Chromosomal model for analysis of a long CTG/CAG tract stability in wild-type Escherichia coli and its nucleotide excision repair mutants

Many human hereditary neurological diseases, including fragile X syndrome, myotonic dystrophy, and Friedreich's ataxia, are associated with expansions of the triplet repeat sequences (TRS) (CGG/CCG, CTG/CAG, and GAA/TTC) within or near specific genes. Mechanisms that mediate mutations of TRS include DNA replication, repair, and gene conversion and (or) recombination. The involvement of the repair systems in TRS instability was investigated in Escherichia coli on plasmid models, and the results showed that the deficiency of some nucleotide excision repair (NER) functions dramatically affects the stability of long CTG inserts. In such models in which there are tens or hundreds of plasmid molecules in each bacterial cell, repetitive sequences may interact between themselves and according to a recombination hypothesis, which may lead to expansions and deletions within such repeated tracts. Since one cannot control interaction between plasmids, it is also sometimes difficult to give precise interpretation of the results. Therefore, using modified lambda phage (lambdaInCh), we have constructed a chromosomal model to study the instability of trinucleotide repeat sequences in E. coli. We have shown that the stability of (CTG/CAG)68 tracts in the bacterial chromosome is influenced by mutations in NER genes in E. coli. The absence of the uvrC or uvrD gene products greatly enhances the instability of the TRS in the chromosome, whereas the lack of the functional UvrA or UvrB proteins causes substantial stabilization of (CTG/CAG) tracts.     

A novel selectable system for detecting expansion of CAG.CTG repeats in mammalian cells

CAG.CTG repeat expansions cause more than a dozen neurodegenerative diseases in humans. To define the mechanism of repeat instability in mammalian cells we developed a selectable assay to detect expansions of CAG.CTG triplet repeats in Chinese hamster ovary (CHO) cells. We showed previously that long tracts of CAG.CTG repeats, embedded in an intron of the APRT gene, kill expression of the gene, rendering the cells APRT-. By contrast, tracts with fewer than 34 repeats allow sufficient expression to give APRT+ cells. Although it should be possible to use APRT+ cells with short repeats to assay for expansion events by selecting for APRT- cells, we find that APRT+ cells with 31 repeats are not killed by the standard APRT- selection protocol, most likely because they produce too little Aprt to incorporate sufficient 8-azaadenine into their adenine pool. To overcome this problem, we devised a new selection, which increases the proportion of the adenine pool contributed by the salvage pathway by partially inhibiting the de novo pathway. We show that APRT- CHO cells with 61 or 95 CAG.CTG repeats survive this selection, whereas cells with 31 repeats die. Using this selection system, we can select for expansion to as few as 39 repeats. Thus, this assay can monitor expansions across the critical boundary from the longest lengths of normal alleles to the shortest lengths of disease alleles.     

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.     

Long CTG.CAG repeats from myotonic dystrophy are preferred sites for intermolecular recombination

Homologous recombination was shown to enable the expansion of CTG.CAG repeat sequences. Other prior investigations revealed the involvement of replication and DNA repair in these genetic instabilities. Here we used a genetic assay to measure the frequency of homologous intermolecular recombination between two CTG.CAG tracts. When compared with non-repeating sequences of similar lengths, long (CTG.CAG)(n) repeats apparently recombine with an approximately 60-fold higher frequency. Sequence polymorphisms that interrupt the homogeneity of the CTG.CAG repeat tracts reduce the apparent recombination frequency as compared with the pure uninterrupted repeats. The orientation of the repeats relative to the origin of replication strongly influenced the apparent frequency of recombination. This suggests the involvement of DNA replication in the recombination process of triplet repeats. We propose that DNA polymerases stall within the CTG.CAG repeat tracts causing nicks or double-strand breaks that stimulate homologous recombination. The recombination process is RecA-dependent.     

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.     

