Role of replication and CpG methylation in fragile X syndrome CGG deletions in primate cells

Instability of the fragile X CGG repeat involves both maternally derived expansions and deletions in the gametes of full-mutation males. It has also been suggested that the absence of aberrant CpG methylation may enhance repeat deletions through an unknown process. The effect of CGG tract length, DNA replication direction, location of replication initiation, and CpG methylation upon CGG stability were investigated using an SV40 primate replication system. Replication-dependant deletions with 53 CGG repeats were observed when replication was initiated proximal to the repeat, with CGG as the lagging-strand template. When we initiated replication further from the repeat, while maintaining CGG as the lagging-strand template or using CCG as the lagging-strand template, significant instability was not observed. CpG methylation of the unstable template stabilized the repeat, decreasing both the frequency and the magnitude of deletion events. Furthermore, CpG methylation slowed the efficiency of replication for all templates. Interestingly, replication forks displayed no evidence of a block at the CGG repeat tract, regardless of replication direction or CpG methylation status. Templates with 20 CGG repeats were stable under all circumstances. These results reveal that CGG deletions occur during replication and are sensitive to replication-fork dynamics, tract length, and CpG methylation.     

DNA double-strand breaks induce deletion of CTG.CAG repeats in an orientation-dependent manner in Escherichia coli

The influences of double-strand breaks (DSBs) within a triplet repeat sequence on its genetic instabilities (expansions and deletions) related to hereditary neurological diseases was investigated. Plasmids containing 43 or 70 CTG.CAG repeats or 43 CGG.CCG repeats were linearized in vitro near the center of the repeats and were transformed into parental, RecA-dependent homologous recombination-deficient, or RecBC exonuclease-deficient Escherichia coli. The resulting repair process considerably increased deletion of the repeating sequence compared to the circular DNA controls. Unexpectedly, the orientation of the insert relative to the unidirectional ColE1 origin of replication affected the amount of instability generated during the repair of the DSB. When the CTG strand was the template for lagging-strand synthesis, instability was increased, most markedly in the recA- strain. Results indicated that RecA and/or RecBC might play a role in DSB repair within the triplet repeat. Altering the length, orientation, and sequence composition of the triplet repeat suggested an important role of DNA secondary structures during repair intermediates. Hence, we hypothesize that ColE1 origin-dependent replication was involved during the repair of the DSB. A model is presented to explain the mechanisms of the observed genetic instabilities.     

The roles of mutS, sbcCD and recA in the propagation of TGG repeats in Escherichia coli

A 24 triplet TGG·CCA repeat array shows length- and orientation-dependent propagation when present in the plasmid pUC18. When TGG₂₄ is present as template for leading-strand synthesis, plasmid recovery is normal in all strains tested. However, when it acts as template for lagging-strand synthesis, plasmid propagation is seriously compromised. Plasmids carrying deletions in the 5′ side of this sequence can be isolated and products carrying 15 TGG triplets do not significantly interfere with plasmid propagation. Mutations in sbcCD, mutS and recA significantly improve the recovery of plasmids with TGG₂₄ on the lagging-strand template. These findings suggest that TGG₂₄ can fold into a structure that can interfere with DNA replication in vivo but that TGG₁₅ cannot. Furthermore, since the presence of the MutS and SbcCD proteins are required for propagation interference, it is likely that stabilisation of mismatched base pairs and secondary structure cleavage are implicated. In contrast, there is no correlation of triplet repeat expansion and deletion instability with predicted DNA folding. These results argue for a dissociation of the factors affecting DNA fragility from those affecting trinucleotide repeat expansion–contraction instability.     

