Normal terC-region of the Bacillus subtilis chromosome acts in a polar manner to arrest the clockwise replication fork

Mechanism and physiological significance of programmed replication termination

Replication forks in both prokaryotic and eukaryotic systems pause at random sites due to depletion of dNTP pools, DNA damage, tight binding nonhistone proteins or unusual DNA sequences and/or structures, in a mostly non-polar fashion. However, there is also physiologically programmed replication termination at sequence-specific authentic replication termini. Here, the structure and functions of programmed replication termini, their mechanism of action and their diverse physiological functions in prokaryotes and eukaryotes have been reviewed.

Coupling of σG activation to completion of engulfment during sporulation of Bacillus subtilis survives large perturbations to DNA translocation and replication

Spore formation in Bacillus subtilis is characterized by activation of RNA polymerase sigma factors, including the late-expressed σ(G). During spore formation an asymmetric division occurs, yielding the smaller prespore and the larger mother cell. At division, only 30% of the chromosome is in the prespore, and the rest is then translocated into the prespore. Following completion of engulfment of the prespore by the mother cell, σ(G) is activated in the prespore. Here we tested the link between engulfment and σ(G) activation by perturbing DNA translocation and replication, which are completed before engulfment. One approach was to have large DNA insertions in the chromosome; the second was to have an impaired DNA translocase; the third was to use a strain in which the site of termination of chromosome replication was relocated. Insertion of 2.3 Mb of Synechocystis DNA into the B. subtilis genome had the largest effect, delaying engulfment by at least 90 min. Chromosome translocation was also delayed and was completed shortly before the completion of engulfment. Despite the delay, σ(G) became active only after the completion of engulfment. All results are consistent with a strong link between completion of engulfment and σ(G) activation. They support a link between completion of chromosome translocation and completion of engulfment.

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.

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.

Functional specificity of the replication fork-arrest complexes of Bacillus subtilis and Escherichia coli: significant specificity for Tus-Ter functioning in E. coli

The Escherichia coli replication terminator TerB was inserted in its two alternate orientations into a Bacillus subtilis fork-arrest assay plasmid. After transferring these new plasmids into B. subtilis, which could overproduce the E. coli terminator protein Tus, it was shown that the E. coli Tus-TerB complex could cause polar replication fork arrest, albeit at a very low level, in B. subtilis. A new B. subtilis-E. coli shuttle plasmid was designed to allow the insertion of either the Terl (B. subtilis) or TerB (E. coli) terminator at the same site and in the active orientation in relation to the approaching replication fork generated in either organism. Fork-arrest assays for both terminator-containing plasmids replicating in both organisms which also produced saturating levels of either the B. subtilis terminator protein (RTP) or Tus were performed. The efficiency of the Tus-TerB complex in causing fork arrest was much higher in E. coli than in B. subtilis. The efficiency of the B. subtilis RTP-Terl complex was higher in B. subtilis than in E. coli, but the effect was significantly less. Evidently a specificity feature in E. coli operates to enhance appreciably the fork-arrest efficiency of a Tus-Ter complex. The specificity effect is of less significance for an RTP-Ter complex functioning in B. subtilis.

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.

Site-directed mutants of RTP of Bacillus subtilis and the mechanism of replication fork arrest

