termination and segregation of the daughter chromosomes has not been discovered, but an important clue comes from the terminus area of the B. subtillis chromosome being bound to the membrane in a high-salt resistant and DnaB-independent fashion.

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.

Developmental regulation of DNA replication: replication fork barriers and programmed gene amplification in Tetrahymena thermophila

The palindromic Tetrahymena ribosomal DNA (rDNA) minichromosome is amplified 10,000-fold during development. Subsequent vegetative replication is cell cycle regulated. rDNA replication differs fundamentally in cycling vegetative and nondividing amplifying cells. Using two-dimensional gel electrophoresis, we show for the first time that replication origins that direct gene amplification also function in normal dividing cells. Two classes of amplification intermediates were identified. The first class is indistinguishable from vegetative rDNA, initiating in just one of the two 5' nontranscribed spacer (NTS) copies in the rDNA palindrome at either of two closely spaced origins. Thus, these origins are active throughout the life cycle and their regulation changes at different developmental stages. The second, novel class of amplification intermediates is generated by multiple initiation events. Intermediates with mass greater than fully replicated DNA were observed, suggesting that onionskin replication occurs at this stage. Unlike amplified rDNA in Xenopus laevis, the novel Tetrahymena species are not produced by random initiation; replication also initiates in the 5' NTS. Surprisingly, a replication fork barrier which is activated only in these amplifying molecules blocks the progression of forks near the center of the palindrome. Whereas barriers have been previously described, this is the first instance in which programmed regulation of replication fork progression has been demonstrated in a eukaryote.

Replication fork arrest and termination of chromosome replication in Bacillus subtilis

Sporulation in Bacillus subtilis provided the first evidence for the presence of sequence-specific replication fork arrest (Ter) sites in the terminus region of the bacterial chromosome. These sites, when complexed with the replication terminator protein (RTP), block movement of a replication fork in a polar manner. The Ter sites are organized into two opposed groups which force the approaching forks to meet and fuse within a restricted terminus region. While the precise advantage provided to the cell through the presence of the so-called replication fork trap is not patently obvious, the same situation appears to have evolved independently in Escherichia coli. The molecular mechanism by which the RTP-Ter complex of B. subtilis (or the analogous but apparently unrelated complex in E. coli) functions is currently unresolved and subject to intense investigation. Replication fork arrest in B. subtilis, requiring RTP, also occurs under conditions of the stringent response at so-called STer sites that lie close to and on both sides of oriC. These sites are yet to be identified and characterized. How they are induced to function under stringent conditions is of considerable interest, and could provide vital clues about the mechanism of fork arrest by RTP-terminator complexes in general.

Search for additional replication terminators in the Bacillus subtilis 168 chromosome

The Bacillus subtilis 168 chromosome is known to contain at least six DNA replication terminators in the terminus region of the chromosome. By using a degenerate DNA probe for the consensus terminator sequence and low-stringency hybridization conditions, several additional minor hybridizing bands were identified. DNA corresponding to the most intense of these bands was cloned and characterized. Although localized in the terminus region, it could not bind RTP and possibly represents a degenerate terminator. A search of the SubtiList database identified an additional terminator sequence in the terminus region, near glnA. It was shown to bind RTP and to function in blocking replication fork movement in a polar manner. Its orientation conformed to the replication fork trap arrangement of the other terminators. The low-stringency hybridization experiments failed to identify any terminus region-type terminators in the region of the chromosome where postinitiation control sequences (STer sites) are known to reside. The two most likely terminators in STer site regions, in terms of sequence similarity to terminus region terminators, were identified through sequence searching. They were synthesized and were found not to bind RTP under conditions that allowed binding to terminus region terminators. Neither did they elicit fork arrest, when present in a plasmid, under stringent conditions. It is concluded that the STer site terminators, at least the first two to the left of oriC, do not have the typical consensus A+B site makeup of terminus region terminators.

Replication fork arrest at relocated replication terminators on the Bacillus subtilis chromosome

The replication terminus region of the Bacillus subtilis chromosome, comprising TerI and TerII plus the rtp gene (referred to as the terC region) was relocated to serC (257 degrees) and cym (10 degrees) on the anticlockwise- and clockwise-replicating segments of the chromosome, respectively. In both cases, it was found that only the orientation of the terC region that placed TerI in opposition to the approaching replication fork was functional in fork arrest. When TerII was opposed to the approaching fork, it was nonfunctional. These findings confirm and extend earlier work which involved relocations to only the clockwise-replicating segment, at metD (100 degrees) and pyr (139 degrees). In the present work, it was further shown that in the strain in which TerII was opposed to an approaching fork at metD, overproduction of the replication terminator protein (RTP) enabled TerII to function as an arrest site. Thus, chromosomal TerII is nonfunctional in arrest in vivo because of a limiting level of RTP. Marker frequency analysis showed that TerI at both cym and metD caused only transient arrest of a replication fork. Arrest appeared to be more severe in the latter situation and caused the two forks to meet at approximately 145 degrees (just outside or on the edge of the replication fork trap). The minimum pause time erected by TerI at metD was calculated to be approximately 40% of the time taken to complete a round of replication. This significant pause at metD caused the cells to become elongated, indicating that cell division was delayed. Further work is needed to establish the immediate cause of the delay in division.

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.