Two opposing effects of mismatch repair on CTG repeat instability in Escherichia coli

The Startling Role of Mismatch Repair in Trinucleotide Repeat Expansions

Trinucleotide repeats are a peculiar class of microsatellites whose expansions are responsible for approximately 30 human neurological or developmental disorders. The molecular mechanisms responsible for these expansions in humans are not totally understood, but experiments in model systems such as yeast, transgenic mice, and human cells have brought evidence that the mismatch repair machinery is involved in generating these expansions. The present review summarizes, in the first part, the role of mismatch repair in detecting and fixing the DNA strand slippage occurring during microsatellite replication. In the second part, key molecular differences between normal microsatellites and those that show a bias toward expansions are extensively presented. The effect of mismatch repair mutants on microsatellite expansions is detailed in model systems, and in vitro experiments on mismatched DNA substrates are described. Finally, a model presenting the possible roles of the mismatch repair machinery in microsatellite expansions is proposed.

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.

DNA triplet repeat expansion and mismatch repair

DNA mismatch repair is a conserved antimutagenic pathway that maintains genomic stability through rectification of DNA replication errors and attenuation of chromosomal rearrangements. Paradoxically, mutagenic action of mismatch repair has been implicated as a cause of triplet repeat expansions that cause neurological diseases such as Huntington disease and myotonic dystrophy. This mutagenic process requires the mismatch recognition factor MutSβ and the MutLα (and/or possibly MutLγ) endonuclease, and is thought to be triggered by the transient formation of unusual DNA structures within the expanded triplet repeat element. This review summarizes the current knowledge of DNA mismatch repair involvement in triplet repeat expansion, which encompasses in vitro biochemical findings, cellular studies, and various in vivo transgenic animal model experiments. We present current mechanistic hypotheses regarding mismatch repair protein function in mediating triplet repeat expansions and discuss potential therapeutic approaches targeting the mismatch repair pathway.

Inhibition of DNA synthesis facilitates expansion of low-complexity repeats: is strand slippage stimulated by transient local depletion of specific dNTPs?

Simple DNA repeats (trinucleotide repeats, micro- and minisatellites) are prone to expansion/contraction via formation of secondary structures during DNA synthesis. Such structures both inhibit replication forks and create opportunities for template-primer slippage, making these repeats unstable. Certain aspects of simple repeat instability, however, suggest additional mechanisms of replication inhibition dependent on the primary DNA sequence, rather than on secondary structure formation. I argue that expanded simple repeats, due to their lower DNA complexity, should transiently inhibit DNA synthesis by locally depleting specific DNA precursors. Such transient inhibition would promote formation of secondary structures and would stabilize these structures, facilitating strand slippage. Thus, replication problems at simple repeats could be explained by potentiated toxicity, where the secondary structure-driven repeat instability is enhanced by DNA polymerase stalling at the low complexity template DNA.

DNA tandem repeat instability in the Escherichia coli chromosome is stimulated by mismatch repair at an adjacent CAG·CTG trinucleotide repeat

Approximately half the human genome is composed of repetitive DNA sequences classified into microsatellites, minisatellites, tandem repeats, and dispersed repeats. These repetitive sequences have coevolved within the genome but little is known about their potential interactions. Trinucleotide repeats (TNRs) are a subclass of microsatellites that are implicated in human disease. Expansion of CAG·CTG TNRs is responsible for Huntington disease, myotonic dystrophy, and a number of spinocerebellar ataxias. In yeast DNA double-strand break (DSB) formation has been proposed to be associated with instability and chromosome fragility at these sites and replication fork reversal (RFR) to be involved either in promoting or in preventing instability. However, the molecular basis for chromosome fragility of repetitive DNA remains poorly understood. Here we show that a CAG·CTG TNR array stimulates instability at a 275-bp tandem repeat located 6.3 kb away on the Escherichia coli chromosome. Remarkably, this stimulation is independent of both DNA double-strand break repair (DSBR) and RFR but is dependent on a functional mismatch repair (MMR) system. Our results provide a demonstration, in a simple model system, that MMR at one type of repetitive DNA has the potential to influence the stability of another. Furthermore, the mechanism of this stimulation places a limit on the universality of DSBR or RFR models of instability and chromosome fragility at CAG·CTG TNR sequences. Instead, our data suggest that explanations of chromosome fragility should encompass the possibility of chromosome gaps formed during MMR.