DNA replication fork arrest during the termination phase of chromosome replication in Bacillus subtilis is brought about by the replication terminator protein (RTP) bound to specific DNA terminator sequences (Ter sites) distributed throughout the terminus region. An attractive suggestion by others was that crucial to the functioning of the RTP-Ter complex is a specific interaction between RTP positioned on the DNA and the helicase associated with the approaching replication fork. In support of this was the behaviour of two site-directed mutants of RTP. They appeared to bind Ter DNA normally but were ineffective in fork arrest as ascertained by in vitro Escherichia coli DnaB helicase and replication assays. We describe here a system for assessing the fork-arrest behaviour of RTP mutants in a bona fide in vivo assay in B. subtilis. One of the previously studied mutants, RTP.Y33N, was non-functional in fork arrest in vivo, as predicted. But through extensive analyses, this RTP mutant was shown to be severely defective in binding to Ter DNA, contrary to expectation. Taken in conjunction with recent findings on the other mutant (RTP.E30K), it is concluded that there is as yet no substantive evidence from the behaviour of RTP mutants to support the RTP-helicase interaction model for fork arrest. In an extension of the present work on RTP.Y33N, we determined the dissociation rates of complexes formed by wild-type (wt) RTP and another RTP mutant with various terminator sequences. The functional wtRTP-TerI complex was quite stable (half-life of 182 minutes), reminiscent of the great stability of the E. coli Tus-Ter complex. More significant were the exceptional stabilities of complexes comprising wtRTP and an RTP double-mutant (E39K.R42Q) bound to some particular terminator sequences. From the measurement of in vivo fork-arrest activities of the various complexes, it is concluded that the stability (half-life) of the whole RTP-Ter complex is not the overriding determinant of arrest, and that the RTP-Ter complex must be actively disrupted, or RTP removed, by the action of the approaching replication fork.

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 terminator protein-based replication fork-arrest systems in various Bacillus species

The replication terminator protein (RTP) of Bacillus subtilis interacts with its cognate DNA terminators to cause replication fork arrest, thereby ensuring that the forks approaching one another at the conclusion of a round of replication meet within a restricted terminus region. A similar situation exists in Escherichia coli, but it appears that the fork-arrest systems in these two organisms have evolved independently of one another. In the present work, RTP homologs in four species closely related to B. subtilis (B. atrophaeus, B. amyloliquefaciens, B. mojavensis, and B. vallismortis) have been identified and characterized. An RTP homolog could not be identified in another closely related species, B. licheniformis. The nucleotide and amino acid changes from B. subtilis among the four homologs are consistent with the recently established phylogenetic tree for these species. The GC contents of the rtp genes raise the possibility that these organisms arose within this branch of the tree by horizontal transfer into a common ancestor after their divergence from B. licheniformis. Only 5 amino acid residue positions were changed among the four homologs, despite an up to 17.2% change in the nucleotide sequence, a finding that highlights the importance of the precise folded structure to the functioning of RTP. The absence of any significant change in the proposed DNA-binding region of RTP emphasizes the importance of its high affinity for the DNA terminator in its functioning. By coincidence, the single change (E30K) found in the B. mojavensis RTP corresponds exactly to that purposefully introduced by others into B. subtilis RTP to implicate a crucial role for E30 in the fork-arrest mechanism. The natural occurrence of this variant is difficult to reconcile with such an implication, and it was shown directly that RTP.E30K functions normally in fork arrest in B. subtilis in vivo. Additional DNA terminators were identified in the new RTP homolog-containing strains, allowing the definition of a Bacillus terminator consensus and identification of two more terminators in the B. subtilis 168 genome sequence to bring the total to nine.

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.

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.

Role of the EBNA-1 protein in pausing of replication forks in the Epstein-Barr virus genome

We have previously shown that replication forks stall at a family of repeated sequences (FR) within the Epstein-Barr virus latent origin of replication oriP, both in a small plasmid and in the intact Epstein-Barr virus genome. Each of the 20 repeated sequences within the FR contains a binding site for Epstein-Barr nuclear antigen 1 (EBNA-1), the only viral protein required for latent replication. We showed that the EBNA-1 protein enhances the accumulation of paused replication forks at the FR. In this study, we have investigated a series of truncated EBNA-1 proteins to determine the portion of the EBNA-1 protein that is responsible for pausing of forks at the FR. Two-dimensional agarose gel electrophoresis was performed on the products of in vitro replication reactions in the presence of full-length EBNA-1 or proteins with various deletions to assess the extent of fork pausing at the FR. We conclude that a portion of the DNA binding domain is important for fork pausing. We also present evidence indicating that phosphorylation of the EBNA-1 protein or EBNA-1-truncated derivatives is not essential for pausing. To investigate the mechanism of EBNA-1-mediated pausing of replication forks, we asked whether EBNA-1 could inhibit the DNA unwinding activity of replicative helicases. We found that EBNA-1, when bound to the FR, inhibits DNA unwinding in vitro by SV40 T antigen and Escherichia coli dnaB helicases in an orientation-independent manner.

