Replication arrest

A comparative genomic analysis of the alkalitolerant soil bacterium Bacillus lehensis G1

Bacillus lehensis G1 is a Gram-positive, moderately alkalitolerant bacterium isolated from soil samples. B. lehensis produces cyclodextrin glucanotransferase (CGTase), an enzyme that has enabled the extensive use of cyclodextrin in foodstuffs, chemicals, and pharmaceuticals. The genome sequence of B. lehensis G1 consists of a single circular 3.99 Mb chromosome containing 4017 protein-coding sequences (CDSs), of which 2818 (70.15%) have assigned biological roles, 936 (23.30%) have conserved domains with unknown functions, and 263 (6.55%) have no match with any protein database. Bacillus clausii KSM-K16 was established as the closest relative to B. lehensis G1 based on gene content similarity and 16S rRNA phylogenetic analysis. A total of 2820 proteins from B. lehensis G1 were found to have orthologues in B. clausii, including sodium-proton antiporters, transport proteins, and proteins involved in ATP synthesis. A comparative analysis of these proteins and those in B. clausii and other alkaliphilic Bacillus species was carried out to investigate their contributions towards the alkalitolerance of the microorganism. The similarities and differences in alkalitolerance-related genes among alkalitolerant/alkaliphilic Bacillus species highlight the complex mechanism of pH homeostasis. The B. lehensis G1 genome was also mined for proteins and enzymes with potential viability for industrial and commercial purposes.

Random and site-specific replication termination

Bi-directionality is a common feature observed for genomic replication for all three phylogenetic kingdoms: Eubacteria, Archaea, and Eukaryotes. A consequence of bi-directional replication, where the two replication forks initiated at an origin move away from each other, is that the replication termination will occur at positions away from the origin sequence(s). The replication termination processes are therefore physically and mechanistically dissociated from the replication initiation. The replication machinery is a highly processive complex that in short time copies huge numbers of bases while competing for the DNA substrate with histones, transcription factors, and other DNA-binding proteins. Importantly, the replication machinery generally wins out; meanwhile, when converging forks meet termination occurs, thus preventing over-replication and genetic instability. Very different scenarios for the replication termination processes have been described for the three phylogenetic kingdoms. In eubacterial genomes replication termination is site specific, while in archaea and eukaryotes termination is thought to occur randomly within zones where converging replication forks meet. However, a few site-specific replication barrier elements that mediate replication termination have been described in eukaryotes. This review gives an overview about what is known about replication termination, with a focus on these natural site-specific replication termination sites.

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.

Origin of replication in circular prokaryotic chromosomes

To predict origins of replication in prokaryotic chromosomes, we analyse the leading and lagging strands of 200 chromosomes for differences in oligomer composition and show that these correlate strongly with taxonomic grouping, lifestyle and molecular details of the replication process. While all bacteria have a preference for Gs over Cs on the leading strand, we discover that the direction of the A/T skew is determined by the polymerase-alpha subunit that replicates the leading strand. The strength of the strand bias varies greatly between both phyla and environments and appears to correlate with growth rate. Finally we observe much greater diversity of skew among archaea than among bacteria. We have developed a program that accurately locates the origins of replication by measuring the differences between leading and lagging strand of all oligonucleotides up to 8 bp in length. The program and results for all publicly available genomes are available from http://www.cbs.dtu.dk/services/GenomeAtlas/suppl/origin.

