The DNA replication fork blocked at the Ter site may be an entrance for the RecBCD enzyme into duplex DNA.

In Escherichia coli, eight kinds of chromosome-derived DNA fragments (named Hot DNA) were found to exhibit homologous recombinational hotspot activity, with the following properties. (i) The Hot activities of all Hot DNAs were enhanced extensively under RNase H-defective (rnh) conditions. (ii) Seven Hot DNAs were clustered at the DNA replication terminus region on the E. coli chromosome and had Chi activities (H. Nishitani, M. Hidaka, and T. Horiuchi, Mol. Gen. Genet. 240:307-314, 1993). Hot activities of HotA, -B, and -C, the locations of which were close to three DNA replication terminus sites, the TerB, -A, and -C sites, respectively, disappeared when terminus-binding (Tau or Tus) protein was defective, thereby suggesting that their Hot activities are termination event dependent. Other Hot groups showed termination-independent Hot activities. In addition, at least HotA activity proved to be dependent on a Chi sequence, because mutational destruction of the Chi sequence on the HotA DNA fragment resulted in disappearance of the HotA activity. The HotA activity which had disappeared was reactivated by insertion of a new, properly oriented Chi sequence at the position between the HotA DNA and the TerB site. On the basis of these observations and positional and orientational relationships between the Chi and the Ter sequences, we propose a model in which the DNA replication fork blocked at the Ter site provides an entrance for the RecBCD enzyme into duplex DNA.     

FtsK controls metastable recombination provoked by an extra Ter site in the Escherichia coli chromosome terminus

The FtsK protein is required for septum formation in Escherichia coli and as a DNA translocase for chromosome processing while the septum closes. Its domain of action on the chromosome overlaps the replication terminus region, which lies between replication pause sites TerA and TerC. An extra Ter site, PsrA*, has been inserted at a position common to the FtsK and terminus domains. It is well tolerated, although it compels replication forks travelling clockwise from oriC to stall and await arrival of counter-clockwise forks. Elevated recombination has been detected at the stalled fork. Analysis of PsrA*-induced homologous recombination by an excision test revealed unique features. (i) rates of excision near PsrA* may fluctuate widely from clone to clone, a phenomenon we term whimsicality, (ii) excision rates are nevertheless conserved for many generations, a phenomenon we term memorization; their metastability at the clone level is explainable by frequent shifting between three cellular states--high, medium and low probability of excision, (iii) PsrA*-induced excision is RecBC-independent and is strongly counteracted by FtsK, which in addition is involved in its whimsicality and (iv) whimsicality disappears as the distance from the pause site increases. Action of FtsK at a replication fork was unexpected because the factor was thought to act on the chromosome only at septation, i.e. after replication is completed. Idiosyncrasy of PsrA*-induced recombination is discussed with respect to possible intermingling of replication, repair and post-replication steps of bacterial chromosome processing during the cell cycle.     

The Escherichia coli UvrD helicase is essential for Tus removal during recombination-dependent replication restart from Ter sites

Blocking replication forks in the Escherichia coli chromosome by ectopic Ter sites renders the RecBCD pathway of homologous recombination and SOS induction essential for viability. In this work, we show that the E. coli helicase II (UvrD) is also essential for the growth of cells where replication forks are arrested at ectopic Ter sites. We propose that UvrD is required for Tus removal from Ter sites. The viability of a SOS non-inducible Ter-blocked strain is fully restored by the expression of the two SOS-induced proteins UvrD and RecA at high level, indicating that these are the only two SOS-induced proteins required for replication across Ter/Tus complexes. Several observations suggest that UvrD acts in concert with homologous recombination and we propose that UvrD is associated with recombination-initiated replication forks and that it removes Tus when a PriA-dependent, restarted replication fork goes across the Ter/Tus complex. Finally, expression of the UvrD homologue from Bacilus subtilis PcrA restores the growth of uvrD-deficient Ter-blocked cells, indicating that the capacity to dislodge Tus is conserved in this distant bacterial species.     