Evidence for two mechanisms of palindrome-stimulated deletion in Escherichia coli: single-strand annealing and replication slipped mispairing

Spontaneous deletion mutations often occur at short direct repeats that flank inverted repeat sequences. Inverted repeats may initiate genetic rearrangements by formation of hairpin secondary structures that block DNA polymerases or are processed by structure-specific endonucleases. We have investigated the ability of inverted repeat sequences to stimulate deletion of flanking direct repeats in Escherichia coli. Propensity for cruciform extrusion in duplex DNA correlated with stimulation of flanking deletion, which was partially sbcD dependent. We propose two mechanisms for palindrome-stimulated deletion, SbcCD dependent and SbcCD independent. The SbcCD-dependent mechanism is initiated by SbcCD cleavage of cruciforms in duplex DNA followed by RecA-independent single-strand annealing at the flanking direct repeats, generating a deletion. Analysis of deletion endpoints is consistent with this model. We propose that the SbcCD-independent pathway involves replication slipped mispairing, evoked from stalling at hairpin structures formed on the single-stranded lagging-strand template. The skew of SbcCD-independent deletion endpoints with respect to the direction of replication supports this hypothesis. Surprisingly, even in the absence of palindromes, SbcD affected the location of deletion endpoints, suggesting that SbcCD-mediated strand processing may also accompany deletion unassociated with secondary structures.     

Effects of sequence on repeat expansion during DNA replication

Small DNA repeat tracts are located throughout the human genome. The tracts are unstable, and expansions of certain repeat sequences cause neuromuscular disease. DNA expansions appear to be associated with lagging-strand DNA synthesis and DNA repair. At some sites of repeat expansion, e.g. the myotonic dystrophy type 2 (DM2) tetranucleotide repeat expansion site, more than one repeat tract with similar sequences lie side by side. Only one of the DM2 repeat tracts, however, is found to expand. Thus, DNA base sequence is a possible factor in repeat tract expansion. Here we determined the expansion potential, during DNA replication by human DNA polymerase β, of several tetranucleotide repeat tracts in which the repeat units varied by one or more bases. The results show that subtle changes, such as switching T for C in a tetranucleotide repeat, can have dramatic consequences on the ability of the nascent-strand repeat tract to expand during DNA replication. We also determined the relative stabilities of self-annealed 100mer repeats by melting-curve analysis. The relative stabilities did not correlate with the relative potentials of the analogous repeats for expansion during DNA replication, suggesting that hairpin formation is not required for expansion during DNA replication.     

Initiation of unidirectional ColE2 DNA replication by a unique priming mechanism.

The ColE2 DNA can be replicated in an in vitro system consisting of a crude extract of Escherichia coli cells. DNA synthesis requires a plasmid-coded protein (Rep) and host DNA polymerase I but not host RNA polymerase. Replication starts at a fixed region containing the origin and proceeds unidirectionally. The leading- and lagging-strand DNA fragments synthesized around the origin were identified from early replicative intermediates. The 5' end of the leading-strand DNA fragment was mapped at a unique position in the minimal origin and carried RNA of a few residues. The results suggested that the initiation of the leading-strand DNA synthesis does not require the host DnaG protein. Thus the Rep protein itself seems to be a primase. Synthesis of the primer RNA at a fixed site in the origin region on a double-stranded DNA template is a unique property of the ColE2 Rep protein among other known primases. The 3' end of the lagging-strand DNA fragment was mapped at a unique position just at the end of the minimal origin region. Termination of the lagging-strand DNA fragment at that position seems to be the mechanism of the unidirectional replication of ColE2 plasmid.     