Replication termination in Escherichia coli: structure and antihelicase activity of the Tus-Ter complex

The arrest of DNA replication in Escherichia coli is triggered by the encounter of a replisome with a Tus protein-Ter DNA complex. A replication fork can pass through a Tus-Ter complex when traveling in one direction but not the other, and the chromosomal Ter sites are oriented so replication forks can enter, but not exit, the terminus region. The Tus-Ter complex acts by blocking the action of the replicative DnaB helicase, but details of the mechanism are uncertain. One proposed mechanism involves a specific interaction between Tus-Ter and the helicase that prevents further DNA unwinding, while another is that the Tus-Ter complex itself is sufficient to block the helicase in a polar manner, without the need for specific protein-protein interactions. This review integrates three decades of experimental information on the action of the Tus-Ter complex with information available from the Tus-TerA crystal structure. We conclude that while it is possible to explain polar fork arrest by a mechanism involving only the Tus-Ter interaction, there are also strong indications of a role for specific Tus-DnaB interactions. The evidence suggests, therefore, that the termination system is more subtle and complex than may have been assumed. We describe some further experiments and insights that may assist in unraveling the details of this fascinating process.

Wavelet to predict bacterial ori and ter: a tendency towards a physical balance

BACKGROUND

Chromosomal DNA replication in bacteria starts at the origin (ori) and the two replicores propagate in opposite directions up to the terminus (ter) region. We hypothesize that the two replicores need to reach ter at the same time to maintain a physical balance; DNA insertion would disrupt such a balance, requiring chromosomal rearrangements to restore the balance. To test this hypothesis, we needed to demonstrate that ori and ter are in a physical balance in bacterial chromosomes. Using wavelet analysis, we documented GC skew, AT skew, purine excess and keto excess on the published bacterial genomic sequences to locate the turning (minimum and maximum) points on the curves. Previously, the minimum point had been supposed to correlate with ori and the maximum to correlate with ter.

RESULTS

We observed a strong tendency of the bacterial chromosomes towards a physical balance, with the minima and maxima corresponding to the known or putative ori and ter and being about half chromosome separated in most of the bacteria studied. A nonparametric method based on wavelet transformation was employed to perform significance tests for the predicted loci.

CONCLUSIONS

The wavelet approach can reliably predict the ori and ter regions and the bacterial chromosomes have a strong tendency towards a physical balance between ori and ter.

Complete nucleotide sequence of plasmid Rts1: implications for evolution of large plasmid genomes

Rts1, a large conjugative plasmid originally isolated from Proteus vulgaris, is a prototype for the IncT plasmids and exhibits pleiotropic thermosensitive phenotypes. Here we report the complete nucleotide sequence of Rts1. The genome is 217,182 bp in length and contains 300 potential open reading frames (ORFs). Among these, the products of 141 ORFs, including 9 previously identified genes, displayed significant sequence similarity to known proteins. The set of genes responsible for the conjugation function of Rts1 has been identified. A broad array of genes related to diverse processes of DNA metabolism were also identified. Of particular interest was the presence of tus-like genes that could be involved in replication termination. Inspection of the overall genome organization revealed that the Rts1 genome is composed of four large modules, providing an example of modular evolution of plasmid genomes.

Effects of replication termination mutants on chromosome partitioning in Bacillus subtilis

Many circular genomes have replication termination systems, yet disruption of these systems does not cause an obvious defect in growth or viability. We have found that the replication termination system of Bacillus subtilis contributes to accurate chromosome partitioning. Partitioning of the terminus region requires that chromosome dimers, that have formed as a result of RecA-mediated homologous recombination, be resolved to monomers by the site-specific recombinase encoded by ripX. In addition, the chromosome must be cleared from the region of formation of the division septum. This process is facilitated by the spoIIIE gene product which is required for movement of a chromosome out of the way of the division septum during sporulation. We found that deletion of rtp, which encodes the replication termination protein, in combination with mutations in ripX or spoIIIE, led to an increase in production of anucleate cells. This increase in production of anucleate cells depended on recA, indicating that there is probably an increase in chromosome dimer formation in the absence of the replication termination system. Our results also indicate that SpoIIIE probably enhances the function of the RipX recombinase system. We also determined the subcellular location of the replication termination protein and found that it is a good marker for the position of the chromosome terminus.

