Replication stalling at Friedreich's ataxia (GAA)n repeats in vivo

Friedreich's ataxia (GAA)n repeats of various lengths were cloned into a Saccharymyces cerevisiae plasmid, and their effects on DNA replication were analyzed using two-dimensional electrophoresis of replication intermediates. We found that premutation- and disease-size repeats stalled the replication fork progression in vivo, while normal-size repeats did not affect replication. Remarkably, the observed threshold repeat length for replication stalling in yeast (approximately 40 repeats) closely matched the threshold length for repeat expansion in humans. Further, replication stalling was strikingly orientation dependent, being pronounced only when the repeat's homopurine strand served as the lagging strand template. Finally, it appeared that length polymorphism of the (GAA)n. (TTC)n repeat in both expansions and contractions drastically increases in the repeat's orientation that is responsible for the replication stalling. These data represent the first direct proof of the effects of (GAA)n repeats on DNA replication in vivo. We believe that repeat-caused replication attenuation in vivo is due to triplex formation. The apparent link between the replication stalling and length polymorphism of the repeat points to a new model for the repeat expansion.     

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.     

Restarted replication forks are error-prone and cause CAG repeat expansions and contractions

Disease-associated trinucleotide repeats form secondary DNA structures that interfere with replication and repair. Replication has been implicated as a mechanism that can cause repeat expansions and contractions. However, because structure-forming repeats are also replication barriers, it has been unclear whether the instability occurs due to slippage during normal replication progression through the repeat, slippage or misalignment at a replication stall caused by the repeat, or during subsequent replication of the repeat by a restarted fork that has altered properties. In this study, we have specifically addressed the fidelity of a restarted fork as it replicates through a CAG/CTG repeat tract and its effect on repeat instability. To do this, we used a well-characterized site-specific replication fork barrier (RFB) system in fission yeast that creates an inducible and highly efficient stall that is known to restart by recombination-dependent replication (RDR), in combination with long CAG repeat tracts inserted at various distances and orientations with respect to the RFB. We find that replication by the restarted fork exhibits low fidelity through repeat sequences placed 2–7 kb from the RFB, exhibiting elevated levels of Rad52- and Rad8^{ScRad5/HsHLTF}-dependent instability. CAG expansions and contractions are not elevated to the same degree when the tract is just in front or behind the barrier, suggesting that the long-traveling Polδ-Polδ restarted fork, rather than fork reversal or initial D-loop synthesis through the repeat during stalling and restart, is the greatest source of repeat instability. The switch in replication direction that occurs due to replication from a converging fork while the stalled fork is held at the barrier is also a significant contributor to the repeat instability profile. Our results shed light on a long-standing question of how fork stalling and RDR contribute to expansions and contractions of structure-forming trinucleotide repeats, and reveal that tolerance to replication stress by fork restart comes at the cost of increased instability of repetitive sequences.     

Expansion of DNA repeats in Escherichia coli: effects of recombination and replication functions.

Duplication or expansion of directly repeated sequence elements is associated with a number of human genetic diseases. To study the mechanisms of repeat expansion, we have developed a plasmid assay in Escherichia coli. Our assay involves two simple repeats of 787 bp in length; expansion to three or more copies of the repeat can be selected by restoration of an intact tetracycline-resistance gene. Expansions occurred at relatively high rates, >10(-5), in the population. Both RecA-dependent recombination and RecA-independent slipped misalignments contributed to the observed expansion events. Mutations that impair DNA polymerase III (DnaE, DnaQ subunits) or the replication fork helicase, DnaB, stimulated both RecA-dependent and RecA-independent expansion events. In these respects, the properties of repeat expansion resemble repeat deletion and suggest that difficulties in DNA replication may trigger both classes of rearrangements. About 20% of the RecA-independent expansion events are accompanied by reciprocal sister-chromosome exchange, producing dimeric plasmids carrying one triplicated and one deleted locus. These products are explained by a model involving misaligned strands across the replication fork. This model predicts that the location of a replication stall site may govern the types of resulting rearrangements. The specific location of such a stall site can also, in theory, account for propensity towards expansion or deletion of repeat arrays. This may have relevance to trinucleotide repeat expansion in human genetic disease.     