CAG*CTG repeat instability in cultured human astrocytes

Cells of the central nervous system (CNS) are prone to the devastating consequences of trinucleotide repeat (TNR) expansion. Some CNS cells, including astrocytes, show substantial TNR instability in affected individuals. Since astrocyte enrichment occurs in brain regions sensitive to neurodegeneration and somatic TNR instability, immortalized SVG-A astrocytes were used as an ex vivo model to mimic TNR mutagenesis. Cultured astrocytes produced frequent (up to 2%) CAG·CTG contractions in a sequence-specific fashion, and an apparent threshold for instability was observed between 25 and 33 repeats. These results suggest that cultured astrocytes recapitulate key features of TNR mutagenesis. Furthermore, contractions were influenced by DNA replication through the repeat, suggesting that instability can arise by replication-based mechanisms in these cells. This is a crucial mechanistic point, since astrocytes in the CNS retain proliferative capacity throughout life and could be vulnerable to replication-mediated TNR instability. The presence of interruptions led to smaller but more frequent contractions, compared to a pure repeat, and the interruptions were sometimes deleted to form a perfect tract. In summary, we suggest that CAG·CTG repeat instability in cultured astrocytes is dynamic and replication-driven, suggesting that TNR mutagenesis may be influenced by the proliferative capacity of key CNS cells.     

Schizosaccharomyces pombe Swi1, Swi3, and Hsk1 are components of a novel S-phase response pathway to alkylation damage

The Swi1 and Swi3 proteins are required for mat1 imprinting and mating-type switching in Schizosaccharomyces pombe, where they mediate a pause of leading-strand replication in response to a lagging-strand signal. In addition, Swi1 has been demonstrated to be involved in the checkpoint response to stalled replication forks, as was described for the Saccharomyces cerevisiae homologue Tof1. This study addresses the roles of Swi1 and Swi3 during a replication process perturbed by the presence of template bases alkylated by methyl methanesulfonate (MMS). Both the swi1 and swi3 mutations have additive effects on MMS sensitivity and on the MMS-induced damage checkpoint response when combined with chk1 and cds1, but they are nonadditive with hsk1. Cells with swi1, swi3, or hsk1 mutations are also defective in slowing progression through S phase in response to MMS damage. Moreover, swi1 and swi3 strains show increased levels of genomic instability even in the absence of exogenously induced DNA damage. Chromosome fragmentation, increased levels of single-stranded DNA, increased recombination, and instability of replication forks stalled in the presence of hydroxyurea are observed, consistent with the possibility that the replication process is affected in these mutants. In conclusion, Swi1, Swi3, and Hsk1 act in a novel S-phase checkpoint pathway that contributes to replication fork maintenance and to survival of alkylation damage.     

Absence of MutSβ leads to the formation of slipped-DNA for CTG/CAG contractions at primate replication forks

Typically disease-causing CAG/CTG repeats expand, but rare affected families can display high levels of contraction of the expanded repeat amongst offspring. Understanding instability is important since arresting expansions or enhancing contractions could be clinically beneficial. The MutSβ mismatch repair complex is required for CAG/CTG expansions in mice and patients. Oddly, by unknown mechanisms MutSβ-deficient mice incur contractions instead of expansions. Replication using CTG or CAG as the lagging strand template is known to cause contractions or expansions respectively; however, the interplay between replication and repair leading to this instability remains unclear. Towards understanding how repeat contractions may arise, we performed in vitro SV40-mediated replication of repeat-containing plasmids in the presence or absence of mismatch repair. Specifically, we separated repair from replication: Replication mediated by MutSβ- and MutSα-deficient human cells or cell extracts produced slipped-DNA heteroduplexes in the contraction- but not expansion-biased replication direction. Replication in the presence of MutSβ disfavoured the retention of replication products harbouring slipped-DNA heteroduplexes. Post-replication repair of slipped-DNAs by MutSβ-proficient extracts eliminated slipped-DNAs. Thus, a MutSβ-deficiency likely enhances repeat contractions because MutSβ protects against contractions by repairing template strand slip-outs. Replication deficient in LigaseI or PCNA-interaction mutant LigaseI revealed slipped-DNA formation at lagging strands. Our results reveal that distinct mechanisms lead to expansions or contractions and support inhibition of MutSβ as a therapeutic strategy to enhance the contraction of expanded repeats.     

Inversions with Deletions and Duplications

Complex mutational events, including de novo inversion with deletion and duplication of sequence, have been observed but are difficult to model. We propose that nascent leading-strand misalignment upon the lagging-strand template during DNA replication can result in the inversion of sequence. The positioning of this misalignment and of the realignment of the leading strand back onto the leading-strand template will determine if the inversion is accompanied by deletion and duplication of sequence. We suggest that such strand misalignment-realignment events may occur at the replication fork during concurrent DNA replication.     