SOS repair and DNA supercoiling influence the genetic stability of DNA triplet repeats in Escherichia coli

Molecular mechanisms responsible for the genetic instability of DNA trinucleotide sequences (TRS) account for at least 20 human hereditary disorders. Many aspects of DNA metabolism influence the frequency of length changes in such repeats. Herein, we demonstrate that expression of Escherichia coli SOS repair proteins dramatically decreases the genetic stability of long (CTG/CAG)n tracts contained in plasmids. Furthermore, the growth characteristics of the bacteria are affected by the (CTG/CAG)n tract, with the effect dependent on the length of the TRS. In an E. coli host strain with constitutive expression of the SOS regulon, the frequency of deletions to the repeat is substantially higher than that in a strain with no SOS response. Analyses of the topology of reporter plasmids isolated from the SOS+ and SOS- strains revealed higher levels of negative supercoiling in strains with the constitutively expressed SOS network. Hence, we used strains with mutations in topoisomerases to examine the effect of DNA topology upon the TRS instability. Higher levels of negative DNA supercoiling correlated with increased deletions in long (CTG/CAG)n, (CGG/CCG)n and (GAA/TTC)n. These observations suggest a link between the induction of bacterial SOS repair, changes in DNA topology and the mechanisms leading to genetic instability of repetitive DNA sequences.     

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.     

Hairpin structure-forming propensity of the (CCTG.CAGG) tetranucleotide repeats contributes to the genetic instability associated with myotonic dystrophy type 2

The genetic instabilities of (CCTG.CAGG)(n) tetranucleotide repeats were investigated to evaluate the molecular mechanisms responsible for the massive expansions found in myotonic dystrophy type 2 (DM2) patients. DM2 is caused by an expansion of the repeat from the normal allele of 26 to as many as 11,000 repeats. Genetic expansions and deletions were monitored in an African green monkey kidney cell culture system (COS-7 cells) as a function of the length (30, 114, or 200 repeats), orientation, or proximity of the repeat tracts to the origin (SV40) of replication. As found for CTG.CAG repeats related to DM1, the instabilities were greater for the longer tetranucleotide repeat tracts. Also, the expansions and deletions predominated when cloned in orientation II (CAGG on the leading strand template) rather than I and when cloned proximal rather than distal to the replication origin. Biochemical studies on synthetic d(CAGG)(26) and d(CCTG)(26) as models of unpaired regions of the replication fork revealed that d(CAGG)(26) has a marked propensity to adopt a defined base paired hairpin structure, whereas the complementary d(CCTG)(26) lacks this capacity. The effect of orientation described above differs from all previous results with three triplet repeat sequences (including CTG.CAG), which are also involved in the etiologies of other hereditary neurological diseases. However, similar to the triplet repeat sequences, the ability of one of the two strands to form a more stable folded structure, in our case the CAGG strand, explains this unorthodox "reversed" behavior.     

Haploinsufficiency of yeast FEN1 causes instability of expanded CAG/CTG tracts in a length-dependent manner

Trinucleotide repeat diseases, such as Huntington's disease, are caused by the expansion of trinucleotide repeats above a threshold of about 35 repeats. Once expanded, the repeats are unstable and tend to expand further both in somatic cells and during transmission, resulting in a more severe disease phenotype. Flap endonuclease 1 (Fen1), has an endonuclease activity specific for 5' flap structures and is involved in Okazaki fragment processing and base excision repair. Fen1 also plays an important role in preventing instability of CAG/CTG trinucleotide repeat sequences, as the expansion frequency of CAG/CTG repeats is increased in FEN1 mutants in vitro and in yeast cells defective for the yeast homolog, RAD27. Here we have tested whether one copy of yeast FEN1 is enough to maintain CAG/CTG tract stability in diploid yeast cells. We found that CAG/CTG repeats are stable in RAD27 +/- cells if the tract is 70 repeats long and exhibit a slightly increased expansion frequency if the tract is 85 or 130 repeats long. However for CAG-155 tracts, the repeat expansion frequency in RAD27 +/- cells is significantly higher than in RAD27 +/+ cells. This data indicates that cells containing longer CAG/CTG repeats need more Fen1 protein to maintain tract stability and that maintenance of long CAG/CTG repeats is particularly sensitive to Fen1 levels. Our results may explain the relatively small effects seen in the Huntington's disease (HD) FEN1 +/- heterozygous mice and myotonic dystrophy type 1 (DM1) FEN1 +/- heterozygous mice, and suggest that inefficient flap processing by Fen1 could play a role in the continued expansions seen in humans with trinucleotide repeat expansion diseases.     