Effects of replication termination mutants on chromosome partitioning in Bacillus subtilis

Many circular genomes have replication termination systems, yet disruption of these systems does not cause an obvious defect in growth or viability. We have found that the replication termination system of Bacillus subtilis contributes to accurate chromosome partitioning. Partitioning of the terminus region requires that chromosome dimers, that have formed as a result of RecA-mediated homologous recombination, be resolved to monomers by the site-specific recombinase encoded by ripX . In addition, the chromosome must be cleared from the region of formation of the division septum. This process is facilitated by the spoIIIE gene product which is required for movement of a chromosome out of the way of the division septum during sporulation. We found that deletion of rtp , which encodes the replication termination protein, in combination with mutations in ripX or spoIIIE , led to an increase in production of anucleate cells. This increase in production of anucleate cells depended on recA , indicating that there is probably an increase in chromosome dimer formation in the absence of the replication termination system. Our results also indicate that SpoIIIE probably enhances the function of the RipX recombinase system. We also determined the subcellular location of the replication termination protein and found that it is a good marker for the position of the chromosome terminus.

Premature termination of DNA replication in plasmids carrying two inversely oriented ColE1 origins

In Escherichia coli plasmids carrying two inversely oriented ColE1 origins, DNA replication initiates at only one of the two potential origins. The other silent origin acts as a replication fork barrier. Whether this barrier is permanent or simply a pausing site remains unknown. Here, we used a repeated primer extension assay to map in vivo, at the nucleotide level, the 5' end of the nascent strand where initiation and blockage of replication forks occurs. Initiation occurred primarily at the previously defined origin, however, an alternative initiation site was detected 17 bp upstream. At the barrier, the lagging strand also terminated at the main initiation site. Therefore, the 5' end of the nascent strand at the barrier was identical to that generated during initiation. This observation strongly suggests that blockage of the replication fork at the silent origin is not just a pausing site but permanent, and leads to a premature termination event.

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.

Characterization of the effects of Escherichia coli replication terminator protein (Tus) on transcription reveals dynamic nature of the tus block to transcription complex progression

We have characterized the blocks to progression of T7 and T3 RNA polymerase transcription complexes created when a Tus protein is bound to the template. The encounter with Tus impedes the progress of the transcription complexes of either enzyme. The duration of the block depends on which polymerase is used and the orientation of Tus on the DNA. Both genuine termination (dissociation of the transcription complex) and halting followed by continued progression after the block is abrogated are observed. The fraction of complexes that terminates depends on which polymerase is used and on the orientation of the Tus molecule. The efficiency of the block to transcription increases as the Tus concentration is increased, even if the concentration of Tus is already many times in excess of what is required to saturate its binding sites on the template in the absence of transcription. The block to transcription is rapidly abrogated if an excess of a DNA containing a binding site for Tus is added to a transcription reaction in which Tus and template have been preincubated. Finally, we find that transcription will rapidly displace Tus from a template under conditions that generate persistent blocks to transcription. These observations reveal that during the encounter with the transcription complex Tus rapidly dissociates from the template but that at sufficiently high concentrations Tus usually rebinds before the transcription complex can move forward. The advantage of a mechanism which can create a persistent block to transcription or replication complex progression, which can nevertheless be rapidly abrogated in response to down regulation of the blocking protein, is suggested.

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.

Skewed oligomers and origins of replication

The putative origin of replication in prokaryotic genomes can be located by a new method that finds short oligomers whose orientation is preferentially skewed around the origin. The skewed oligomer method is shown to work for all bacterial genomes and one of three archaeal genomes sequences to date, confirming known or predicted origins in most cases and in three cases (H. pylori, M. thermoautotrophicum, and Synechocystis sp.), suggesting origins that were previously unknown. In many cases, the presence of conserved genes and nucleotide motifs confirms the predictions. An algorithm for finding these skewed seven-base and eight-base sequences is described, along with a method for combining evidence from multiple skewed oligomers to accurately locate the replication origin. Possible explanations for the phenomenon of skewed oligomers are discussed. Explanations are presented for why some bacterial genomes contain hundreds of highly skewed oligomers, whereas others contain only a handful.

