Bi-directional replication and random termination

Control of DNA replication in vitro using a reversible replication barrier

A major obstacle to studying DNA replication is that it involves asynchronous and highly delocalized events. A reversible replication barrier overcomes this limitation and allows replication fork movement to be synchronized and localized, facilitating the study of replication fork function and replication coupled repair. Here we provide details on establishing a reversible replication barrier in vitro and using it to monitor different aspects of DNA replication. DNA template containing an array of lac operator (lacO) sequences is first bound to purified lac repressor (LacR). This substrate is then replicated in vitro using a biochemical replication system, which results in replication forks stalled on either side of the LacR array regardless of when or where they arise. Once replication forks are synchronized at the barrier, isopropyl-β-D-thiogalactopyranoside can be added to disrupt LacR binding so that replication forks synchronously resume synthesis. We describe how this approach can be employed to control replication fork elongation, termination, stalling and uncoupling, as well as assays that can be used to monitor these processes. We also explain how this approach can be adapted to control whether replication forks encounter a DNA lesion on the leading or lagging strand template and whether a converging fork is present. The required reagents can be prepared in 1-2 weeks and experiments using this approach are typically performed over 1-3 d. The main requirements for utilizing the LacR replication barrier are basic biochemical expertise and access to an in vitro system to study DNA replication. Investigators should also be trained in working with radioactive materials.

The abundance of Fob1 modulates the efficiency of rRFBs to stall replication forks

In eukaryotes, ribosomal genes (rDNA) are organized in tandem repeats localized in one or a few clusters. Each repeat encompasses a transcription unit and a non-transcribed spacer. Replication forks moving in the direction opposite to transcription are blocked at specific sites called replication fork barriers (rRFBs) in the non-transcribed spacer close to the 3′ end of the transcription unit. Here, we investigated and quantified the efficiency of rRFBs in Saccharomyces cerevisiae and to this end transfected budding yeast cells that express dissimilar quantities of Fob1 with circular minichromosomes containing different copies of the minimal 20-bp DNA segment that bind Fob1. To identify fork stalling we used high-resolution 2D agarose gel electrophoresis. The results obtained indicated that neighbor DNA sequences and the relative abundance of Fob1 modulate the efficiency of rRFBs to stall replication forks.

Replication landscape of the human genome

Despite intense investigation, human replication origins and termini remain elusive. Existing data have shown strong discrepancies. Here we sequenced highly purified Okazaki fragments from two cell types and, for the first time, quantitated replication fork directionality and delineated initiation and termination zones genome-wide. Replication initiates stochastically, primarily within non-transcribed, broad (up to 150 kb) zones that often abut transcribed genes, and terminates dispersively between them. Replication fork progression is significantly co-oriented with the transcription. Initiation and termination zones are frequently contiguous, sometimes separated by regions of unidirectional replication. Initiation zones are enriched in open chromatin and enhancer marks, even when not flanked by genes, and often border ‘topologically associating domains' (TADs). Initiation zones are enriched in origin recognition complex (ORC)-binding sites and better align to origins previously mapped using bubble-trap than λ-exonuclease. This novel panorama of replication reveals how chromatin and transcription modulate the initiation process to create cell-type-specific replication programs.

The physical origin and termination sites of DNA replication in human cells have remained elusive. Here the authors use Okazaki fragment sequencing to reveal global replication patterns and show how chromatin and transcription modulate the process.

The mechanism of DNA replication termination in vertebrates

Eukaryotic DNA replication terminates when replisomes from adjacent replication origins converge. Termination involves local completion of DNA synthesis, decatenation of daughter molecules, and replisome disassembly. Termination has been difficult to study because termination events are generally asynchronous and sequence non-specific. To overcome these challenges, we paused converging replisomes with a site-specific barrier in Xenopus egg extracts. Upon removal of the barrier, forks underwent synchronous and site-specific termination, allowing mechanistic dissection of this process. We show that DNA synthesis does not slow detectably as forks approach each other and that leading strands pass each other unhindered before undergoing ligation to downstream lagging strands. Dissociation of CMG helicases occurs only after the final ligation step, and is not required for completion of DNA synthesis, strongly suggesting that converging CMGs pass one another and dissociate from double-stranded DNA. This termination mechanism allows rapid completion of DNA synthesis while avoiding premature replisome disassembly