Specific chromosomal sites enhancing homologous recombination in Escherichia coli mutants defective in RNase H

To clone new replication origin(s) activated under RNase H-defective (rnh ^?) conditions in Escherichia coli cells, whole chromosomal DNA digested with EcoRI was to with a Km^r DNA fragment and transformed into an rnh^? derivative host. From the Kmr transformants, we obtained eight kinds of plasmid-like DNA, each of which contained a specific DNA fragment, termed “Hot”, derived from the E. coli genome. Seven of the Hot DNAs (HotA-G) mapped to various sites within a narrow DNA replication termination region (about 280 kb), without any particular selection. Because Hot DNA could not be transformed into a mutant strain in which the corresponding Hot region had been deleted from the chromosome, the Hot DNA, though obtained as covalently closed circular (ccc) DNA, must have arisen by excision from the host chromosome into which it had initially integrated, rather than by autonomous replication of the transformed species. While Hot DNA does not have a weak replication origin it does have a strong recombinational hotspot active in the absence of RNase H. This notion is supported by the finding that Chi activity was present on all Hot DNAs tested and no Hot-positive clone without Chi activity was obtained, with the exception of a DNA clone carrying the dif site.     

Replication fork collapse at replication terminator sequences

Replication fork arrest is a source of genome re arrangements, and the recombinogenic properties of blocked forks are likely to depend on the cause of blockage. Here we study the fate of replication forks blocked at natural replication arrest sites. For this purpose, Escherichia coli replication terminator sequences Ter were placed at ectopic positions on the bacterial chromosome. The resulting strain requires recombinational repair for viability, but replication forks blocked at Ter are not broken. Linear DNA molecules are formed upon arrival of a second round of replication forks that copy the DNA strands of the first blocked forks to the end. A model that accounts for the requirement for homologous recombination for viability in spite of the lack of chromosome breakage is proposed. This work shows that natural and accidental replication arrests sites are processed differently.     

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.     

Requirement for RecFOR-mediated recombination in priA mutant

Restart of arrested replication forks is an important process and PriA, the main Escherichia coli replication restart protein, is essential for viability under any condition that increases the frequency of fork arrest. In priA mutant, replication forks are arrested by spontaneously occurring roadblocks and blocked replication forks persist as a result of the defect in replication restart. In the present work, we analysed how recombination proteins contribute to the viability of the priA mutant. RecFOR-mediated homologous recombination occurs in a large fraction of priA mutant cells, indicating a frequent formation of DNA single strand gaps and their recombinational repair. This high level of homologous recombination renders the proteins that resolve Holliday junctions recombination intermediates essential for viability. When homologous recombination is blocked at early steps by recFOR or recA inactivation, exonuclease V-mediated DNA degradation is required for full viability of priA mutants, indicating that unrepaired gaps are broken and that DNA degradation of the broken DNA allows the formation of viable cells. Models for the formation of single strand DNA gaps consequently to a replication restart defect and for gap processing are proposed.     

A model of the replication fork blocking protein Fob1p based on the catalytic core domain of retroviral integrases

The replication fork blocks are common in both prokaryotes and eukaryotes. In most cases, these blocks are associated with increased levels of mitotic recombination. One of the best-characterized replication fork blocks in eukaryotes is found in ribosomal DNA (rDNA) repeats of Saccharomyces cerevisiae. It has been shown that the replication fork blocking protein Fob1p regulates the recombination rate and the number of rDNA copies in S. cerevisiae, but the mechanistic aspects of these events are still poorly understood. Sequence profile searches revealed that Fob1p is related to retroviral integrases. Subsequently, the catalytic domain of HIV-1 integrase was used as a template to build a reliable three-dimensional model of Fob1p. Structural insights from this study may be useful in explaining Fob1p-mediated formation of extrachromosomal rDNA circles that accelerate aging in yeast and recombination events that lead to expansion or contraction of rDNA.     

Role of the Rep helicase gene in homologous recombination in Neisseria gonorrhoeae

In Escherichia coli, the Rep helicase has been implicated in replication fork progression, replication restart, homologous recombination, and DNA repair. We show that a Neisseria gonorrhoeae rep mutant is deficient in the homologous-recombination-mediated processes of DNA transformation and pilus-based colony variation but not in DNA repair.     

