Replication forks pause at yeast centromeres

Establishment of cohesion at the pericentromere by the Ctf19 kinetochore subcomplex and the replication fork-associated factor, Csm3

The cohesin complex holds sister chromatids together from the time of their duplication in S phase until their separation during mitosis. Although cohesin is found along the length of chromosomes, it is most abundant at the centromere and surrounding region, the pericentromere. We show here that the budding yeast Ctf19 kinetochore subcomplex and the replication fork-associated factor, Csm3, are both important mediators of pericentromeric cohesion, but they act through distinct mechanisms. We show that components of the Ctf19 complex direct the increased association of cohesin with the pericentromere. In contrast, Csm3 is dispensable for cohesin enrichment in the pericentromere but is essential in ensuring its functionality in holding sister centromeres together. Consistently, cells lacking Csm3 show additive cohesion defects in combination with mutants in the Ctf19 complex. Furthermore, delaying DNA replication rescues the cohesion defect observed in cells lacking Ctf19 complex components, but not Csm3. We propose that the Ctf19 complex ensures additional loading of cohesin at centromeres prior to passage of the replication fork, thereby ensuring its incorporation into functional linkages through a process requiring Csm3.

During cell division, chromosomes must be distributed accurately to daughter cells to protect against aneuploidy, a state in which cells have too few or too many chromosomes, and which is associated with diseases such as cancer and birth defects. This process begins with the generation of an exact copy of each chromosome and the establishment of tight linkages that hold the newly duplicated sister chromosomes together. These linkages, generated by the cohesin complex, are essential to resist the pulling forces of the spindle, which will pull the sister chromosomes apart into the two new daughter cells. Here we examine the establishment of cohesin at the pericentromere, the region surrounding the site of spindle attachment and where its forces are strongest. We find that a dedicated pathway promotes cohesin establishment in this region through a two-step mechanism. In the first step, a group of proteins, known as the Ctf19 complex, promote the association of cohesin with this region. In the second step, the Csm3 protein, which is coupled to the DNA replication machinery, ensures its conversion into functional linkages. We demonstrate the importance of this process for accurate chromosome segregation during cell division.

Highly transcribed RNA polymerase II genes are impediments to replication fork progression in Saccharomyces cerevisiae

Replication forks face multiple obstacles that slow their progression. By two-dimensional gel analysis, yeast forks pause at stable DNA protein complexes, and this pausing is greatly increased in the absence of the Rrm3 helicase. We used a genome-wide approach to identify 96 sites of very high DNA polymerase binding in wild-type cells. Most of these binding sites were not previously identified pause sites. Rather, the most highly represented genomic category among high DNA polymerase binding sites was the open reading frames (ORFs) of highly transcribed RNA polymerase II genes. Twice as many pause sites were identified in rrm3 compared with wild-type cells, as pausing in this strain occurred at both highly transcribed RNA polymerase II genes and the previously identified protein DNA complexes. ORFs of highly transcribed RNA polymerase II genes are a class of natural pause sites that are not exacerbated in rrm3 cells.

High-resolution mapping of points of site-specific replication stalling

Genetic instability due to stalled replication forks is thought to underlie a number of human diseases, such as premature ageing and cancer susceptibility syndromes. In addition, site-specific stalling occurs at some genetic loci. A detailed understanding of the topology of the stalled replication fork gives a valuable insight into the causes and mechanisms of replication stalling. The method described here allows mapping of the position of the 3'-end of the nascent leading or lagging strand at the replication fork, stalled at a site-specific barrier. The replicating DNA is purified, digested with restriction enzymes, and enriched by BND-cellulose chromatography. The DNA is separated on a sequencing gel, transferred to a membrane, and hybridised to a strand-specific probe. The data obtained using this method allow determining the position of the 3'-end of the nascent strand at a stalled fork with a one-nucleotide resolution.