Termination of DNA replication forks: "Breaking up is hard to do"

To ensure duplication of the entire genome, eukaryotic DNA replication initiates from thousands of replication origins. The replication forks move through the chromatin until they encounter forks from neighboring origins. During replication fork termination forks converge, the replisomes disassemble and topoisomerase II resolves the daughter DNA molecules. If not resolved efficiently, terminating forks result in genomic instability through the formation of pathogenic structures. Our recent findings shed light onto the mechanism of replisome disassembly upon replication fork termination. We have shown that termination-specific polyubiquitylation of the replicative helicase component – Mcm7, leads to dissolution of the active helicase in a process dependent on the p97/VCP/Cdc48 segregase. The inhibition of terminating helicase disassembly resulted in a replication termination defect. In this extended view we present hypothetical models of replication fork termination and discuss remaining and emerging questions in the DNA replication termination field.

Topoisomerase 2 is dispensable for the replication and segregation of small yeast artificial chromosomes (YACs)

DNA topoisomerases are thought to play a critical role in transcription, replication and recombination as well as in the condensation and segregation of sister duplexes during cell division. Here, we used high-resolution two-dimensional agarose gel electrophoresis to study the replication intermediates and final products of small circular and linear minichromosomes of Saccharomyces cerevisiae in the presence and absence of DNA topoisomerase 2. The results obtained confirmed that whereas for circular minichromosomes, catenated sister duplexes accumulated in the absence of topoisomerase 2, linear YACs were able to replicate and segregate regardless of this topoisomerase. The patterns of replication intermediates for circular and linear YACs displayed significant differences suggesting that DNA supercoiling might play a key role in the modulation of replication fork progression. Altogether, this data supports the notion that for linear chromosomes the torsional tension generated by transcription and replication dissipates freely throughout the telomeres.

Replicating damaged DNA in eukaryotes

DNA damage is one of many possible perturbations that challenge the mechanisms that preserve genetic stability during the copying of the eukaryotic genome in S phase. This short review provides, in the first part, a general introduction to the topic and an overview of checkpoint responses. In the second part, the mechanisms of error-free tolerance in response to fork-arresting DNA damage will be discussed in some detail.

A variable fork rate affects timing of origin firing and S phase dynamics in Saccharomyces cerevisiae

Activation (in the following referred to as firing) of replication origins is a continuous and irreversible process regulated by availability of DNA replication molecules and cyclin-dependent kinase activities, which are often altered in human cancers. The temporal, progressive origin firing throughout S phase appears as a characteristic replication profile, and computational models have been developed to describe this process. Although evidence from yeast to human indicates that a range of replication fork rates is observed experimentally in order to complete a timely S phase, those models incorporate velocities that are uniform across the genome. Taking advantage of the availability of replication profiles, chromosomal position and replication timing, here we investigated how fork rate may affect origin firing in budding yeast. Our analysis suggested that patterns of origin firing can be observed from a modulation of the fork rate that strongly correlates with origin density. Replication profiles of chromosomes with a low origin density were fitted with a variable fork rate, whereas for the ones with a high origin density a constant fork rate was appropriate. This indeed supports the previously reported correlation between inter-origin distance and fork rate changes. Intriguingly, the calculated correlation between fork rate and timing of origin firing allowed the estimation of firing efficiencies for the replication origins. This approach correctly retrieved origin efficiencies previously determined for chromosome VI and provided testable prediction for other chromosomal origins. Our results gain deeper insights into the temporal coordination of genome duplication, indicating that control of the replication fork rate is required for the timely origin firing during S phase.