Replication inhibitors modulate instability of an expanded trinucleotide repeat at the myotonic dystrophy type 1 disease locus in human cells

Gene-specific CTG/CAG repeat expansion is associated with at least 14 human diseases, including myotonic dystrophy type 1 (DM1). Most of our understanding of trinucleotide instability is from nonhuman models, which have presented mixed results, supporting replication errors or processes independent of cell division as causes. Nevertheless, the mechanism occurring at the disease loci in patient cells is poorly understood. Using primary fibroblasts derived from a fetus with DM1, we have shown that spontaneous expansion of the diseased (CTG)(216) allele occurred in proliferating cells but not in quiescent cells. Expansions were "synchronous," with mutation frequencies approaching 100%. Furthermore, cells were treated with agents known to alter DNA synthesis but not to directly damage DNA. Inhibiting replication initiation with mimosine had no effect upon instability. Inhibiting both leading- and lagging-strand synthesis with aphidicolin or blocking only lagging strand synthesis with emetine significantly enhanced CTG expansions. It was striking that only the expanded DM1 allele was altered, leaving the normal allele, (CTG)(12), and other repeat loci unaffected. Standard and small-pool polymerase chain reaction revealed that inhibitors enhanced the magnitude of short expansions in most cells threefold, whereas 11%-25% of cells experienced gains of 122-170 repeats, to sizes of (CTG)(338)-(CTG)(386). Similar results were observed for an adult DM1 cell line. Our results support a role for the perturbation of replication fork dynamics in DM1 CTG expansions within patient fibroblasts. This is the first report that repeat-length alterations specific to a disease allele can be modulated by exogenously added compounds.     

Palindrome regeneration by template strand-switching mechanism at the origin of DNA replication of porcine circovirus via the rolling-circle melting-pot replication model

Palindromic sequences (inverted repeats) flanking the origin of DNA replication with the potential of forming single-stranded stem-loop cruciform structures have been reported to be essential for replication of the circular genomes of many prokaryotic and eukaryotic systems. In this study, mutant genomes of porcine circovirus with deletions in the origin-flanking palindrome and incapable of forming any cruciform structures invariably yielded progeny viruses containing longer and more stable palindromes. These results suggest that origin-flanking palindromes are essential for termination but not for initiation of DNA replication. Detection of template strand switching in the middle of an inverted repeat strand among the progeny viruses demonstrated that both the minus genome and a corresponding palindromic strand served as templates simultaneously during DNA biosynthesis and supports the recently proposed rolling-circle "melting-pot" replication model. The genome configuration presented by this model, a four-stranded tertiary structure, provides insights into the mechanisms of DNA replication, inverted repeat correction (or conversion), and illegitimate recombination of any circular DNA molecule with an origin-flanking palindrome.     

Lagging-Strand Replication from the ssoA Origin of Plasmid pMV158 in Streptococcus pneumoniae: In Vivo and In Vitro Influences of Mutations in Two Conserved ssoA Regions

The streptococcal plasmid pMV158 replicates by the rolling-circle mechanism. One feature of this replication mechanism is the generation of single-stranded DNA intermediates which are converted to double-stranded molecules. Lagging-strand synthesis initiates from the plasmid single-stranded origin, sso. We have used the pMV158-derivative plasmid pLS1 (containing the ssoA type of lagging-strand origin) and a set of pLS1 derivatives with mutations in two conserved regions of the ssoA (the recombination site B [RS_B] and a conserved 6-nucleotide sequence [CS-6]) to identify sequences important for plasmid lagging-strand replication in Streptococcus pneumoniae. Cells containing plasmids with mutations in the RS_B accumulated 30-fold more single-stranded DNA than cells containing plasmids with mutations in the CS-6 sequence. Specificity of lagging-strand synthesis was tested by the development of a new in vitro replication system with pneumococcal cell extracts. Four major initiation sites of lagging-strand DNA synthesis were observed. The specificity of initiation was maintained in plasmids with mutations in the CS-6 region. Mutations in the RS_B region, on the other hand, resulted in the loss of specific initiation of lagging-strand synthesis and also severely reduced the efficiency of replication.     