Rad51 suppresses gross chromosomal rearrangement at centromere in Schizosaccharomyces pombe

Centromere that plays a pivotal role in chromosome segregation is composed of repetitive elements in many eukaryotes. Although chromosomal regions containing repeats are the hotspots of rearrangements, little is known about the stability of centromere repeats. Here, by using a minichromosome that has a complete set of centromere sequences, we have developed a fission yeast system to detect gross chromosomal rearrangements (GCRs) that occur spontaneously. Southern and comprehensive genome hybridization analyses of rearranged chromosomes show two types of GCRs: translocation between homologous chromosomes and formation of isochromosomes in which a chromosome arm is replaced by a copy of the other. Remarkably, all the examined isochromosomes contain the breakpoint in centromere repeats, showing that isochromosomes are produced by centromere rearrangement. Mutations in the Rad3 checkpoint kinase increase both types of GCRs. In contrast, the deletion of Rad51 recombinase preferentially elevates isochromosome formation. Chromatin immunoprecipitation analysis shows that Rad51 localizes at centromere around S phase. These data suggest that Rad51 suppresses rearrangements of centromere repeats that result in isochromosome formation.

Orchestration of the S-phase and DNA damage checkpoint pathways by replication forks from early origins

The S-phase checkpoint activated at replication forks coordinates DNA replication when forks stall because of DNA damage or low deoxyribonucleotide triphosphate pools. We explore the involvement of replication forks in coordinating the S-phase checkpoint using dun1Delta cells that have a defect in the number of stalled forks formed from early origins and are dependent on the DNA damage Chk1p pathway for survival when replication is stalled. We show that providing additional origins activated in early S phase and establishing a paused fork at a replication fork pause site restores S-phase checkpoint signaling to chk1Delta dun1Delta cells and relieves the reliance on the DNA damage checkpoint pathway. Origin licensing and activation are controlled by the cyclin-Cdk complexes. Thus, oncogene-mediated deregulation of cyclins in the early stages of cancer development could contribute to genomic instability through a deficiency in the forks required to establish the S-phase checkpoint.

Mrc1 and Tof1 regulate DNA replication forks in different ways during normal S phase

The Mrc1 and Tof1 proteins are conserved throughout evolution, and in budding yeast they are known to associate with the MCM helicase and regulate the progression of DNA replication forks. Previous work has shown that Mrc1 is important for the activation of checkpoint kinases in responses to defects in S phase, but both Mrc1 and Tof1 also regulate the normal process of chromosome replication. Here, we show that these two important factors control the normal progression of DNA replication forks in distinct ways. The rate of progression of DNA replication forks is greatly reduced in the absence of Mrc1 but much less affected by loss of Tof1. In contrast, Tof1 is critical for DNA replication forks to pause at diverse chromosomal sites where nonnucleosomal proteins bind very tightly to DNA, and this role is not shared with Mrc1.

Replication fork barriers: pausing for a break or stalling for time?

Defects in chromosome replication can lead to translocations that are thought to result from recombination events at stalled DNA replication forks. The progression of forks is controlled by an essential DNA helicase, which unwinds the parental duplex and can stall on encountering tight protein-DNA complexes. Such pause sites are hotspots for recombination and it has been proposed that stalled replisomes disassemble, leading to fork collapse. However, in both prokaryotes and eukaryotes it now seems that paused forks are surprisingly stable, so that DNA synthesis can resume without recombination if the barrier protein is removed. Recombination at stalled forks might require other events that occur after pausing, or might be dependent on features of the surrounding DNA sequence. These findings have important implications for our understanding of the regulation of genome stability in eukaryotic cells, in which pausing of forks is mediated by specific proteins that are associated with the replicative helicase.

The Saccharomyces cerevisiae Helicase Rrm3p Facilitates Replication Past Nonhistone Protein-DNA Complexes

The Saccharomyces cerevisiae RRM3 gene encodes a 5' to 3' DNA helicase. While replication of most of the yeast genome was not dependent upon Rrm3p, in its absence, replication forks paused and often broke at an estimated 1400 discrete sites, including tRNA genes, centromeres, inactive replication origins, and transcriptional silencers. These replication defects were associated with activation of the intra-S phase checkpoint. Activation of the checkpoint was critical for viability of rrm3Delta cells, especially at low temperatures. Each site whose replication was affected by Rrm3p is assembled into a nonnucleosomal protein-DNA complex. At tRNA genes and the silent mating type loci, disruption of these complexes eliminated dependence upon Rrm3p. These data indicate that the Rrm3p DNA helicase helps replication forks traverse protein-DNA complexes, naturally occurring impediments that are encountered in each S phase.