Asymmetry indices for analysis and prediction of replication origins in eukaryotic genomes

DNA replication was recently shown to induce the formation of compositional skews in the genomes of the yeasts Saccharomyces cerevisiae and Kluyveromyces lactis. In this work, I have characterized further GC and TA skew variations in the vicinity of S. cerevisiae replication origins and termination sites, and defined asymmetry indices for origin analysis and prediction. The presence of skew jumps at some termination sites in the S. cerevisiae genome was established. The majority of S. cerevisiae replication origins are marked by an oriented consensus sequence called ACS, but no evidence could be found for asymmetric origin firing that would be linked to ACS orientation. Asymmetry indices related to GC and TA skews were defined, and a global asymmetry index I_GC,TA was described. I_GC,TA was found to strongly correlate with origin efficiency in S. cerevisiae and to allow the determination of sets of intergenes significantly enriched in origin loci. The generalized use of asymmetry indices for origin prediction in naive genomes implies the determination of the direction of the skews, i.e. the identification of which strand, leading or lagging, is enriched in G and which one is enriched in T. Recent work indicates that in Candida albicans and in several related species, centromeres contain early and efficient replication origins. It has been proposed that the skew jumps observed at these positions would reflect the activity of these origins, thus allowing to determine the direction of the skews in these genomes. However, I show here that the skew jumps at C. albicans centromeres are not related to replication and that replication-associated GC and TA skews in C. albicans have in fact the opposite directions of what was proposed.

Replication fork dynamics and the DNA damage response

Prevention and repair of DNA damage is essential for maintenance of genomic stability and cell survival. DNA replication during S-phase can be a source of DNA damage if endogenous or exogenous stresses impair the progression of replication forks. It has become increasingly clear that DNA-damage-response pathways do not only respond to the presence of damaged DNA, but also modulate DNA replication dynamics to prevent DNA damage formation during S-phase. Such observations may help explain the developmental defects or cancer predisposition caused by mutations in DNA-damage-response genes. The present review focuses on molecular mechanisms by which DNA-damage-response pathways control and promote replication dynamics in vertebrate cells. In particular, DNA damage pathways contribute to proper replication by regulating replication initiation, stabilizing transiently stalled forks, promoting replication restart and facilitating fork movement on difficult-to-replicate templates. If replication fork progression fails to be rescued, this may lead to DNA damage and genomic instability via nuclease processing of aberrant fork structures or incomplete sister chromatid separation during mitosis.

Effects of Friedreich's ataxia GAA repeats on DNA replication in mammalian cells

Friedreich's ataxia (FRDA) is a common hereditary degenerative neuro-muscular disorder caused by expansions of the (GAA)n repeat in the first intron of the frataxin gene. The expanded repeats from parents frequently undergo further significant length changes as they are passed on to progeny. Expanded repeats also show an age-dependent instability in somatic cells, albeit on a smaller scale than during intergenerational transmissions. Here we studied the effects of (GAA)n repeats of varying lengths and orientations on the episomal DNA replication in mammalian cells. We have recently shown that the very first round of the transfected DNA replication occurs in the lack of the mature chromatin, does not depend on the episomal replication origin and initiates at multiple single-stranded regions of plasmid DNA. We now found that expanded GAA repeats severely block this first replication round post plasmid transfection, while the subsequent replication cycles are only mildly affected. The fact that GAA repeats affect various replication modes in a different way might shed light on their differential expansions characteristic for FRDA.

Characterization of the replication origin of the myxobacterial self-replicative plasmid pMF1

Thus far, pMF1 is the only endogenous myxobacterial plasmid whose replication mechanism is unclear. In this study, we determined that the plasmid replicates via the theta-mode. The pMF1.14 gene, located in the pMF1.13-pMF1.15 operon (repABC), encodes an essential replication initiation protein that was predicted to have no typical DNA/protein binding motifs but contains rich disordered regions. The pMF1 replication-related essential cis-acting DNA region, approximate 370bp, was located within pMF1.14, and was found to contain several directly and inverted atypical repeats. The unique characteristics of the pMF1 replicon are suggested to be the reason for its strict narrow host range in Myxococcus cells.