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.

Replication and control of circular bacterial plasmids

An essential feature of bacterial plasmids is their ability to replicate as autonomous genetic elements in a controlled way within the host. Therefore, they can be used to explore the mechanisms involved in DNA replication and to analyze the different strategies that couple DNA replication to other critical events in the cell cycle. In this review, we focus on replication and its control in circular plasmids. Plasmid replication can be conveniently divided into three stages: initiation, elongation, and termination. The inability of DNA polymerases to initiate de novo replication makes necessary the independent generation of a primer. This is solved, in circular plasmids, by two main strategies: (i) opening of the strands followed by RNA priming (theta and strand displacement replication) or (ii) cleavage of one of the DNA strands to generate a 3'-OH end (rolling-circle replication). Initiation is catalyzed most frequently by one or a few plasmid-encoded initiation proteins that recognize plasmid-specific DNA sequences and determine the point from which replication starts (the origin of replication). In some cases, these proteins also participate directly in the generation of the primer. These initiators can also play the role of pilot proteins that guide the assembly of the host replisome at the plasmid origin. Elongation of plasmid replication is carried out basically by DNA polymerase III holoenzyme (and, in some cases, by DNA polymerase I at an early stage), with the participation of other host proteins that form the replisome. Termination of replication has specific requirements and implications for reinitiation, studies of which have started. The initiation stage plays an additional role: it is the stage at which mechanisms controlling replication operate. The objective of this control is to maintain a fixed concentration of plasmid molecules in a growing bacterial population (duplication of the plasmid pool paced with duplication of the bacterial population). The molecules involved directly in this control can be (i) RNA (antisense RNA), (ii) DNA sequences (iterons), or (iii) antisense RNA and proteins acting in concert. The control elements maintain an average frequency of one plasmid replication per plasmid copy per cell cycle and can "sense" and correct deviations from this average. Most of the current knowledge on plasmid replication and its control is based on the results of analyses performed with pure cultures under steady-state growth conditions. This knowledge sets important parameters needed to understand the maintenance of these genetic elements in mixed populations and under environmental conditions.

Structural analysis of the 6 kb cryptic plasmid pFAJ2600 from Rhodococcus erythropolis NI86/21 and construction of Escherichia coli-Rhodococcus shuttle vectors

The complete nucleotide sequence of the 5936 bp cryptic plasmid pFAJ2600 from Rhodococcus erythropolis NI86/21 was determined. Based on the characteristics of its putative replication genes, repA and repB, pFAJ2600 was assigned to the family of pAL5000-related small replicons identified in Mycobacterium (pAL5000), Corynebacterium (pXZ10142), Brevibacterium (pRBL1), Bifidobacterium (pMB1) and Neisseria (pJD1). The replication systems of these plasmids show striking similarities to the ones used by the ColE2 family of plasmids from Enterobacteria with respect to both trans-acting factors and ori sequences. Two possible plasmid stabilization systems are encoded on pFAJ2600: a site-specific recombinase (PmrA) related to the Escherichia coli Xer proteins for plasmid multimer resolution and an ATPase (ParA) related to the A-type of proteins in sop/par partitioning systems. The proposed replication termination region of pFAJ2600 has features in common with the Ter loci of Bacillus subtilis. Chimeras composed of a pUC18-Cmr derivative inserted in the parA-repA intergenic region of vector pFAJ2600 produced vectors that could be shuttled between Escherichia coli and several Rhodococcus species (R. erythropolis, R. fascians, R. rhodochrous, R. ruber). The pFAJ2600-based shuttle vector pFAJ2574 was stably maintained in R. erythropolis and R. fascians growing under non-selective conditions.