Structure-dependent recombination hot spot activity of GAA.TTC sequences from intron 1 of the Friedreich's ataxia gene

The recombinational properties of long GAA.TTC repeating sequences were analyzed in Escherichia coli to gain further insights into the molecular mechanisms of the genetic instability of this tract as possibly related to the etiology of Friedreich's ataxia. Intramolecular and intermolecular recombination studies showed that the frequency of recombination between the GAA.TTC tracts was as much as 15 times higher than the non-repeating control sequences. Homologous, intramolecular recombination between GAA.TTC tracts and GAAGGA.TCCTTC repeats also occurred with a very high frequency (approximately 0.8%). Biochemical analyses of the recombination products demonstrated the expansions and deletions of the GAA.TTC repeats. These results, together with our previous studies on the CTG.CAG sequences, suggest that the recombinational hot spot characteristics may be a common feature of all triplet repeat sequences. Unexpectedly, we found that the recombination properties of the GAA.TTC tracts were unique, compared with CTG.CAG repeats, because they depended on the DNA secondary structure polymorphism. Increasing the length of the GAA.TTC repeats decreased the intramolecular recombination frequency between these tracts. Also, a correlation was found between the propensity of the GAA.TTC tracts to adopt the sticky DNA conformation and the inhibition of intramolecular recombination. The use of novobiocin to modulate the intracellular DNA topology, i.e. the lowering of the negative superhelical density, repressed the formation of the sticky DNA structure, thereby restoring the expected positive correlation between the length of the GAA.TTC tracts and the frequency of intramolecular recombination. Hence, our results demonstrate that sticky DNA exists and functions in E. coli.     

Structure-Forming CAG/CTG Repeat Sequences are Sensitive to Breakage in the Absence of Mrc1 Checkpoint Function and S-Phase Checkpoint Signaling: Implications for Trinucleotide Repeat Expansion Diseases

Expansion of trinucleotide repeat sequences is the cause of multiple inherited human genetic diseases including Huntington’s disease and myotonic dystrophy. CTG and CAG repeats have been shown to form stable secondary structures that can impair Okazaki fragment processing and may impede replication fork progression. We recently showed that mutation of DNA damage checkpoint proteins results in increased chromosome breaks at expanded CAG/CTG repeats and in increased repeat instability (expansions and contractions).1 Here we report that long CAG~155 tracts are especially sensitive to absence of Mrc1 (Claspin) checkpoint function, implicating the S-phase checkpoint in maintenance of trinucleotide repeats and other secondary-structure forming sequences. Based on all of our results, we propose a model for the detection of different types of structures by different checkpoint signaling pathways.     

Weak strand displacement activity enables human DNA polymerase beta to expand CAG/CTG triplet repeats at strand breaks

Using synthetic DNA constructs in vitro, we find that human DNA polymerase beta effectively catalyzes CAG/CTG triplet repeat expansions by slippage initiated at nicks or 1-base gaps within short (14 triplet) repeat tracts in DNA duplexes under physiological conditions. In the same constructs, Escherichia coli DNA polymerase I Klenow Fragment exo(-) is much less effective in expanding repeats, because its much stronger strand displacement activity inhibits slippage by enabling rapid extension through two downstream repeats into flanking non-repeat sequence. Polymerase beta expansions of CAG/CTG repeats, observed over a 32-min period at rates of approximately 1 triplet added per min, reveal significant effects of break type (nick versus gap), strand composition (CTG versus CAG), and dNTP substrate concentration, on repeat expansions at strand breaks. At physiological substrate concentrations (1-10 microm of each dNTP), polymerase beta expands triplet repeats with the help of weak strand displacement limited to the two downstream triplet repeats in our constructs. Such weak strand displacement activity in DNA repair at strand breaks may enable short tracts of repeats to be converted into longer, increasingly mutable ones associated with neurological diseases.     