Stimulation of direct-repeat recombination by RNA polymerase III transcription

Eukaryotic cells have to regulate the progression and integrity of DNA replication forks through concomitantly transcribed genes. A transcription-dependent increase of recombination within protein-coding and ribosomal genes of eukaryotic cells is well documented. Here we addressed whether tRNA transcription and tRNA-dependent transcription-associated replication pausing leads to genetic instability. Thus, we designed a plasmid based, LEU2 direct-repeat containing system for the analysis of factors that contribute to tRNA(SUP53)-dependent genetic instability. We show that tRNA(SUP53) transcription is recombinogenic and that recombination can be further stimulated by deletion of the 5' to 3' helicase Rrm3. Furthermore, tRNA(SUP53)-dependent recombination was markedly increased in the presence of 4-NQO in rrm3Delta cells only. The frequency of recombination events mediated by tRNA(SUP53) transcription does not correlate with the appearance and intensity of replication fork pausing sites. Our results provide evidence that the convergent encounter of replication and RNA polymerase III transcription machineries stimulates recombination, although to a lesser extent than RNA polymerase I or II transcription. However, there is no correlation between recombination and the specific replication fork pausing sites found at the tRNA (SUP53) gene. Our results indicate that tRNA-specific replication fork pausing sites are poorly recombinogenic.

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.

Rtf1-mediated eukaryotic site-specific replication termination

The molecular mechanisms mediating eukaryotic replication termination and pausing remain largely unknown. Here we present the molecular characterization of Rtf1 that mediates site-specific replication termination at the polar Schizosaccharomyces pombe barrier RTS1. We show that Rtf1 possesses two chimeric myb/SANT domains: one is able to interact with the repeated motifs encoded by the RTS1 element as well as the elements enhancer region, while the other shows only a weak DNA binding activity. In addition we show that the C-terminal tail of Rtf1 mediates self-interaction, and deletion of this tail has a dominant phenotype. Finally, we identify a point mutation in Rtf1 domain I that converts the RTS1 element into a replication barrier of the opposite polarity. Together our data establish that multiple protein DNA and protein-protein interactions between Rtf1 molecules and both the repeated motifs and the enhancer region of RTS1 are required for site-specific termination at the RTS1 element.

Precise determination, cross-recognition, and functional analysis of the double-strand origins of the rolling-circle replication plasmids in haloarchaea

The precise nick site in the double-strand origin (DSO) of pZMX201, a 1,668-bp rolling-circle replication (RCR) plasmid from the haloarchaeon Natrinema sp. CX2021, was determined by electron microscopy and DSO mapping. In this plasmid, DSO nicking occurred between residues C404 and G405 within a heptanucleotide sequence (TCTC/GGC) located in the stem region of an imperfect hairpin structure. This nick site sequence was conserved among the haloarchaeal RCR plasmids, including pNB101, suggesting that the DSO nick site might be the same for all members of this plasmid family. Interestingly, the DSOs of pZMX201 and pNB101 were found to be cross-recognized in RCR initiation and termination in a hybrid plasmid system. Mutation analysis of the DSO from pZMX201 (DSO(Z)) in this hybrid plasmid system revealed that: (i) the nucleotides in the middle of the conserved TCTCGGC sequence play more-important roles in the initiation and termination process; (ii) the left half of the hairpin structure is required for initiation but not for termination; and (iii) a 36-bp sequence containing TCTCGGC and the downstream sequence is essential and sufficient for termination. In conclusion, these haloarchaeal plasmids, with novel features that are different from the characteristics of both single-stranded DNA phages and bacterial RCR plasmids, might serve as a good model for studying the evolution of RCR replicons.

Replication fork reversal occurs spontaneously after digestion but is constrained in supercoiled domains

Replication fork reversal was investigated in undigested and linearized replication intermediates of bacterial DNA plasmids containing a stalled fork. Two-dimensional agarose gel electrophoresis, a branch migration and extrusion assay, electron microscopy, and DNA-psoralen cross-linking were used to show that extensive replication fork reversal and extrusion of the nascent-nascent duplex occurs spontaneously after DNA nicking and restriction enzyme digestion but that fork retreat is severely limited in covalently closed supercoiled domains.