Differential Tus-Ter binding and lock formation: implications for DNA replication termination in Escherichia coli

In E. coli, DNA replication termination occurs at Ter sites and is mediated by Tus. Two clusters of five Ter sites are located on each side of the terminus region and constrain replication forks in a polar manner. The polarity is due to the formation of the Tus-Ter-lock intermediate. Recently, it has been shown that DnaB helicase which unwinds DNA at the replication fork is preferentially stopped at the non-permissive face of a Tus-Ter complex without formation of the Tus-Ter-lock and that fork pausing efficiency is sequence dependent, raising two essential questions: Does the affinity of Tus for the different Ter sites correlate with fork pausing efficiency? Is formation of the Tus-Ter-lock the key factor in fork pausing? The combined use of surface plasmon resonance and GFP-Basta showed that Tus binds strongly to TerA-E and G, moderately to TerH-J and weakly to TerF. Out of these ten Ter sites only two, TerF and H, were not able to form significant Tus-Ter-locks. Finally, Tus's resistance to dissociation from Ter sites and the strength of the Tus-Ter-locks correlate with the differences in fork pausing efficiency observed for the different Ter sites by Duggin and Bell (2009).     

Specific chromosomal sites enhancing homologous recombination in Escherichia coli mutants defective in RNase H

To clone new replication origin(s) activated under RNase H-defective (rnh ^–) conditions in Escherichia coli cells, whole chromosomal DNA digested with EcoRI was to with a Km^r DNA fragment and transformed into an rnh^– derivative host. From the Kmr transformants, we obtained eight kinds of plasmid-like DNA, each of which contained a specific DNA fragment, termed Hot, derived from the E. coli genome. Seven of the Hot DNAs (HotA-G) mapped to various sites within a narrow DNA replication termination region (about 280 kb), without any particular selection. Because Hot DNA could not be transformed into a mutant strain in which the corresponding Hot region had been deleted from the chromosome, the Hot DNA, though obtained as covalently closed circular (ccc) DNA, must have arisen by excision from the host chromosome into which it had initially integrated, rather than by autonomous replication of the transformed species. While Hot DNA does not have a weak replication origin it does have a strong recombinational hotspot active in the absence of RNase H. This notion is supported by the finding that Chi activity was present on all Hot DNAs tested and no Hot-positive clone without Chi activity was obtained, with the exception of a DNA clone carrying the dif site.     

Circular and linear simian virus 40 DNAs differ in recombination.

Linear forms of simian virus 40 (SV40) DNA, when added to transfection mixtures containing circular SV40 and phi X174 RFI DNAs, enhanced the frequency of SV40/phi X174 recombination, as measured by infectious center in situ plaque hybridization in monkey BSC-1 cells. The sequences required for the enhancement of recombination by linear DNA reside within the SV40 replication origin/regulatory region (nucleotides 5,171 to 5,243/0 to 128). Linearization of phi X174 RFI DNA did not increase the recombination frequency. The SV40/phi X174 recombinant structures arising from transfections supplemented with linear forms of origin-containing SV40 DNA contained phi X174 DNA sequences interspersed within tandem head-to-tail repeats derived from the recombination-enhancing linear DNA. Evidence is presented that the tandem repeats are not formed by homologous recombination and that linear forms of SV40 DNA must compete with circular SV40 DNA for the available T antigen to enhance recombination. We propose that the enhancement of recombination by linear SV40 DNA results from the entry of that DNA into a rolling circle type of replication pathway which generates highly recombinogenic intermediates.     

Unusual Telomeric DNAs in Human Telomerase-Negative Immortalized Cells

A significant fraction of human cancer cells and immortalized cells maintain telomeres in a telomerase-independent manner called alternative lengthening of telomeres (ALT). It has been suggested that ALT involves homologous recombination that is expected to generate unique intermediate DNAs. However, the precise molecular mechanism of ALT is not known. To gain insight into how telomeric DNAs (T-DNAs) are maintained in ALT, we examined the physical structures of T-DNAs in ALT cells. We found abundant single-stranded regions in both G and C strands of T-DNAs. Moreover, two-dimensional gel electrophoreses and native in-gel hybridization analyses revealed novel ALT-specific single-stranded T-DNAs, in addition to previously reported t-circles. These newly identified ALT-specific T-DNAs include (i) the t-complex, which consists of highly branched T-DNAs with large numbers of internal single-stranded portions; (ii) ss-G, which consists of mostly linear single-G-strand T-DNAs; and (iii) ss-C, which consists of most likely circular single-C-strand T-DNAs. Cellular-DNA fractionation by the Hirt protocol revealed that t-circles and ss-G exist in ALT cells as extrachromosomal and chromatin-associated DNAs. We propose that such ALT-specific T-DNAs are produced by telomere metabolism specific to ALT, namely, homologous recombination and the rolling-circle replication mechanism.     