Diverse effects of individual mismatch repair components on transcription-induced CAG repeat instability in human cells

Several neurodegerative diseases are caused by expansion of a trinucleotide repeat tract in a critical gene. The mechanism of repeat instability is not yet defined, but in mice it requires MutSbeta, a complex of MSH2 and MSH3. We showed previously that transcription through a CAG repeat tract induces repeat instability in human cells via a pathway that requires the mismatch repair (MMR) components, MSH2 and MSH3, and the entire transcription-coupled nucleotide excision repair pathway [Y. Lin, V. Dion, J.H. Wilson, Transcription promotes contraction of CAG repeat tracts in human cells, Nat. Struct. Mol. Biol. 13 (2006) 179-180; Y. Lin, J.H. Wilson, Transcription-induced CAG repeat contraction in human cells is mediated in part by transcription-coupled nucleotide excision repair, Mol. Cell Biol. 27 (2007) 6209-6217]. Here, we examine the role of downstream MMR processing components on transcription-induced CAG instability, using our selection assay for repeat contraction. In contrast to knockdowns of MSH2 or MSH3, which reduce repeat contractions, we show that siRNA-mediated depletion of MLH1 or PMS2 increases contraction frequency. Knockdown of DNMT1, which has been identified as an MMR factor in genetic studies, also elevates the frequency of contraction. Simultaneous knockdowns of MLH1 or DNMT1 along with MSH2, XPA, or BRCA1, whose individual knockdowns each decrease CAG contraction, yield intermediate frequencies. In sharp contrast, double knockdown of MLH1 and DNMT1 additively increases the frequency of CAG contraction. These results show that MMR components can alter repeat stability in diverse ways, either enhancing or suppressing CAG contraction, and they provide insight into the influence of MMR components on transcription-induced CAG repeat instability.

E. coli mismatch repair acts downstream of replication fork stalling to stabilize the expanded (GAA.TTC)(n) sequence

Expanded triplet repeat sequences are known to cause at least 16 inherited neuromuscular diseases. In addition to short-length changes, expanded triplet repeat tracts frequently undergo large changes, often amounting to hundreds of base-pairs. Such changes might occur when template or primer slipping creates insertion/deletion loops (IDLs), which are normally repaired by the mismatch repair system (MMR). However, in prokaryotes and eukaryotes, MMR promotes large changes in the length of (CTG.CAG)(n) sequences, the motif most commonly associated with human disease. We tested the effect of MMR on instability of the expanded (GAA.TTC)(n) sequence, which causes Friedreich ataxia, by comparing repeat instability in wild-type and MMR-deficient strains of Escherichia coli. As expected, the prevalence of small mutations increased in the MMR-deficient strains. However, the prevalence of large contractions increased in the MMR mutants specifically when GAA was the lagging strand template, the orientation in which replication fork stalling is known to occur. After hydroxyurea-induced stalling, both orientations of replication showed significantly more large contractions in MMR mutants than in the wild-type, suggesting that fork stalling may be responsible for the large contractions. Deficiency of MMR promoted large contractions independently of RecA status, a known determinant of (GAA.TTC)(n) instability. These data suggest that two independent mechanisms act in response to replication stalling to prevent instability of the (GAA.TTC)(n) sequence in E. coli, when GAA serves as the lagging strand template: one that is dependent on RecA-mediated restart of stalled forks, and another that is dependent on MMR-mediated repair of IDLs. While MMR destabilizes the (CTG.CAG)(n) sequence, it is involved in stabilization of the (GAA.TTC)(n) sequence. The role of MMR in triplet repeat instability therefore depends on the repeat sequence and the orientation of replication.

