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.     

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 cloning 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.     

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.     

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.     

Chromatin remodeling in the noncoding repeat expansion diseases

Friedreich ataxia, myotonic dystrophy type 1 and 3 forms of intellectual disability, fragile X syndrome, FRAXE mental retardation, and FRA12A mental retardation are repeat expansion diseases caused by expansion of CTG.CAG, GAA.TTC, or CGG.CCG repeat tracts. These repeats are transcribed but not translated. They are located in different parts of different genes and cause symptoms that range from ataxia and hypertrophic cardiomyopathy to muscle wasting, male infertility, and mental retardation, yet recent reports suggest that, despite these differences, the repeats may share a common property, namely the ability to initiate repeat-mediated epigenetic changes that result in heterochromatin formation.     

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.     

Long CTG.CAG repeat sequences markedly stimulate intramolecular recombination

Previous studies have shown that homologous recombination is a powerful mechanism for generation of massive instabilities of the myotonic dystrophy CTG.CAG sequences. However, the frequency of recombination between the CTG.CAG tracts has not been studied. Here we performed a systematic study on the frequency of recombination between these sequences using a genetic assay based on an intramolecular plasmid system in Escherichia coli. The rate of intramolecular recombination between long CTG.CAG tracts oriented as direct repeats was extraordinarily high; recombinants were found with a frequency exceeding 12%. Recombination occurred in both RecA(+) and RecA(-) cells but was approximately 2-11 times higher in the recombination proficient strain. Long CTG.CAG tracts recombined approximately 10 times more efficiently than non-repeating control sequences of similar length. The recombination frequency was 60-fold higher for a pair of (CTG.CAG)(165) tracts compared with a pair of (CTG.CAG)(17) sequences. The CTG.CAG sequences in orientation II (CTG repeats present on a lagging strand template) recombine approximately 2-4 times more efficiently than tracts of identical length in the opposite orientation relative to the origin of replication. This orientation effect implies the involvement of DNA replication in the intramolecular recombination between CTG.CAG sequences. Thus, long CTG.CAG tracts are hot spots for genetic recombination.     

Genetic instabilities of triplet repeat sequences by recombination

The expansion of triplet repeat sequences is an initial step in the disease etiology of a number of hereditary neurological disorders in humans. Diseases such as myotonic dystrophy, Huntington's, several spinocerebellar ataxias, fragile X syndrome, and Friedreich's ataxia are caused by the expansions of CTG.CAG, CGG.CCG, or GAA.TTC repeats. The mechanisms of the expansion process have been investigated intensely in E. coli, yeast, transgenic mice, mammalian cell culture, and in human clinical cases. Whereas studies from 1994-1999 have implicated DNA replication and repair at the paused synthesis sites due to the unusual conformations of the triplet repeat sequences, recent work has shown that homologous recombination (gene conversion) is a powerful mechanism for generating massive expansions, in addition to, or in concert with, replication and repair.     

Unexpected formation of parallel duplex in GAA and TTC trinucleotide repeats of Friedreich's ataxia

The onset and progress of Friedreich's ataxia (FRDA) is associated with the genetic instability of the (GAA).(TTC) trinucleotide repeats located within the frataxin gene. The instability of these repeats may involve the formation of an alternative DNA structure. Poly-purine (R)/poly-pyrimidine (Y) sequences typically form triplex DNA structures which may contribute to genetic instability. Conventional wisdom suggested that triplex structures formed by these poly-purine (R)/poly-pyrimidine (Y) sequences may contribute to their genetic instability. Here, we report the characterization of the single-stranded GAA and TTC sequences and their mixtures using NMR, UV-melting, and gel electrophoresis, as well as chemical and enzymatic probing methods. We show that the FRDA GAA/TTC, repeats are capable of forming various alternative structures. The most intriguing is the observation of a parallel (GAA).(TTC) duplex in equilibrium with the antiparallel Watson-Crick (GAA).(TTC) duplex. We also show that the GAA strands form self-assembled structures, whereas the TTC strands are essentially unstructured. Finally, we demonstrate that the FRDA repeats form only the YRY triplex (but not the RRY triplex) at neutral pH and the complete formation of the YRY triplex requires the ratio of GAA to TTC strand larger than 1:2. The structural features presented here and in other studies distinguish the FRDA (GAA)?(TTC) repeats from the fragile X (CGG).CCG), myotonic dystrophy (CTG).(CAG) and the Huntington (CAG).(CTG) repeats.     