Dna2 helicase/nuclease causes replicative fork stalling and double-strand breaks in the ribosomal DNA of Saccharomyces cerevisiae

We have proposed that faulty processing of arrested replication forks leads to increases in recombination and chromosome instability in Saccharomyces cerevisiae and contributes to the shortened lifespan of dna2 mutants. Now we use the ribosomal DNA locus, which is a good model for all stages of DNA replication, to test this hypothesis. We show directly that DNA replication pausing at the ribosomal DNA replication fork barrier (RFB) is accompanied by the occurrence of double-strand breaks near the RFB. Both pausing and breakage are elevated in the early aging, hypomorphic dna2-2 helicase mutant. Deletion of FOB1, encoding the fork barrier protein, suppresses the elevated pausing and DSB formation, and represses initiation at rDNA ARSs. The dna2-2 mutation is synthetically lethal with deltarrm3, encoding another DNA helicase involved in rDNA replication. It does not appear to be the case that the rDNA is the only determinant of genome stability during the yeast lifespan however since strains carrying deletion of all chromosomal rDNA but with all rDNA supplied on a plasmid, have decreased rather than increased lifespan. We conclude that the replication-associated defects that we can measure in the rDNA are symbolic of similar events occurring either stochastically throughout the genome or at other regions where replication forks move slowly or stall, such as telomeres, centromeres, or replication slow zones.

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.

Tying up loose ends: nonhomologous end-joining in Saccharomyces cerevisiae

The ends of chromosomal DNA double-strand breaks (DSBs) can be accurately rejoined by at least two discrete pathways, homologous recombination and nonhomologous end-joining (NHEJ). The NHEJ pathway is essential for repair of specific classes of DSB termini in cells of the budding yeast Saccharomyces cerevisiae. Endonuclease-induced DSBs retaining complementary single-stranded DNA overhangs are repaired efficiently by end-joining. In contrast, damaged DSB ends (e.g., termini produced by ionizing radiation) are poor substrates for this pathway. NHEJ repair involves the functions of at least 10 genes, including YKU70, YKU80, DNL4, LIF1, SIR2, SIR3, SIR4, RAD50, MRE11, and XRS2. Most or all of these genes are required for efficient recombination-independent recircularization of linearized plasmids and for rejoining of EcoRI endonuclease-induced chromosomal DSBs in vivo. Several NHEJ mutants also display aberrant processing and rejoining of DSBs that are generated by HO endonuclease or formed spontaneously in dicentric plasmids. In addition, all NHEJ genes except DNL4 and LIF1 are required for stabilization of telomeric repeat sequences. Each of the proteins involved in NHEJ appears to bind, directly or through protein associations, with the ends of linear DNA. Enzymatic and/or structural roles in the rejoining of DSB termini have been postulated for several proteins within the group. Most yeast NHEJ genes have homologues in human cells and many biochemical activities and protein:protein interactions have been conserved in higher eucaryotes. Similarities and differences between NHEJ repair in yeast and mammalian cells are discussed.

Evidence from mutational specificity studies that yeast DNA polymerases delta and epsilon replicate different DNA strands at an intracellular replication fork

Although polymerases delta and epsilon are required for DNA replication in eukaryotic cells, whether each polymerase functions on a separate template strand remains an open question. To begin examining the relative intracellular roles of the two polymerases, we used a plasmid-borne yeast tRNA gene and yeast strains that are mutators due to the elimination of proofreading by DNA polymerases delta or epsilon. Inversion of the tRNA gene to change the sequence of the leading and lagging strand templates altered the specificities of both mutator polymerases, but in opposite directions. That is, the specificity of the polymerase delta mutator with the tRNA gene in one orientation bore similarities to the specificity of the polymerase epsilon mutator with the tRNA gene in the other orientation, and vice versa. We also obtained results consistent with gene orientation having a minor influence on mismatch correction of replication errors occurring in a wild-type strain. However, the data suggest that neither this effect nor differential replication fidelity was responsible for the mutational specificity changes observed in the proofreading-deficient mutants upon gene inversion. Collectively, the data argue that polymerases delta and epsilon each encounter a different template sequence upon inversion of the tRNA gene, and so replicate opposite strands at the plasmid DNA replication fork.