Accumulation of Single-Stranded DNA and Destabilization of Telomeric Repeats in Yeast Mutant Strains Carrying a Deletion of RAD27

The Saccharomyces cerevisiae RAD27 gene encodes the yeast homologue of the mammalian FEN-1 nuclease, a protein that is thought to be involved in the processing of Okazaki fragments during DNA lagging-strand synthesis. One of the predicted DNA lesions occurring in rad27 strains is the presence of single-stranded DNA of the template strand for lagging-strand synthesis. We examined this prediction by analyzing the terminal DNA structures generated during telomere replication in rad27 strains. The lengths of the telomeric repeat tracts were found to be destabilized in rad27 strains, indicating that naturally occurring direct repeats are subject to tract expansions and contractions in such strains. Furthermore, abnormally high levels of single-stranded DNA of the templating strand for lagging-strand synthesis were observed in rad27 cells. Overexpression of Dna2p in wild-type cells also yielded single-stranded DNA regions on telomeric DNA and caused a cell growth arrest phenotype virtually identical to that seen for rad27 cells grown at the restrictive temperature. Furthermore, overexpression of the yeast exonuclease Exo1p alleviated the growth arrest induced by both conditions, overexpression of Dna2p and incubation of rad27 cells at 37 degrees C. However, the telomere heterogeneity and the appearance of single-stranded DNA are not prevented by the overexpression of Exo1p in these strains, suggesting that this nuclease is not simply redundant with Rad27p. Our data thus provide in vivo evidence for the types of DNA lesions predicted to occur when lagging-strand synthesis is deficient and suggest that Dna2p and Rad27p collaborate in the processing of Okazaki fragments.     

Novel PMS1 alleles preferentially affect the repair of primer strand loops during DNA replication

Null mutations in DNA mismatch repair (MMR) genes elevate both base substitutions and insertions/deletions in simple sequence repeats. Data suggest that during replication of simple repeat sequences, polymerase slippage can generate single-strand loops on either the primer or template strand that are subsequently processed by the MMR machinery to prevent insertions and deletions, respectively. In the budding yeast Saccharomyces cerevisiae and mammalian cells, MMR appears to be more efficient at repairing mispairs comprised of loops on the template strand compared to loops on the primer strand. We identified two novel yeast pms1 alleles, pms1-G882E and pms1-H888R, which confer a strong defect in the repair of "primer strand" loops, while maintaining efficient repair of "template strand" loops. Furthermore, these alleles appear to affect equally the repair of 1-nucleotide primer strand loops during both leading- and lagging-strand replication. Interestingly, both pms1 mutants are proficient in the repair of 1-nucleotide loop mispairs in heteroduplex DNA generated during meiotic recombination. Our results suggest that the inherent inefficiency of primer strand loop repair is not simply a mismatch recognition problem but also involves Pms1 and other proteins that are presumed to function downstream of mismatch recognition, such as Mlh1. In addition, the findings reinforce the current view that during mutation avoidance, MMR is associated with the replication apparatus.     