Molecular characterization of the minimal replicon and the unidirectional theta replication of pSCM201 in extremely halophilic archaea

A 3,463-bp plasmid, pSCM201, was isolated from a halophilic archaeon, Haloarcula sp. strain AS7094. The minimal replicon that is essential and sufficient for autonomous replication and stable maintenance in Haloarcula hispanica was determined by deletion analysis of the plasmid. This minimal replicon ( approximately 1.8 kb) consisted of only two functionally related segments: (i) a putative origin (ori201) containing an AT-rich region and sets of repeats and (ii) an adjacent gene encoding a putative replication initiation protein (Rep201). Electron microscopic observation and Southern blotting analysis demonstrated that pSCM201 replicates via a theta mechanism. Precise mapping of the putative origin suggested that the replication initiated from a fixed site close to the AT-rich region and proceeded unidirectionally toward the downstream rep201 gene, which was further confirmed by electron microscopic analysis of the ClaI-digested replication intermediates. To our knowledge, this is the first unidirectional theta replication plasmid experimentally identified in the domain of archaea. It provides a novel plasmid system to conduct research on archaeal DNA replication.

Replication-associated strand asymmetries in mammalian genomes: toward detection of replication origins

In the course of evolution, mutations do not affect both strands of genomic DNA equally. This imbalance mainly results from asymmetric DNA mutation and repair processes associated with replication and transcription. In prokaryotes, prevalence of G over C and T over A is frequently observed in the leading strand. The sign of the resulting TA and GC skews changes abruptly when crossing replication-origin and termination sites, producing characteristic step-like transitions. In mammals, transcription-coupled skews have been detected, but so far, no bias has been associated with replication. Here, analysis of intergenic and transcribed regions flanking experimentally identified human replication origins and the corresponding mouse and dog homologous regions demonstrates the existence of compositional strand asymmetries associated with replication. Multiscale analysis of human genome skew profiles reveals numerous transitions that allow us to identify a set of 1,000 putative replication initiation zones. Around these putative origins, the skew profile displays a characteristic jagged pattern also observed in mouse and dog genomes. We therefore propose that in mammalian cells, replication termination sites are randomly distributed between adjacent origins. Taken together, these analyses constitute a step toward genome-wide studies of replication mechanisms.

From DNA sequence analysis to modeling replication in the human genome

We explore the large-scale behavior of nucleotide compositional strand asymmetries along human chromosomes. As we observe for 7 of 9 origins of replication experimentally identified so far, the (TA+GC) skew displays rather sharp upward jumps, with a linear decreasing profile in between two successive jumps. We present a model of replication with well positioned replication origins and random terminations that accounts for the observed characteristic serrated skew profiles. We succeed in identifying 287 pairs of putative adjacent replication origins with an origin spacing approximately 1-2 Mbp that are likely to correspond to replication foci observed in interphase nuclei and recognized as stable structures that persist throughout subsequent cell generations.

Bidirectional replication initiates at sites throughout the mitochondrial genome of birds

Analysis of mitochondrial replication intermediates of Gallus gallus on fork-direction gels indicates that replication occurs in both directions around circular mitochondrial DNA. This finding was corroborated by a study of chick mitochondrial DNA on standard neutral two-dimensional agarose gels, which yielded archetypal initiation arcs in fragments covering the entire genome. There was, however, considerable variation in initiation arc intensity. The majority of initiation events map to regions flanking the major non-coding region, in particular the NADH dehydrogenase subunit 6 (ND6) gene. Initiation point mapping of the ND6 gene identified prominent free 5' ends of DNA, which are candidate start sites for DNA synthesis. Therefore we propose that the initiation zone of G. gallus mitochondrial DNA encompasses most, if not all, of the genome, with preferred initiation sites in regions flanking the major non-coding region. Comparison with mammals suggests a common mechanism of initiation of mitochondrial DNA replication in higher vertebrates.

Characterization of a theta-replicating plasmid from Streptococcus thermophilus

Plasmids of Streptococcus thermophilus were previously classified, based on DNA homology, into at least four groups (A-D). Here, we report the characterization of plasmids of group B and D. The sequence analysis of pSMQ173b (group D) indicates that this plasmid contains 4449 bp, five open reading frames (ORFs) and replicates via the rolling-circle mechanism of the pGI3 family. The plasmid pSMQ308 (group B) contains 8144 bp and six ORFs. Two ORFs likely encode a primase/helicase and an integrase. Northern blot experiments demonstrate that these two orfs are transcribed within the three strains containing plasmids of group B. Two-dimensional agarose gel electrophoresis shows that pSMQ308 replicates via a theta mechanism. To our knowledge, this is the first report of a plasmid replicating via a theta mode in S. thermophilus. Finally, a classification of 20 sequenced S. thermophilus plasmids into six groups based on their mode of replication is proposed.