Termination of mammalian rDNA replication: polar arrest of replication fork movement by transcription termination factor TTF-I

A replication fork barrier (RFB) at the 3' end of eukaryotic ribosomal RNA genes blocks bidirectional fork progression and limits DNA replication to the same direction as transcription. We have reproduced the RFB in vitro in HeLa cell extracts using 3' terminal murine rDNA fused to an SV40 origin-based vector. The RFB is polar and modularly organized, requiring both the Sal box transcription terminator and specific flanking sequences. Mutations within the terminator element, depletion of the RNA polymerase I-specific transcription termination factor TTF-I, or deletion of the termination domain of TTF-I abolishes RFB activity. Thus, the same factor that blocks elongating RNA polymerase I prevents head-on collision between the DNA replication apparatus and the transcription machinery.

Reorganization of terminator DNA upon binding replication terminator protein: implications for the functional replication fork arrest complex

Termination of DNA replication in Bacillus subtilis involves the polar arrest of replication forks by a specific complex formed between the replication terminator protein (RTP) and DNA terminator sites. While determination of the crystal structure of RTP has facilitated our understanding of how a single RTP dimer interacts with terminator DNA, additional information is required in order to understand the assembly of a functional fork arrest complex, which requires an interaction between two RTP dimers and the terminator site. In this study, we show that the conformation of the major B.subtilis DNA terminator,TerI, becomes considerably distorted upon binding RTP. Binding of the first dimer of RTP to the B site of TerI causes the DNA to become slightly unwound and bent by approximately 40 degrees. Binding of a second dimer of RTP to the A site causes the bend angle to increase to approximately 60 degrees . We have used this new data to construct two plausible models that might explain how the ternary terminator complex can block DNA replication in a polar manner. In the first model, polarity of action is a consequence of the two RTP-DNA half-sites having different conformations. These different conformations result from different RTP-DNA contacts at each half-site (due to the intrinsic asymmetry of the terminator DNA), as well as interactions (direct or indirect) between the RTP dimers on the DNA. In the second model, polar fork arrest activity is a consequence of the different affinities of RTP for the A and B sites of the terminator DNA, modulated significantly by direct or indirect interactions between the RTP dimers.

Structure of a replication-terminator protein complexed with DNA

The crystal structure of the Escherichia coli replication-terminator protein (Tus) bound to terminus-site (Ter) DNA has been determined at 2.7 A resolution. The Tus protein folds into a previously undescribed architecture divided into two domains by a central basic cleft. This cleft accommodates locally deformed B-form Ter DNA and makes extensive contacts with the major groove, mainly through two interdomain beta-strands. The unusual structural features of this complex may explain how the replication fork is halted in only one direction.

The ColE1 unidirectional origin acts as a polar replication fork pausing site

Co-orientation of replication origins is the most common organization found in nature for multimeric plasmids. Streptococcus pyogenes broad-host-range plasmid pSM19035 and Escherichia coli pPI21 are among the exceptions. pPI21, which is a derivative of pSM19035 and pBR322, has two long inverted repeats, each one containing a potentially active ColE1 unidirectional origin. Analysis of pPI21 replication intermediates (RIs) by two-dimensional agarose gel electrophoresis and electron microscopy revealed the accumulation of a specific RI containing a single internal bubble. The data obtained demonstrated that initiation of DNA replication occurred at a single origin in pPI21. Progression of the replicating fork initiated at either of the two potential origins was transiently stalled at the other inversely oriented silent ColE1 origin of the plasmid. The accumulated RIs, containing an internal bubble, occurred as a series of stereoisomers with different numbers of knots in their replicated portion. These observations provide one of the first functional explanations for the disadvantage of head-to-head plasmid multimers with respect to head-to-tail ones.

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.