Helicase-contrahelicase interaction and the mechanism of termination of DNA replication

Termination of DNA replication at a sequence-specific replication terminus is potentiated by the binding of the replication terminator protein (RTP) to the terminus sequence, causing polar arrest of the replicative helicase (contrahelicase activity). Two alternative models have been proposed to explain the mechanism of replication fork arrest. In the first model, the RTP-terminus DNA interaction simply imposes a polar barrier to helicase movement without involving any specific interaction between the helicase and the terminator proteins. The second model proposes that there is a specific interaction between the two proteins, and that the DNA-protein interaction both restricts the fork arrest to the replication terminus and determines the polarity of the process. The evidence presented in this paper strongly supports the second model.

Structure of the replication terminus-terminator protein complex as probed by affinity cleavage

The replication terminator protein (RTP) of Bacillus subtilis is a homodimer that binds to each replication terminus and impedes replication fork movement in only one orientation with respect to the replication origin. The three-dimensional structure of the RTP-DNA complex needs to be determined to understand how structurally symmetrical dimers of RTP generate functional asymmetry. The functional unit of each replication terminus of Bacillus subtilis consists of four turns of DNA complexed with two interacting dimers of RTP. Although the crystal structure of the RTP apoprotein dimer has been determined at 2.6-A resolution, the functional unit of the terminus is probably too large and too flexible to lend itself to cocrystallization. We have therefore used an alternative strategy to delineate the three dimensional structure of the RTP-DNA complex by converting the protein into a site-directed chemical nuclease. From the pattern of base-specific cleavage of the terminus DNA by the chemical nuclease, we have mapped the amino acid to base contacts. Using these contacts as distance constraints, with the crystal structure of RTP, we have constructed a model of the DNA-protein complex. The biological implications of the model have been discussed.

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.

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.

Crystal structure of the replication terminator protein from B. subtilis at 2.6 A

The crystal structure of the replication terminator protein (RTP) of B. subtilis has been determined at 2.6 A resolution. As previously suggested by both biochemical and biophysical studies, the molecule exists as a symmetric dimer and is in the alpha + beta protein-folding class. The protein has several uncommon features, including an antiparallel coiled-coil, which serves as the dimerization domain, and both an alpha-helix and a beta-ribbon suitably positioned to interact with the major and minor grooves of B-DNA. A site has been identified on the surface of RTP that is biochemically and positionally suitable for interaction with the replication-specific helicase. Other features of the structure are consistent with the polar contrahelicase mechanism of the protein. A model of the interaction between RTP and its cognate DNA is presented.

When replication forks stop

DNA synthesis is an accurate and very processive phenomenon, yet chromosome replication does not proceed at a constant rate and progression of the replication fork can be impeded. Several structural and functional features of the template can modulate the rate of progress of the replication fork. These include DNA secondary structures, DNA damage and occupied protein-binding sites. In addition, prokaryotes contain sites where replication is specifically arrested. DNA regions at which the replication machinery is blocked or transiently slowed could be particularly susceptible to genome rearrangements. Illegitimate recombination, a ubiquitous phenomenon which may have dramatic consequences, occurs by a variety of mechanisms. The observation that some rearrangements might be facilitated by a pause in replication could provide a clue in elucidating these processes. In support of this, some homologous and illegitimate recombination events have already been correlated with replication pauses or arrest sites.