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.     

Srs2 helicase of Saccharomyces cerevisiae selectively unwinds triplet repeat DNA

Trinucleotide repeat expansions are the mutational cause of at least 15 genetic diseases. In vitro, single-stranded triplet repeat DNA forms highly stable hairpins, depending on repeat sequence, and a strong correlation exists between hairpin-forming ability and the risk of expansion in vivo. Hairpins are viewed, therefore, as likely mutagenic precursors to expansions. If a helicase unwinds the hairpin, it would be less likely to expand. Previous work indicated that yeast Srs2 DNA helicase selectively blocks expansions in vivo (Bhattacharyya, S., and Lahue, R. S. (2004) Mol. Cell. Biol. 24, 7324-7330). For example, srs2 mutants, including an ATPase-defective point mutant, exhibit substantially higher expansion rates than wild type controls. In contrast, mutation of another helicase gene, SGS1, had little effect on expansion rates. These findings prompted the idea that Srs2 might selectively unwind triplet repeat hairpins. In this study, DNA helicase assays were performed with purified Srs2, Sgs1, and Escherichia coli UvrD (DNA helicase II). Srs2 shows substantially faster unwinding than Sgs1 or UvrD on partial duplex substrates containing (CTG) x (CTG) sequences, provided that Srs2 encounters the triplet repeat DNA immediately on entering the duplex. Srs2 was also faster at unwinding (CAG) x (CAG)- and (CCG) x (CCG)-containing substrates and an intramolecular (CTG) x (CTG) hairpin. In contrast, all three enzymes unwind about equally well control substrates with either Watson-Crick base pairs or mismatched substrates with non-CNG repeats. Overall, the selective unwinding activity of Srs2 on triplet repeat hairpin DNA helps explain the genetic evidence that Srs2, not the RecQ homolog Sgs1, is a preferred helicase for preventing expansions.     

A SCA7 CAG/CTG repeat expansion is stable in Drosophila melanogaster despite modulation of genomic context and gene dosage

CAG and CTG repeat expansions are the cause of at least a dozen inherited neurological disorders. In these so-called "dynamic mutation" diseases, the expanded repeats display dramatic genetic instability, changing in size when transmitted through the germline and within somatic tissues. As the molecular basis of the repeat instability process remains poorly understood, modeling of repeat instability in model organisms has provided some insights into potentially involved factors, implicating especially replication and repair pathways. Studies in mice have also shown that the genomic context of the repeat sequence is required for CAG/CTG repeat instability in the case of spinocerebellar ataxia type 7 (SCA7), one of the most unstable of all CAG/CTG repeat disease loci. While most studies of repeat instability have taken a candidate gene approach, unbiased screens for factors involved in trinucleotide repeat instability have been lacking. We therefore attempted to use Drosophila melanogaster to model expanded CAG repeat instability by creating transgenic flies carrying trinucleotide repeat expansions, deriving flies with SCA7 CAG90 repeats in cDNA and genomic context. We found that SCA7 CAG90 repeats are stable in Drosophila, regardless of context. To screen for genes whose reduced function might destabilize expanded CAG repeat tracts in Drosophila, we crossed the SCA7 CAG90 repeat flies with various deficiency stocks, including lines lacking genes encoding the orthologues of flap endonuclease-1, PCNA, and MutS. In all cases, perfect repeat stability was preserved, suggesting that Drosophila may not be a suitable system for determining the molecular basis of SCA7 CAG repeat instability.     

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.