Chromosome fragility at GAA tracts in yeast depends on repeat orientation and requires mismatch repair

Expansion of triplex-forming GAA/TTC repeats in the first intron of FXN gene results in Friedreich's ataxia. Besides FXN, there are a number of other polymorphic GAA/TTC loci in the human genome where the size variations thus far have been considered to be a neutral event. Using yeast as a model system, we demonstrate that expanded GAA/TTC repeats represent a threat to eukaryotic genome integrity by triggering double-strand breaks and gross chromosomal rearrangements. The fragility potential strongly depends on the length of the tracts and orientation of the repeats relative to the replication origin, which correlates with their propensity to adopt triplex structure and to block replication progression. We show that fragility is mediated by mismatch repair machinery and requires the MutSbeta and endonuclease activity of MutLalpha. We suggest that the mechanism of GAA/TTC-induced chromosomal aberrations defined in yeast can also operate in human carriers with expanded tracts.

ATR protects the genome against CGG.CCG-repeat expansion in Fragile X premutation mice

Fragile X mental retardation syndrome is a repeat expansion disease caused by expansion of a CGG.CCG-repeat tract in the 5' UTR of the FMR1 gene. In humans, small expansions occur more frequently on paternal transmission while large expansions are exclusively maternal in origin. It has been suggested that expansion is the result of aberrant DNA replication, repair or recombination. To distinguish amongst these possibilities we crossed mice containing 120 CGG.CCG-repeats in the 5' UTR of the mouse Fmr1 gene to mice with mutations in ATR, a protein important in the cellular response to stalled replication forks and bulky DNA lesions. We show here that ATR heterozygosity results in increased expansion rates of maternally, but not paternally, transmitted alleles. In addition, age-related somatic expansions occurred in mice of both genders that were not seen in ATR wild-type animals. Some ATR-sensitive expansion occurs in postmitotic cells including haploid gametes suggesting that aberrant DNA repair is responsible. Our data suggest that two mechanisms of repeat expansion exist that may explain the small and large expansions seen in humans. In addition, our data provide an explanation for the maternal bias of large expansions in humans and the lower incidence of these expansions in mice.

Proofreading and secondary structure processing determine the orientation dependence of CAG x CTG trinucleotide repeat instability in Escherichia coli

Expanded CAG x CTG trinucleotide repeat tracts are associated with several human inherited diseases, including Huntington's disease, myotonic dystrophy, and spinocerebellar ataxias. Here we describe a new model system to investigate repeat instability in the Escherichia coli chromosome. Using this system, we reveal patterns of deletion instability consistent with secondary structure formation in vivo and address the molecular basis of orientation-dependent instability. We demonstrate that the orientation dependence of CAG x CTG trinucleotide repeat deletion is determined by the proofreading subunit of DNA polymerase III (DnaQ) in the presence of the hairpin nuclease SbcCD (Rad50/Mre11). Our results suggest that, although initiation of slippage can occur independently of CAG x CTG orientation, the folding of the intermediate affects its processing and this results in orientation dependence. We propose that proofreading is inefficient on the CTG-containing strand because of its ability to misfold and that SbcCD contributes to processing in a manner that is dependent on proofreading and repeat tract orientation. Furthermore, we demonstrate that transcription and recombination do not influence instability in this system.