Rad52-independent accumulation of joint circular minichromosomes during S phase in Saccharomyces cerevisiae

We investigated the formation of X-shaped molecules consisting of joint circular minichromosomes (joint molecules) in Saccharomyces cerevisiae by two-dimensional neutral/neutral gel electrophoresis of psoralen-cross-linked DNA. The appearance of joint molecules was found to be replication dependent. The joint molecules had physical properties reminiscent of Holliday junctions or hemicatenanes, as monitored by strand displacement, branch migration, and nuclease digestion. Physical linkage of the joint molecules was detected along the entire length of the minichromosome and most likely involved newly replicated sister chromatids. Surprisingly, the formation of joint molecules was found to be independent of Rad52p as well as of other factors associated with a function in homologous recombination or in the resolution of stalled replication intermediates. These findings thus imply the existence of a nonrecombinational pathway(s) for the formation of joint molecules during the process of DNA replication or minichromosome segregation.

Complex mechanism of site-specific DNA replication termination in fission yeast

A site-specific replication terminator, RTS1, is present at the Schizosaccharomyces pombe mating-type locus mat1. RTS1 regulates the direction of replication at mat1, optimizing mating-type switching that occurs as a replication-coupled recombination event. Here we show that RTS1 contains two cis-acting sequences that cooperate for efficient replication termination. First, a sequence of approximately 450 bp containing four repeated 55 bp motifs is essential for function. Secondly, a purine-rich sequence of approximately 60 bp without intrinsic activity, located proximal to the repeats, acts cooperatively to increase barrier activity 4-fold. Our data suggest that the trans-acting factors rtf1p and rtf2p act through the repeated motifs and the purine-rich element, respectively. Thus, efficient site-specific replication termination at RTS1 occurs by a complex mechanism involving several cis-acting sequences and trans-acting factors. Interestingly, RTS1 displays similarities to mammalian rDNA replication barriers.

Examination of lactococcal bacteriophage c2 DNA replication using two-dimensional agarose gel electrophoresis

The ori locus of the prolate-headed lactococcal bacteriophage c2 supports plasmid replication in Lactococcus lactis in the absence of phage infection. To determine whether phage c2 DNA replication is initiated at the ori locus in vivo and to investigate the mechanism of phage DNA replication, replicating intermediates of phage c2 were analyzed using neutral/neutral two-dimensional agarose gel electrophoresis (2D). The 2D data revealed that c2 replicates via a theta mechanism and localized the initiation of theta replication to the ori region of the c2 genome.

A DNA replication-arrest site RTS1 regulates imprinting by determining the direction of replication at mat1 in S. pombe

Mating-type switching in Schizosaccharomyces pombe involves a strand-specific, alkali-labile imprint at the mat1 (mating-type) locus. The imprint is synthesized during replication in a swi1, swi3, and polymerase alpha (swi7) dependent manner and is dependent on mat1 being replicated in a specific direction. Here we show that the direction of replication at mat1 is controlled by a cis-acting polar terminator of replication (RTS1). Two-dimensional gel analysis of replication intermediates reveals that RTS1 only terminates replication forks moving in the centromere-distal direction. A genetic analysis shows that RTS1 optimizes the imprinting process. Transposing the RTS1 element to the distal side of mat1 abolishes imprinting of the native mat1 allele but restores imprinting of an otherwise unimprinted inverted mat1 allele. These data provide conclusive evidence for the "direction of replication model" that explains the asymmetrical switching pattern of S. pombe, and identify a DNA replication-arrest element implicated in a developmental process. Such elements could play a more general role during development and differentiation in higher eukaryotes by regulating the direction of DNA replication at key loci.