Protein-nucleoside contacts in the interaction between the replication terminator protein of Bacillus subtilis and the DNA terminator

The interaction between the DNA replication terminator, IRI, of Bacillus subtilis and its cognate replication terminator protein (RTP) has been examined by the technique of missing nucleoside interference (MNI). IRI contains two adjacent binding sites (A and B) for RTP dimers. The B site is proximal to the replication fork arrest site. The present results have shown that nucleoside contacts with RTP in the two sites are very different. There are more extensive contacts of nucleosides in both strands of the B site with RTP compared with the A site. The data also strongly suggest that filling by RTP of the B site occurs first and is needed for subsequent co-operative filling of an overlapping A site. The A site alone binds RTP poorly. The findings are consistent with interaction occurring between RTP dimers bound to adjacent sites of IRI, which would explain why RTP bound to the B site alone cannot cause replication fork arrest.

Autoregulation of the gene encoding the replication terminator protein of Bacillus subtilis

One of two putative sigma A promoters identified previously in the region immediately upstream from the rtp gene (encoding the replication terminator protein) [Smith and Wake, J. Bacteriol. 170 (1988) 4083-4090] has been shown by transcription start point (tsp) mapping to be the functional rtp promoter. In these tsp mapping experiments, it was observed that the level of mRNA from this promoter, Prtp, was increased by a factor of 30 in the absence of the replication terminator protein (RTP), consistent with the autoregulation of rtp at the level of transcription. In vitro transcription from Prtp by sigma A RNA polymerase has been shown to be specifically repressed by RTP. A Prtp-spoVG-lacZ fusion was inserted into the chromosome of a strain in which RTP production was inducible by IPTG. Addition of IPTG to cultures of the new strain lowered beta Gal production by a factor of at least four. It is concluded that rtp is autoregulated in vivo at the level of transcription.

Stability and asymmetric replication of the Bacillus subtilis 168 chromosome structure

Chromosomal DNAs from a number of strains derived from Bacillus subtilis 168 were digested with restriction endonucleases NotI or SfiI, and the locations of chromosomal alterations were compared with the recently constructed standard NotI-SfiI restriction map (M. Itaya and T. Tanaka, J. Mol. Biol. 220:631-648, 1991). In general, the chromosome structure of B. subtilis 168 was found to be stable, as expected from the genetic stability of this species. DNA alterations, typically deletions, are formed in three limited loci on the chromosome. One of these alterations was characterized as a spontaneous deletion formed between rrn operons, and another occurred as a result of prophage SP beta excision. I found that oriC and terC are not located on precisely opposite sides of the chromosome. Replication in the counter clockwise direction was 196 kb longer than replication in the clockwise direction. The characteristic of length difference is not changed by deletion formation.

Definition and polarity of action of DNA replication terminators in Bacillus subtilis

The first stage in termination of chromosome replication in Bacillus subtilis involves arrest of the clockwise fork at the inverted repeat region (IRR), comprising the opposed IRI and IRII sequences, adjacent to the upstream region of the rtp gene, which encodes the replication terminator protein RTP. RTP binds to IRI and IRII. The ability of the IRR and its components to function as terminators, in conjunction with RTP, and their polarity of action have now been tested by the use of plasmids replicating in B. subtilis as unidirectional theta structures and into which potential terminator sequences were inserted in alternate orientations relative to fork movement. When the complete IRR was inserted into such plasmids and the new plasmids transferred into a B. subtilis strain overproducing RTP, it was able to block movement of a replication fork approaching from either direction. IRI and IRII were shown to function as polar terminators, each blocking movement of a fork when it approached from one particular direction but not the other. Furthermore, the polarity of action was in accordance with the IRR being able to operate as a replication fork trap. Thus, a fork approaching the IRR would pass through the first terminator encountered (IRI or IRII) and be halted by the second. The previously observed nonfunctioning of a particular orientation of chromosomal IRR as a fork arrest site probably reflects a limiting level of RTP in the cell. Interestingly, a 21 base-pair core sequence spanning a single RTP binding site within IRI (the 47 base-pair IRI contains 2 binding sites) was unable to arrest a fork approaching from either direction in the plasmid system. This suggests that both binding sites within an IR must be filled in order to function as an arrest site. It is possible that co-operative interaction between adjacent dimers within IRI or IRII provides the necessary conformation for causing fork arrest.