Mechanisms of tandem repeat instability in bacteria

Hypermutable tandem repeat sequences (TRSs) are present in the genomes of both prokaryotic and eukaryotic organisms. Numerous studies have been conducted in several laboratories over the past decade to investigate the mechanisms responsible for expansions and contractions of microsatellites (a subset of TRSs with a repeat length of 1-6 nucleotides) in the model prokaryotic organism Escherichia coli. Both the frequency of tandem repeat instability (TRI), and the types of mutational events that arise, are markedly influenced by the DNA sequence of the repeat, the number of unit repeats, and the types of cellular pathways that process the TRS. DNA strand slippage is a general mechanism invoked to explain instability in TRSs. Misaligned DNA sequences are stabilized both by favorable base pairing of complementary sequences and by the propensity of TRSs to form relatively stable secondary structures. Several cellular processes, including replication, recombination and a variety of DNA repair pathways, have been shown to interact with such structures and influence TRI in bacteria. This paper provides an overview of our current understanding of mechanisms responsible for TRI in bacteria, with an emphasis on studies that have been carried out in E. coli. In addition, new experimental data are presented, suggesting that TLS polymerases (PolII, PolIV and PolV) do not contribute significantly to TRI in E. coli.

Chemical modifiers of unstable expanded simple sequence repeats: what goes up, could come down

A mounting number of inherited human disorders, including Huntington disease, myotonic dystrophy, fragile X syndrome, Friedreich ataxia and several spinocerebellar ataxias, have been associated with the expansion of unstable simple sequence DNA repeats. Despite a similar genetic basis, pathogenesis in these disorders is mediated by a variety of both loss and gain of function pathways. Thus, therapies targeted at downstream pathology are likely to be disease specific. Characteristically, disease-associated expanded alleles in these disorders are highly unstable in the germline and somatic cells, with a tendency towards further expansion. Whereas germline expansion accounts for the phenomenon of anticipation, tissue-specific, age-dependent somatic expansion may contribute towards the tissue-specificity and progressive nature of the symptoms. Thus, somatic expansion presents as a novel therapeutic target in these disorders. Suppression of somatic expansion should be therapeutically beneficial, whilst reductions in repeat length could be curative. It is well established that both cis- and trans-acting genetic modifiers play key roles in the control of repeat dynamics. Importantly, recent data have revealed that expanded CAG.CTG repeats are also sensitive to a variety of trans-acting chemical modifiers. These data provide an exciting proof of principle that drug induced suppression of somatic expansion might indeed be feasible. Moreover, as our understanding of the mechanism of expansion is refined more rational approaches to chemical intervention in the expansion pathway can be envisioned. For instance, the demonstration that expansion of CAG.CTG repeats is dependent on the Msh2, Msh3 and Pms2 genes, highlights components of the DNA mismatch repair pathway as therapeutic targets. In addition to potential therapeutic applications, the response of expanded simple repeats to genotoxic assault suggests such sequences could also have utility as bio-monitors of environmentally induced genetic damage in the soma.

Mechanism of trinucleotide repeats instabilities: the necessities of repeat non-B secondary structure formation and the roles of cellular trans-acting factors

The mechanism underlying CAG.CTG CGG.CCG and GAA.TTC trinucleotide repeats expansion and contraction instabilities has not been clearly understood. Investigations in vitro have demonstrated that the disease causing repeats are capable of adopting non-B secondary structures that mediate repeats expansion. However, in vivo, similar observations have not been easily made so far. Investigations on the non-B secondary structure formation using E.coli, yeast etc cannot simulate the suggested repeats expansion instability. These could leave a space to infer a disassociation of the suggested repeats non-B secondary structure formation and the repeats expansion in vivo. Although longer trinucleotide repeats may be theoretically easier to form non-B DNA secondary structures in replication or in post-replication, however such non-B secondary structures are likely to cause repeat fragility rather than repeat expansion. In fact, repeat expansion as seen in patients may not necessarily require trinucleotide repeats to form non-B secondary structures, instead the repeat expansions can be produced through a RNA transcription-stimulated local repeat DNA replication and a subsequent DNA rearrangement.

Repeat instability: mechanisms of dynamic mutations

Disease-causing repeat instability is an important and unique form of mutation that is linked to more than 40 neurological, neurodegenerative and neuromuscular disorders. DNA repeat expansion mutations are dynamic and ongoing within tissues and across generations. The patterns of inherited and tissue-specific instability are determined by both gene-specific cis-elements and trans-acting DNA metabolic proteins. Repeat instability probably involves the formation of unusual DNA structures during DNA replication, repair and recombination. Experimental advances towards explaining the mechanisms of repeat instability have broadened our understanding of this mutational process. They have revealed surprising ways in which metabolic pathways can drive or protect from repeat instability.