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.

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

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

Early activated replication origins within the cell cycle-regulated histone H4 genes in Physarum

It was previously shown that the two members of the cell cycle-regulated histone H4 gene family, H4-1 and H4-2, are replicated at the onset of S phase in the naturally synchronous plasmodium of Physarum polycephalum, suggesting that they are flanked by replication origins. It was further shown that a DNA fragment upstream of the H4-1 gene is able to confer autonomous replication of a plasmid in the budding yeast. In this paper, we re-investigated replication of the unlinked Physarum histone H4 genes by mapping the replication origin of these two loci using alkaline agarose gel and neutral/neutral 2-dimensional agarose gel electrophoreses. We showed that the two replicons containing the H4 genes are simultaneously activated at the onset of S phase and we mapped an efficient, bidirectional replication origin in the vicinity of each gene. Our data demonstrated that the Physarum sequence that functions as an ARS in yeast is not the site of replication initiation at the H4-1 locus. We also observed a stalling of the rightward moving replication fork downstream of the H4-1 gene, in a region where transient topoisomerase II sites were previously mapped. Our results further extend the concept of replication/transcription coupling in Physarum to cell cycle-regulated genes.

DnaB helicase is unable to dissociate RNA-DNA hybrids. Its implication in the polar pausing of replication forks at ColE1 origins

A series of plasmids were constructed containing two unidirectional ColE1 replication origins in either the same or opposite orientations and their replication mode was investigated using two-dimensional agarose gel electrophoresis. The results obtained showed that, in these plasmids, initiation of DNA replication occurred at only one of the two potential origins per replication round regardless of origins orientation. In those plasmids with inversely oriented origins, the silent origin act as a polar pausing site for the replication fork initiated at the other origin. The distance between origins (up to 5.8 kilobase pairs) affected neither the interference between them to initiate replication nor the pausing function of the silent origin. A deletion analysis indicated that the presence of a transcription promoter upstream of the origin was the only essential requirement for it to initiate replication as well as to account for its polar pausing function. Finally, in vitro helicase assays showed that Escherichia coli DnaB is able to melt DNA-DNA homoduplexes but is very inefficient to unwind RNA-DNA hybrids. Altogether, these observations strongly suggest that replication forks pause at silent ColE1 origins due to the inability of DnaB helicase, which leads the replication fork in vivo, to unwind RNA-DNA hybrids.

Bacteriophage T4 initiates bidirectional DNA replication through a two-step process

Two-dimensional gel analysis of the bacteriophage T4 ori(uvsY) region revealed a novel "comet" on the Y arc. This comet contains simple Y molecules in which the branch points map to the ori(uvsY) transcript region. The comet depends on the the origin and DNA synthesis and is abolished by a mutation that reduces replication without affecting transcription. These results argue that the branched molecules are intermediates in replication initiation. A transcriptional terminator, cloned just downstream of the origin promoter, shortened the tail of the comet. Therefore, the location of the transcript determines the DNA branch points. We conclude that the comet DNA consists of intermediates in which unidirectional replication has been triggered by priming from the RNA of the origin R loop.

Conserved cis- and trans-acting determinants for replication initiation and regulation of replication fork movement in tetrahymenid species

The rDNA minichromosomes of Tetrahymena thermophila and Tetrahymena pyriformis share a high degree of sequence similarity and structural organization. The T.thermophila 5' non-transcribed spacer (5' NTS) is sufficient for replication and contains three repeated sequence elements that are conserved in T.pyriformis , including type I elements, the only known determinant for replication control. To assess the role of conserved sequences in replication control, structural and functional studies were performed on T.pyriformis rDNA. Similar to T.thermophila , replication initiates exclusively in the 5' NTS, localizing to a 900 bp segment. Elongating replication forks arrest transiently at one site which bears strong similarity to a tripartite sequence element present at fork arrest sites in T.thermophila rDNA. An in vitro type I element binding activity indistinguishable from the T.thermophila protein, ssA-TIBF, was detected in T.pyriformis extracts. The respective TIBF proteins bind with comparable affinity to type I elements from both species, suggesting that in vivo recognition could cross species boundaries. Despite these similarities, the T.pyriformis 5' NTS failed to support replication in transformed T.thermophila cells, suggesting a more complex genetic organization than previously realized.