DM2 CCTG*CAGG repeats are crossover hotspots that are more prone to expansions than the DM1 CTG*CAG repeats in Escherichia coli

Myotonic dystrophy type 2 (DM2) is caused by the extreme expansion of the repeating tetranucleotide CCTG*CAGG sequence from <30 repeats in normal individuals to approximately 11,000 for the full mutation in certain patients. This repeat is in intron 1 of the zinc finger protein 9 gene on chromosome 3q21. Since prior work demonstrated that CTG*CAG and GAA*TTC triplet repeats (responsible for DM1 and Friedreich's ataxia, respectively) can expand by genetic recombination, we investigated the capacity of the DM2 tetranucleotide repeats to also expand during this process. Both gene conversion and unequal crossing over are attractive mechanisms to effect these very large expansions. (CCTG*CAGG)n (where n=30, 75, 114 or 160) repeats showed high recombination crossover frequencies (up to 27-fold higher than the non-repeating control) in an intramolecular plasmid system in Escherichia coli. Furthermore, a distinct orientation effect was observed where orientation II (CAGG on the leading strand template) was more prone to recombine. Expansions of up to double the length of the tetranucleotide repeats were found. Also, the repeating tetranucleotide sequence was more prone to expansions (to give lengths longer than a single repeating tract) than deletions as observed for the CTG*CAG and GAA*TTC repeats. We determined that the DM2 tetranucleotide repeats showed a lower thermodynamic stability when compared to the DM1 trinucleotide repeats, which could make them better targets for DNA repair events, thus explaining their expansion-prone behavior. Genetic studies in SOS-repair mutants revealed high frequencies of recombination crossovers although the SOS-response itself was not induced. Thus, the genetic instabilities of the CCTG*CAGG repeats may be mediated by a recombination-repair mechanism that is influenced by DNA structure.     

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.     

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.     

Non-B DNA conformations formed by long repeating tracts of myotonic dystrophy type 1, myotonic dystrophy type 2, and Friedreich's ataxia genes, not the sequences per se, promote mutagenesis in flanking regions

The expansions of long repeating tracts of CTG.CAG, CCTG.CAGG, and GAA.TTC are integral to the etiology of myotonic dystrophy type 1 (DM1), myotonic dystrophy type 2 (DM2), and Friedreich's ataxia (FRDA). Essentially all studies on the molecular mechanisms of this expansion process invoke an important role for non-B DNA conformations which may be adopted by these repeat sequences. We have directly evaluated the role(s) of the repeating sequences per se, or of the non-B DNA conformations formed by these sequences, in the mutagenic process. Studies in Escherichia coli and three types of mammalian (COS-7, CV-1, and HEK-293) fibroblast-like cells revealed that conditions which promoted the formation of the non-B DNA structures enhanced the genetic instabilities, both within the repeat sequences and in the flanking sequences of up to approximately 4 kbp. The three strategies utilized included: the in vivo modulation of global negative supercoil density using topA and gyrB mutant E. coli strains; the in vivo cleavage of hairpin loops, which are an obligate consequence of slipped-strand structures, cruciforms, and intramolecular triplexes, by inactivation of the SbcC protein; and by genetic instability studies with plasmids containing long repeating sequence inserts that do, and do not, adopt non-B DNA structures in vitro. Hence, non-B DNA conformations are critical for these mutagenesis mechanisms.     

Gene conversion (recombination) mediates expansions of CTG[middle dot]CAG repeats

Genetic recombination is a robust mechanism for expanding CTG.CAG triplet repeats involved in the etiology of hereditary neurological diseases (Jakupciak, J. P., and Wells, R. D. (1999) J. Biol. Chem. 274, 23468-23479). This two-plasmid recombination system in Escherichia coli with derivatives of pUC19 and pACYC184 was used to investigate the effect of triplet repeat orientation on recombination and extent of expansions; tracts of 36, 50, 80, and 36, 100, and 175 repeats in length, respectively, in all possible permutations of length and in both orientations (relative to the unidirectional replication origins) revealed little or no effect of orientation of expansions. The extent of expansions was generally severalfold the length of the progenitor tract and frequently exceeded the combined length of the two tracts in the cotransformed plasmids. Expansions were much more frequent than deletions. Repeat tracts bearing two G-to-A interruptions (polymorphisms) within either 171- or 219-base pair tracts substantially reduced the expansions compared with uninterrupted repeat tracts of similar lengths. Gene conversion, rather than crossing over, was the recombination mechanism. Prior studies showed that DNA replication, repair, and tandem duplication also mediated genetic instabilities of the triplet repeat sequence. However, gene conversion (recombinational repair) is by far the most powerful expansion mechanism. Thus, we propose that gene conversion is the likely expansion mechanism for myotonic dystrophy, spinocerebellar ataxia type 8, and fragile X syndrome.     