Identification and characterization of a novel type of replication terminator with bidirectional activity on the Bacillus subtilis theta plasmid pLS20

We have sequenced and analysed a 3.1 kb fragment of the 55 kb endogenous Bacillus subtilis plasmid pLS20 containing its replication functions. Just outside the region required for autonomous replication, a segment of 18 bp was identified as being almost identical to part of the major B. subtilis chromosomal replication terminator. Here, we demonstrate that this segment is part of a functional replication terminator. This newly identified element, designated TerLS20, is the first replication terminator identified on a theta plasmid from a Gram-positive bacterium. TerLS20 is distinct from other known replication terminators in the sense that it is functional in both orientations. The region required for bipolar functionality of TerLS20 was delineated to a sequence of 29 bp, which is characterized by an imperfect dyad symmetry.

Mutations in the Escherichia coli Tus protein define a domain positioned close to the DNA in the Tus-Ter complex

A new genetic screen for mutations in the tus gene of Escherichia coli has been devised that selects for Tus proteins with altered ability to arrest DNA replication. We report here the characterization of three such mutants: TusP42S, TusE49K, and TusH50Y. TusP42S and TusE49K arrest DNA replication in vivo at 36% of the efficiency of wild-type Tus, whereas TusH50Y functions at 78% efficiency. The loss of replication arrest activity did not correlate with changes in the stability of the Tus-TerB complexes formed by the mutant proteins. TusE49K formed a more stable protein-DNA complex than wild-type Tus (t1/2 of 178 versus 149 min, respectively) and TusP42 had a 9-min half-life, yet these two mutants showed identical efficiencies for replication arrest. When tested in vitro using a helicase assay or an oriC replication system, we observed a general, but imperfect, correlation between the in vivo and in vitro assays. Finally, the half-lives of the mutant protein-DNA complexes suggested that the domain of Tus where these mutations are located is positioned close to the DNA in the Tus-Ter complex.

The contrahelicase activities of the replication terminator proteins of Escherichia coli and Bacillus subtilis are helicase-specific and impede both helicase translocation and authentic DNA unwinding

Replication forks are arrested at sequence-specific replication termini primarily, perhaps exclusively, by polar arrest of helicase-catalyzed DNA unwinding by the terminator protein. The mechanism of this arrest is of considerable interest. This paper presents experimental evidence in support of four major points pertaining to termination of DNA replication. First, the replication terminator proteins of both Escherichia coli and Bacillus subtilis are helicase-specific contrahelicases, i.e. the proteins specifically impede the activities of helicases that are involved in symmetric DNA replication but not of those involved in conjugative DNA transfer and rolling circle replication. Second, the terminator protein (Ter) of E. coli blocks not only helicase translocation but also authentic DNA unwinding. Third, the replication terminator protein of Gram-positive B. subtilis is a polar contrahelicase of the primosomal helicase PriA of Gram-negative E. coli. Finally, the blockage of PriA-catalyzed DNA unwinding was abrogated by the passage of an RNA transcript through the replication terminator protein-terminus complex. These results are significant because of their relevance to the mechanistic aspects of replication termination.

Replication through the terminus region of the Bacillus subtilis chromosome is not essential for the formation of a division septum that partitions the DNA

Germinated and outgrowing spores of a temperature-sensitive DNA initiation mutant of Bacillus subtilis were allowed to initiate a single round of replication by being shifted from 34 to 47 degrees C at the appropriate time. The DNA replication inhibitor 6-(parahydroxyphenylazo)-uracil was added to separate portions of the culture at various times during the round. Samples were collected from each around the time of the first division septation for measurements of the extent of the round completed, the level of division septation, the position of the septum within the outgrown cell, and the distribution of DNA (nucleoid) in relation to the septum. The extent of replication was measured directly through a hybridization approach. The results show clearly that a central division septum can close down onto a chromosome that is only partially replicated (to a minimum extent of about 60% of the round) such that DNA appears on both sides of the septum and frequently very close to it. It is concluded, as claimed previously on the basis of a less direct approach (T. McGinness and R.G. Wake, J. Mol. Biol. 134:251-264, 1979), that replication through the terminus region of the chromosome is not essential for the formation of a division septum that partitions the DNA.