Bacteriophage T4 helicase loader protein gp59 functions as gatekeeper in origin-dependent replication in vivo

Bacteriophage T4 initiates origin-dependent replication via an R-loop mechanism in vivo. During in vitro reactions, the phage-encoded gp59 stimulates loading of the replicative helicase, gp41, onto branched intermediates, including origin R-loops. However, although gp59 is essential for recombination-dependent replication from D-loops, it does not appear to be required for origin-dependent replication in vivo. In this study, we have analyzed the origin-replicative intermediates formed during infections that are deficient in gp59 and other phage replication proteins. During infections lacking gp59, the initial replication forks from two different T4 origins actively replicated both leading- and lagging-strands. However, the retrograde replication forks from both origins were abnormal in the gp59-deficient infections. The lagging-strand from the initial fork was elongated as a new leading-strand in the retrograde direction without lagging-strand synthesis, whereas in the wild-type, leading- and lagging-strand synthesis appeared to be coupled. These results imply that gp59 inhibits the polymerase holoenzyme in vivo until the helicase-primase (gp41-gp61) complex is loaded, and we thereby refer to gp59 as a gatekeeper. We also found that all origin-replicative intermediates were absent in infections deficient in the helicase gp41 or the single-strand-binding protein gp32, regardless of whether gp59 was present or absent. These results argue that replication from the origin in vivo is dependent on both the helicase and single-strand-binding protein and demonstrate that the strong replication defect of gene 41 and 32 single mutants is not caused by gp59 inhibition of the polymerase.     

Genetic instability induced by overexpression of DNA ligase I in budding yeast

Recombination and microsatellite mutation in humans contribute to disorders including cancer and trinucleotide repeat (TNR) disease. TNR expansions in wild-type yeast may arise by flap ligation during lagging-strand replication. Here we show that overexpression of DNA ligase I (CDC9) increases the rates of TNR expansion, of TNR contraction, and of mitotic recombination. Surprisingly, this effect is observed with catalytically inactive forms of Cdc9p protein, but only if they possess a functional PCNA-binding site. Furthermore, in vitro analysis indicates that the interaction of PCNA with Cdc9p and Rad27p (Fen1) is mutually exclusive. Together our genetic and biochemical analysis suggests that, although DNA ligase I seals DNA nicks during replication, repair, and recombination, higher than normal levels can yield genetic instability by disrupting the normal interplay of PCNA with other proteins such as Fen1.     

Hairpin structures are the primary amplification products: a novel mechanism for generation of inverted repeats during gene amplification.

Early events of DNA amplification which occur during perturbed replication were studied by using simian virus 40 (SV40)-transformed Chinese hamster cells (CO60) as a model system. The amplification is observed shortly after carcinogen treatment, and the amplified sequences contain molecules organized as inverted repeats (IRs). SV40 amplification in vitro was studied by using extracts from carcinogen-treated CO60 cells. In the amplified DNA the SV40 origin region was rereplicated, while more distal sequences were not replicated even once. Using several experimental procedures such as sucrose gradients, "snap-back" assay, and two-dimensional gel electrophoresis, we show that the overreplicated DNA contains IRs which are synthesized de novo as hairpins or stem-loop structures which were detached from the template molecules. The fully replicated SV40 molecules synthesized by the HeLa extracts do not contain such IRs. We propose "U-turn replication" as a novel mechanism for gene amplification, accounting for the generation of extrachromosomal inverted duplications as a result of perturbed replication and template switching of the DNA polymerases.     

Sequence requirements for protein-primed DNA replication of bacteriophage PRD1

In vitro studies have demonstrated that linear duplex, protein-free DNA molecules containing an inverted terminal repeat (ITR) sequence of the PRD1 genome at one end can undergo replication by a protein-primed mechanism. No DNA replication was observed when the ITR sequence was deleted or was not exposed at the terminus of the template DNA. We have determined the minimal origin of replication by analyzing the template activity of various deletion derivatives. Our results showed that the terminal 20 base-pairs of ITR are required for efficient in vitro DNA replication. We have found that, within the minimal replication origin region, there are complementary sequences. A site-specific mutagenesis analysis showed that most of the point mutations in the complementary sequences markedly reduced the template activity. The analyses of the results obtained with synthetic oligonucleotides have revealed that the specificity of the replication origin is strand specific and even on a single-stranded template a particular DNA sequence including a 3'-terminal C residue is required for the initiation of PRD1 DNA replication in vitro.