"Break copy" duplication: a model for chromosome fragment formation in Saccharomyces cerevisiae

Introduction of a chromosome fragmentation vector (CFV) into the budding yeast Saccharomyces cerevisiae results in a targeted homologous recombination event that yields an independently segregating chromosome fragment (CF) and an alteration in the strain's karyotype. Fragmentation with an acentric CFV directed in a centromere-proximal orientation generates a CF that contains all sequences proximal to the targeting segment and results in loss of the endogenous targeted chromosome to yield a 2N-1 + CF karyotype. In contrast, fragmentation with a centric CFV directed in a centromere-distal orientation generates a CF that contains all sequences distal to the targeting segment and retention of the endogenous targeted chromosome to yield a 2N + CF karyotype. We have termed this phenomenon "break copy" duplication. Using yeast strains in which the centromere had been transposed to a new location, it was demonstrated that the centromere inhibited break copy duplication. These data suggest that CF formation is the product of an unscheduled DNA replication event initiated by the free end of the CFV and is analogous to a "half" double-strand break gap-repair reaction. We suggest that break copy duplication may have evolved as a mechanism for maintenance of ploidy following DNA breakage.

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.

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.

The relationship between sequence-specific termination of DNA replication and transcription

In Escherichia coli and Bacillus subtilis replication fork arrest occurs in the terminus at sequence-specific sites by the binding of replication terminator proteins to the fork arrest sites. The protein-DNA complex causes polar arrest of the replication forks by inhibiting the activity of the replicative helicases in only one orientation of the terminus with respect to the replication origin. This activity has been named as polar contrahelicase. In this paper we report on a second novel activity of the terminator proteins of E.coli and B.subtilis, namely the ability of the proteins to block RNA chain elongation by several prokaryotic RNA polymerases in a polar mode. The replication terminator proteins ter and RTP of E.coli and B.subtilis respectively, impeded RNA chain elongation catalyzed by T7, SP6 and E.coli RNA polymerases in a polar mode at the replication arrest sites. The RNA chain anti-elongation and the contrahelicase activities were isopolar. Whereas one monomer of ter was necessary and sufficient to block RNA chain elongation, two interacting dimers of RTP were needed to effect the same blockage. The biological significance of the RNA chain anti-elongation activity is manifested in the functional inactivation of a replication arrest site by invasion of RNA chains from outside, and the consequent need to preserve replication arrest activity by restricting the passage of transcription through the terminus-terminator protein complex.

The chromatin of the Saccharomyces cerevisiae centromere shows cell-type specific changes

We have analysed the centromeric chromatin from chromosome XIV of Saccharomyces cerevisiae at different stages of mitosis with the help of mutants of the cell division cycle. The pattern of centromeric chromatin in cells arrested using cdc20-1, tub2-401 and cdc15-1 alleles was indistinguishable from that of vegetatively growing cells, indicating that the centromeric complex is constitutively present during mitosis and possibly throughout the entire cell cycle. In contrast chromatin isolated from G0 cells and spores exhibited distinct differences in centromeric chromatin probably due to structural rearrangements of the centromeric complex. In particular the alterations found in spores are indicative of an inactive centromeric complex. The differences in centromeric chromatin in spores do not reflect a general reorganisation of the chromatin in this cell type, as the chromatin structure of the PHO3/PHO5 locus in spores was found to be identical to that in vegetative cells under repressed conditions. Thus the structural analysis of the centromere in different cell types provides evidence about the requirement of CEN DNA/protein complexes in different cell types and in different stages of the cell cycle.

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.