Genetic instabilities in (CTG.CAG) repeats occur by recombination.

The expansion of triplet repeat sequences (TRS) associated with hereditary neurological diseases is believed from prior studies to be due to DNA replication. This report demonstrates that the expansion of (CTG.CAG)(n) in vivo also occurs by homologous recombination as shown by biochemical and genetic studies. A two-plasmid recombination system was established in Escherichia coli with derivatives of pUC19 (harboring the ampicillin resistance gene) and pACYC184 (harboring the tetracycline resistance gene). The derivatives contained various triplet repeat inserts ((CTG.CAG), (CGG.CCG), (GAA.TTC), (GTC.GAC), and (GTG.CAC)) of different lengths, orientations, and extents of interruptions and a control non-repetitive sequence. The availability of the two drug resistance genes and of several unique restriction sites on the plasmids enabled rigorous genetic and biochemical analyses. The requirements for recombination at the TRS include repeat lengths >30, the presence of CTG.CAG on both plasmids, and recA and recBC. Sequence analyses on a number of DNA products isolated from individual colonies directly demonstrated the crossing-over and expansion of the homologous CTG.CAG regions. Furthermore, inversion products of the type [(CTG)(13)(CAG)(67)].[(CTG)(67)(CAG)(13)] were isolated as the apparent result of "illegitimate" recombination events on intrahelical pseudoknots. This work establishes the relationships between CTG.CAG sequences, multiple fold expansions, genetic recombination, formation of new recombinant DNA products, and the presence of both drug resistance genes. Thus, if these reactions occur in humans, unequal crossing-over or gene conversion may also contribute to the expansions responsible for anticipation associated with several hereditary neurological syndromes.     

Trinucleotide repeats associated with human disease.

Triplet repeat expansion diseases (TREDs) are characterized by the coincidence of disease manifestation with amplification of d(CAG. CTG), d(CGG.CCG) or d(GAA.TTC) repeats contained within specific genes. Amplification of triplet repeats continues in offspring of affected individuals, which generally results in progressive severity of the disease and/or an earlier age of onset, phenomena clinically referred to as 'anticipation'. Recent biophysical and biochemical studies reveal that five of the six [d(CGG)n, d(CCG)n, (CAG)n, d(CTG)n and d(GAA)n] complementary sequences that are associated with human disease form stable hairpin structures. Although the triplet repeat sequences d(GAC)n and d(GTC)n also form hairpins, repeats of the double-stranded forms of these sequences are conspicuously absent from DNA sequence databases and are not anticipated to be associated with human disease. With the exception of d(GAG)n and d(GTG)n, the remaining triplet repeat sequences are unlikely to form hairpin structures at physiological salt and temperature. The details of hairpin structures containing trinucleotide repeats are summarized and discussed with respect to potential mechanisms of triplet repeat expansion and d(CGG.CCG) n methylation/demethylation.     

Slipped (CTG).(CAG) repeats of the myotonic dystrophy locus: surface probing with anti-DNA antibodies

At least 15 human diseases have been associated with the length-dependent expansion of gene-specific (CTG).(CAG) repeats, including myotonic dystrophy (DM1) and spinocerebellar ataxia type 1 (SCA1). Repeat expansion is likely to involve unusual DNA structures. We have structurally characterized such DNA, with (CTG)(n).(CAG)(n) repeats of varying length (n=17-79), by high-resolution gel electrophoresis, and have probed their surfaces with anti-DNA antibodies of known specificities. We prepared homoduplex S-DNAs, which are (CTG)x.(CAG)y where x=y, and heteroduplex SI-DNAs, which are hybrids where x>y or x相似文献