Roles of double-strand breaks, nicks, and gaps in stimulating deletions of CTG.CAG repeats by intramolecular DNA repair

A series of plasmids harboring CTG.CAG repeats with double-strand breaks (DSB), single-strand nicks, or single-strand gaps (15 or 30 nucleotides) within the repeat regions were used to determine their capacity to induce genetic instabilities. These plasmids were introduced into Escherichia coli in the presence of a second plasmid containing a sequence that could support homologous recombination repair between the two plasmids. The transfer of a point mutation from the second to the first plasmid was used to monitor homologous recombination (gene conversion). Only DSBs increased the overall genetic instability. This instability took place by intramolecular repair, which was not dependent on RuvA. Double-strand break-induced instabilities were partially stabilized by a mutation in recF. Gaps of 30 nt formed a distinct 30 nt deletion product, whereas single strand nicks and gaps of 15 nt did not induce expansions or deletions. Formation of this deletion product required the CTG.CAG repeats to be present in the single-stranded region and was stimulated by E.coli DNA ligase, but was not dependent upon the RecFOR pathway. Models are presented to explain the intramolecular repair-induced instabilities and the formation of the 30 nt deletion product.

Advances in mechanisms of genetic instability related to hereditary neurological diseases

Substantial progress has been realized in the past several years in our understanding of the molecular mechanisms responsible for the expansions and deletions (genetic instabilities) of repeating tri-, tetra- and pentanucleotide repeating sequences associated with a number of hereditary neurological diseases. These instabilities occur by replication, recombination and repair processes, probably acting in concert, due to slippage of the DNA complementary strands relative to each other. The biophysical properties of the folded-back repeating sequence strands play a critical role in these instabilities. Non-B DNA structural elements (hairpins and slipped structures, DNA unwinding elements, tetraplexes, triplexes and sticky DNA) are described. The replication mechanisms are influenced by pausing of the replication fork, orientation of the repeat strands, location of the repeat sequences relative to replication origins and the flap endonuclease. Methyl-directed mismatch repair, nucleotide excision repair, and repair of damage caused by mutagens are discussed. Genetic recombination and double-strand break repair advances in Escherichia coli, yeast and mammalian models are reviewed. Furthermore, the newly discovered capacities of certain triplet repeat sequences to cause gross chromosomal rearrangements are discussed.

Generation of long tracts of disease-associated DNA repeats

The generation of long uninterrupted DNA repeats is important for the study of repeat instability associated with several human genetic diseases, including myotonic dystrophy type 1. However, obtaining defined lengths of long repeats in vitro has been problematic. Strand slippage and/or DNA secondary structure formation may prevent efficient ligation. For example, a purified (CTG)140•(CAG)140 repeat fragment containing 4-bp AGCA/TGCT overhanging ends ligated poorly using T4 or Escherichia coli DNA ligase, although limited repeat ligation occurred using thermostable DNA ligase. Here we describe a general procedure for ligating multimers of DNA repeats. Multimers are efficiently ligated when slippage is prevented or when DNA repeats contain a single G/C overhang. A vector is designed from which pure repeat fragments containing a G/C overhang can be generated for further ligation. (CAG)n•(CTG)n DNA molecules longer than 800 bp were generated using this approach. This approach also worked for (GAA)n•(TTC)n, (CCTG)n•(CAGG)n, and (ATTCT)n•(AGAAT)n tracts associated with Friedreich ataxia, DM2, and spinocerebellar ataxia type 10, respectively.