Quantitation of a simian virus 40 nonhomologous recombination pathway.

We describe an infectious-center in situ plaque hybridization procedure which quantitates simian virus 40 (SV40) nonhomologous recombination in terms of the number of recombinant-producing cells in the DNA transfected cell population. Using this assay to measure the efficiency of recombination with SV40 DNA in permissive monkey BSC-1 cells, we found that: (i) over a range of DNA concentrations, polyomavirus DNA (which is partially homologous to SV40 DNA) cannot be distinguished from nonhomologous phi X174 RF1 DNA with respect to its ability to recombine with SV40 DNA; (ii) at defined DNA concentrations, polyomavirus and phi X174 RF1 DNA compete with each other for recombination with SV40 DNA; (iii) virtually all segments of the phi X174 genome recombine, apparently at random, with SV40 DNA; (iv) the frequency of recombinant-producing cells, among the successfully transfected (virion-producing) cells, depends upon the input SV40 DNA concentration in the transfection solution; and (v) replication-defective SV40 mutant DNAs compete with wild-type SV40 DNA for recombination with phi X174 RF1 DNA. From these observations, we conclude that the efficiency of recombination with SV40, in the system under study, is unaffected by nucleotide sequence homology and that a limiting stage in the recombination pathway occurs before SV40 DNA replication. Comparison of the dependency of recombination on initial SV40 DNA concentration with the dependency on initial phi X174 RF1 DNA concentration indicates that SV40 DNA sequences are a controlling factor in the nonhomologous recombination pathway.     

Recovery of Arrested Replication Forks by Homologous Recombination Is Error-Prone

Homologous recombination is a universal mechanism that allows repair of DNA and provides support for DNA replication. Homologous recombination is therefore a major pathway that suppresses non-homology-mediated genome instability. Here, we report that recovery of impeded replication forks by homologous recombination is error-prone. Using a fork-arrest-based assay in fission yeast, we demonstrate that a single collapsed fork can cause mutations and large-scale genomic changes, including deletions and translocations. Fork-arrest-induced gross chromosomal rearrangements are mediated by inappropriate ectopic recombination events at the site of collapsed forks. Inverted repeats near the site of fork collapse stimulate large-scale genomic changes up to 1,500 times over spontaneous events. We also show that the high accuracy of DNA replication during S-phase is impaired by impediments to fork progression, since fork-arrest-induced mutation is due to erroneous DNA synthesis during recovery of replication forks. The mutations caused are small insertions/duplications between short tandem repeats (micro-homology) indicative of replication slippage. Our data establish that collapsed forks, but not stalled forks, recovered by homologous recombination are prone to replication slippage. The inaccuracy of DNA synthesis does not rely on PCNA ubiquitination or trans-lesion-synthesis DNA polymerases, and it is not counteracted by mismatch repair. We propose that deletions/insertions, mediated by micro-homology, leading to copy number variations during replication stress may arise by progression of error-prone replication forks restarted by homologous recombination.     

Cells defective for replication restart undergo replication fork reversal

We have studied the fate of blocked replication forks with the use of the Escherichia coli priA mutant, in which spontaneously arrested replication forks persist owing to the lack of the major replication restart pathway. Such blocked forks undergo a specific reaction named replication fork reversal, in which newly synthesized strands anneal to form a DNA double-strand end adjacent to a four-way junction. Indeed, (i) priA recB mutant chromosomes are linearized by a reaction that requires the presence of the Holliday junction resolvase RuvABC, and (ii) RuvABC-dependent linearization is prevented by the presence of RecBC. Replication fork reversal in a priA mutant occurs independently of the recombination proteins RecA and RecR. recBC inactivation does not affect priA mutant viability but prevents priA chronic SOS induction. We propose that, in the absence of PriA, RecBC action at reversed forks does not allow replication restart, which leads to the accumulation of SOS-inducing RecA filaments. Our results suggest that types of replication blockage that cause replication fork reversal occur spontaneously.