Excision repair and gene orientation modulate the strand specificity of UV mutagenesis in a plasmid-borne yeast tRNA gene

Ultraviolet (UV) mutagenesis in a plasmid-borne Saccharomyces cerevisiae tRNA gene (SUP4-o) occurs preferentially at sites where the pyrimidine in the base pair is part of a dipyrimidine sequence on the transcribed strand. In this study, we examined whether excision repair, or strand identity with respect to DNA replication, influences this strand bias. The specificity of UV mutagenesis was determined for a wild type (RAD) strain and an isogenic excision repair-deficient (rad1) derivative, each carrying SUP4-o on the vector YCpMP2, or another vector (YCpJA1) that differed only in the orientation of SUP4-o with respect to a unique origin of replication. Most (> or = 90%) of the SUP4-o mutations induced by UV in these strains were single base pair substitutions, predominantly (> 87%) transitions. The rad1 defect and inversion of SUP4-o in the RAD strain eliminated the strand preference, whereas inversion of SUP4-o in the rad1 strain caused it to reappear. Both conditions also altered the distribution of frequently mutated sites and the relative fraction of transitions at TT sequences. These results suggest that excision repair and gene orientation can be important determinants for the strand and site specificities of UV mutagenesis in SUP4-o on YCpMP2 and YCpJA1. We consider several possible explanations for our observations, including potential roles for transcription by RNA polymerase II, sequence context effects on the efficiency of excision repair, and inherent differences in strand mutability or translesion synthesis by the leading and lagging strand DNA replication complexes.

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.

Analysis of Schizosaccharomyces pombe mitochondrial DNA replication by two dimensional gel electrophoresis

The entire mitochondrial genome of Schizosaccharomyces pombe ura4-294h- was analyzed by the 2D pulsed field gel electrophoresis technique developed by Brewer and Fangman. The genome consists of multimers with an average size of 100 kb and analysis of the overlapping restriction fragments of the complete mitochondrial DNA (mtDNA) genome resulted in simple Y 2D gel patterns. Large single-stranded DNA molecules or double-stranded DNA molecules containing large or numerous single-stranded regions were found in the S. pombe mtDNA preparation. The replication of mtDNA monomers was found to occur in either direction. On the basis of these results, a replication mechanism for S. pombe mtDNA that is most consistent with a rolling circle model is suggested.

A search for an essential function of the replication origin ARS1 in the life cycle of Saccharomyces cerevisiae

We have investigated the significance of the chromosomal replication origin, ARS1, during the entire life cycle of yeast. This was done by substituting the chromosomal copy with a series of ars1 deletion mutants. It was shown that the ARS1 replication origin is not essential for mitotic or premeiotic DNA replication since no effect on growth, chromosomal loss rate and spore viability was observed in the ars1 mutant strains. We conclude that replication origins are abundantly, present in the yeast genome and that the removal of a single replication origin is compensated for by replication forks emanating from neighbouring origins.

The centromere of budding yeast

Stable maintenance of genetic information during meiosis and mitosis is dependent on accurate chromosome transmission. The centromere is a key component of the segregational machinery that couples chromosomes with the spindle apparatus. Most of what is known about the structure and function of the centromeres has been derived from studies on yeast cells. In Saccharomyces cerevisiae, the centromere DNA requirements for mitotic centromere function have been defined and some of the proteins required for an active complex have been identified. Centromere DNA and the centromere proteins form a complex that has been studied extensively at the chromatin level. Finally, recent findings suggest that assembly and activation of the centromere are integrated in the cell cycle.

The arrest of replication forks in the rDNA of yeast occurs independently of transcription

Replication forks, moving opposite to the direction of transcription, are arrested at the 3' ends of the 35S transcription units in the rDNA locus of S. cerevisiae. Because of its position and polarity, we tested the hypothesis that this replication fork barrier (RFB) results from the act of transcription. Three results contradict this hypothesis. First, the RFB persists in a strain containing a disruption of the gene for the 135 kd subunit of RNA polymerase I. Second, the RFB causes a polar arrest of replication forks when transplanted to a plasmid. Third, transcription by RNA polymerase II of a plasmid copy of the 35S transcription unit lacking the RFB does not generate a barrier. We propose that replication forks are arrested in a directional manner through the binding of one or more proteins to two closely spaced sites in the RFB.