Genetic recombination destabilizes (CTG)n.(CAG)n repeats in E. coli

The expansion of trinucleotide repeats has been implicated in 17 neurological diseases to date. Factors leading to the instability of trinucleotide repeat sequences have thus been an area of intense interest. Certain genes involved in mismatch repair, recombination, nucleotide excision repair, and replication influence the instability of trinucleotide repeats in both Escherichia coli and yeast. Using a genetic assay for repeat deletion in E. coli, the effect of mutations in the recA, recB, and lexA genes on the rate of deletion of (CTG)n.(CAG)n repeats of varying lengths were examined. The results indicate that mutations in recA and recB, which decrease the rate of recombination, had a stabilizing effect on (CAG)n.(CTG)n repeats decreasing the high rates of deletion seen in recombination proficient cells. Thus, recombination proficiency correlates with high rates of genetic instability in triplet repeats. Induction of the SOS system, however, did not appear to play a significant role in repeat instability, nor did the presence of triplet repeats in cells turn on the SOS response. A model is suggested where deletion during exponential growth may result from attempts to restart replication when paused at triplet repeats.

Somatic deletion events occur during early embryonic development and modify the extent of CAG expansion in subsequent generations

Alterations in trinucleotide repeat length during transmission are important in the pathophysiology of Huntington's disease (HD). However, it is not well understood where, when and by what mechanism expansion occurs. We have followed the fate of CAG repeats during development in mice that can [hHD(-/+)/Msh2(+/+)] or cannot [hHD(-/+)/Msh2(-/-)] expand their repeats. Here we show that long repeats are shortened during somatic replication early in the embryo of the progeny. Our data point to different mechanisms for expansion and deletion. Deletions arise during replication, do not depend on the presence of Msh2 and are largely restricted to early development. In contrast, expansions depend on strand break repair, require the presence of Msh2 and occur later in development. Overall, these results suggest that deletions in early development serve as a safeguard of the genome and protect against expansion of the disease-range repeats during transmission.

Trinucleotide repeat instability: a hairpin curve at the crossroads of replication, recombination, and repair

The trinucleotide repeats that expand to cause human disease form hairpin structures in vitro that are proposed to be the major source of their genetic instability in vivo. If a replication fork is a train speeding along a track of double-stranded DNA, the trinucleotide repeats are a hairpin curve in the track. Experiments have demonstrated that the train can become derailed at the hairpin curve, resulting in significant damage to the track. Repair of the track often results in contractions and expansions of track length. In this review we introduce the in vitro evidence for why CTG/CAG and CCG/CGG repeats are inherently unstable and discuss how experiments in model organisms have implicated the replication, recombination and repair machinery as contributors to trinucleotide repeat instability in vivo.

Selectable system for monitoring the instability of CTG/CAG triplet repeats in mammalian cells

Despite substantial progress in understanding the mechanism by which expanded CTG/CAG trinucleotide repeats cause neurodegenerative diseases, little is known about the basis for repeat instability itself. By taking advantage of a novel phenomenon, we have developed a selectable assay to detect contractions of CTG/CAG triplets. When inserted into an intron in the APRT gene or the HPRT minigene, long tracts of CTG/CAG repeats (more than about 33 repeat units) are efficiently incorporated into mRNA as a new exon, thereby rendering the encoded protein nonfunctional, whereas short repeat tracts do not affect the phenotype. Therefore, contractions of long repeats can be monitored in large cell populations, by selecting for HPRT(+) or APRT(+) clones. Using this selectable system, we determined the frequency of spontaneous contractions and showed that treatments with DNA-damaging agents stimulate repeat contractions. The selectable system that we have developed provides a versatile tool for the analysis of CTG/CAG repeat instability in mammalian cells. We also discuss how the effect of long CTG/CAG repeat tracts on splicing may contribute to the progression of polyglutamine diseases.

Long CTG tracts from the myotonic dystrophy gene induce deletions and rearrangements during recombination at the APRT locus in CHO cells

Expansion of CTG triplet repeats in the 3' untranslated region of the DMPK gene causes the autosomal dominant disorder myotonic dystrophy. Instability of CTG repeats is thought to arise from their capacity to form hairpin DNA structures. How these structures interact with various aspects of DNA metabolism has been studied intensely for Escherichia coli and Saccharomyces cerevisiae but is relatively uncharacterized in mammalian cells. To examine the stability of (CTG)(17), (CTG)(98), and (CTG)(183) repeats during homologous recombination, we placed them in the second intron of one copy of a tandemly duplicated pair of APRT genes. Cells selected for homologous recombination between the two copies of the APRT gene displayed distinctive patterns of change. Among recombinants from cells with (CTG)(98) and (CTG)(183), 5% had lost large numbers of repeats and 10% had suffered rearrangements, a frequency more than 50-fold above normal levels. Analysis of individual rearrangements confirmed the involvement of the CTG repeats. Similar changes were not observed in proliferating (CTG)(98) and (CTG)(183) cells that were not recombinant at APRT. Instead, they displayed high frequencies of small changes in repeat number. The (CTG)(17) repeats were stable in all assays. These studies indicate that homologous recombination strongly destabilizes long tracts of CTG repeats.

Replication and expansion of trinucleotide repeats in yeast

The mechanisms of trinucleotide repeat expansions, underlying more than a dozen hereditary neurological disorders, are yet to be understood. Here we looked at the replication of (CGG)(n) x (CCG)(n) and (CAG)(n) x (CTG)(n) repeats and their propensity to expand in Saccharomyces cerevisiae. Using electrophoretic analysis of replication intermediates, we found that (CGG)(n) x (CCG)(n) repeats significantly attenuate replication fork progression. Replication inhibition for this sequence becomes evident at as few as approximately 10 repeats and reaches a maximal level at 30 to 40 repeats. This is the first direct demonstration of replication attenuation by a triplet repeat in a eukaryotic system in vivo. For (CAG)(n) x (CTG)(n) repeats, on the contrary, there is only a marginal replication inhibition even at 80 repeats. The propensity of trinucleotide repeats to expand was evaluated in a parallel genetic study. In wild-type cells, expansions of (CGG)(25) x (CCG)(25) and (CAG)(25) x (CTG)(25) repeat tracts occurred with similar low rates. A mutation in the large subunit of the replicative replication factor C complex (rfc1-1) increased the expansion rate for the (CGG)(25) repeat approximately 50-fold but had a much smaller effect on the expansion of the (CTG)(25) repeat. These data show dramatic sequence-specific expansion effects due to a mutation in the lagging strand DNA synthesis machinery. Together, the results of this study suggest that expansions are likely to result when the replication fork attempts to escape from the stall site.

Identification of RTG2 as a modifier gene for CTG*CAG repeat instability in Saccharomyces cerevisiae

Trinucleotide repeats (TNRs) undergo frequent mutations in families affected by TNR diseases and in model organisms. Much of the instability is conferred in cis by the sequence and length of the triplet tract. Trans-acting factors also modulate TNR instability risk, on the basis of such evidence as parent-of-origin effects. To help identify trans-acting modifiers, a screen was performed to find yeast mutants with altered CTG.CAG repeat mutation frequencies. The RTG2 gene was identified as one such modifier. In rtg2 mutants, expansions of CTG.CAG repeats show a modest increase in rate, depending on the starting tract length. Surprisingly, contractions were suppressed in an rtg2 background. This creates a situation in a model system where expansions outnumber contractions, as in humans. The rtg2 phenotype was apparently specific for CTG.CAG repeat instability, since no changes in mutation rate were observed for dinucleotide repeats or at the CAN1 reporter gene. This feature sets rtg2 mutants apart from most other mutants that affect genetic stability both for TNRs and at other DNA sequences. It was also found that RTG2 acts independently of its normal partners RTG1 and RTG3, suggesting a novel function of RTG2 that helps modify CTG.CAG repeat mutation risk.

Genetic assays for measuring rates of (CAG).(CTG) repeat instability in Escherichia coli

Genetic selection assays were developed to measure rates of deletion of one or more (CAG).(CTG) repeats, or an entire repeat tract, in Escherichia coli. In-frame insertions of >or=25 repeats in the chloramphenicol acetyltransferase (CAT) gene of pBR325 resulted in a chloramphenicol-sensitive (Cm(s)) phenotype. When (CAG)25 comprised the leading template strand, deletion of one or more repeats resulted in a chloramphenicol resistant (Cm(r)) phenotype at a rate of 4 x 10(-2) revertants per cell per generation. The mutation rates for plasmids containing (CAG)43 or (CAG)79 decreased significantly. When (CTG)n comprised the leading template strand the Cm(r) mutation rates were 100-1000 lower than for the opposite orientation. As an initial application of this assay, the effects of mutations influencing mismatch repair and recombination were examined. The methyl directed mismatch repair system increased repeat stability only when (CTG)n comprised the leading template strand. Replication errors made with the opposite repeat orientation were apparently not recognized. For the (CAG)n leading strand orientation, mutation rates were reduced as much as 3000-fold in a recA- strain. In a second assay, out-of-frame mutation inserts underwent complete deletion at rates ranging from about 5 x 10(-9) to 1 x 10(-7) per cell per generation. These assays allow careful quantitation of triplet repeat instability in E. coli and provide a way to examine the effects of mutations in replication, repair, and recombination on repeat instability.

Involvement of the nucleotide excision repair protein UvrA in instability of CAG*CTG repeat sequences in Escherichia coli

Several human genetic diseases have been associated with the genetic instability, specifically expansion, of trinucleotide repeat sequences such as (CTG)(n).(CAG)(n). Molecular models of repeat instability imply replication slippage and the formation of loops and imperfect hairpins in single strands. Subsequently, these loops or hairpins may be recognized and processed by DNA repair systems. To evaluate the potential role of nucleotide excision repair in repeat instability, we measured the rates of repeat deletion in wild type and excision repair-deficient Escherichia coli strains (using a genetic assay for deletions). The rate of triplet repeat deletion decreased in an E. coli strain deficient in the damage recognition protein UvrA. Moreover, loops containing 23 CTG repeats were less efficiently excised from heteroduplex plasmids after their transformation into the uvrA(-) strain. As a result, an increased proportion of plasmids containing the full-length repeat were recovered after the replication of heteroduplex plasmids containing unrepaired loops. In biochemical experiments, UvrA bound to heteroduplex substrates containing repeat loops of 1, 2, or 17 CAG repeats with a K(d) of about 10-20 nm, which is an affinity about 2 orders of magnitude higher than that of UvrA bound to the control substrates containing (CTG)(n).(CAG)(n) in the linear form. These results suggest that UvrA is involved in triplet repeat instability in cells. Specifically, UvrA may bind to loops formed during replication slippage or in slipped strand DNA and initiate DNA repair events that result in repeat deletion. These results imply a more comprehensive role for UvrA, in addition to the recognition of DNA damage, in maintaining the integrity of the genome.

Modulation of transcription reveals a new mechanism of triplet repeat instability in Escherichia coli

Many human hereditary disease genes are associated with the expansion of triplet repeat sequences. In Escherichia coli (CTG/CAG) triplet repeat sequences are unstable and we have developed a plasmid-based assay enabling us to observe and quantify both expansions and deletions. In this work, we have investigated the role of transcription on the instability of a (CTG/CAG) insert containing 64 repeats. Using this assay, we show that induction of transcription results in a significant increase in the frequency of long deletions and a reduction in the frequency of long expansions. On the other hand, overproduction of transcription repressor molecules leads to an increase in both expansions and deletions. In this latter case, we propose that the increased instability is due to the arrest of replication progression by the interaction of the repressor molecule with its cognate operator and subsequent generations of DNA strand breaks.

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 TGG(24) 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 TGG(24) on the lagging-strand template. These findings suggest that TGG(24) can fold into a structure that can interfere with DNA replication in vivo but that TGG(15) 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.