Repeat expansion in the budding yeast ribosomal DNA can occur independently of the canonical homologous recombination machinery

Major eukaryotic genomic elements, including the ribosomal DNA (rDNA), are composed of repeated sequences with well-defined copy numbers that must be maintained by regulated recombination. Although mechanisms that instigate rDNA recombination have been identified, none are directional and they therefore cannot explain precise repeat number control. Here, we show that yeast lacking histone chaperone Asf1 undergo reproducible rDNA repeat expansions. These expansions do not require the replication fork blocking protein Fob1 and are therefore independent of known rDNA expansion mechanisms. We propose the existence of a regulated rDNA repeat gain pathway that becomes constitutively active in asf1Δ mutants. Cells lacking ASF1 accumulate rDNA repeats with high fidelity in a processive manner across multiple cell divisions. The mechanism of repeat gain is dependent on highly repetitive sequence but, surprisingly, is independent of the homologous recombination proteins Rad52, Rad51 and Rad59. The expansion mechanism is compromised by mutations that decrease the processivity of DNA replication, which leads to progressive loss of rDNA repeats. Our data suggest that a novel mode of break-induced replication occurs in repetitive DNA that is dependent on high homology but does not require the canonical homologous recombination machinery.     

Pausing of simian virus 40 DNA replication fork movement in vivo by (dG-dA)n·(dT-dC)n tracts

We have earlier demonstrated that a sequence bordering an amplified DNA segment and containing the unusual sequence (dG-dA)_n·(dT-dC)_n could slow replication fork movement [Rao et al., Nucleic Acids Res. 16 (1988) 8077–8094]. This was done by cloning the unusual sequence in simian virus 40 (SV40) and following the rate of incorporation of radioactively labeled nucleotides into various regions of the SV40 genome. In the present study, we have analyzed the in vivo replicative intermediates of the SV40 variants containing the unusual sequences by a two-dimensional gel electrophoretic technique. We found that the technique can be used to detect minor pauses in DNA replication and demonstrated that the cloned (dG-dA)_n·(dT-dC)_n tracts, that can potentially adopt triplex structures, could slow DNA replication fork movement. A sequence from the plasmid pUC18 did not slow fork movement when cloned in the same locus of SV40. The pause caused by the alternating guanosine-adenosine repeats might play a role in the regulation of DNA replication and gene amplification in vivo.     

三核苷酸重复序列失稳定机制:重复序列形成non-B二级结构的必要性和细胞反式作用因子的作用

与三核苷酸重复序列CAG.CTG、CGG·CCG和GAA·TTC扩增和缺失有关的分子机制尚不能得到清楚的阐释.体外研究表明,上述疾病相关的重复序列可以在体外形成non-B二级结构,并介导重复序列扩增.然而,迄今为止,类似的观察尚未在体内研究过程中得以实现.利用模型生物大肠杆菌和酵母等进行的有关研究并不能模拟三核苷酸重复序列的扩增,这暗示三核苷酸重复序列的体内扩增可能与重复序列形成non-B二级结构关联性并不大.尽管理论上较长的三核苷酸重复序列可以在复制和后复制过程中较易形成non-B DNA二级结构,但这样的二级结构倾向于导致重复序列出现"脆性",而不是扩增.事实上,患者所具有的三核苷酸重复序列扩增并非一定需要通过non-B二级结构的介导,这些重复序列的扩增是可以通过一种RNA转录诱导的局部DNA重复序列的复制和其后的DNA重排得以发生.     

Role of recombination and replication fork restart in repeat instability

Eukaryotic genomes contain many repetitive DNA sequences that exhibit size instability. Some repeat elements have the added complication of being able to form secondary structures, such as hairpin loops, slipped DNA, triplex DNA or G-quadruplexes. Especially when repeat sequences are long, these DNA structures can form a significant impediment to DNA replication and repair, leading to DNA nicks, gaps, and breaks. In turn, repair or replication fork restart attempts within the repeat DNA can lead to addition or removal of repeat elements, which can sometimes lead to disease. One important DNA repair mechanism to maintain genomic integrity is recombination. Though early studies dismissed recombination as a mechanism driving repeat expansion and instability, recent results indicate that mitotic recombination is a key pathway operating within repetitive DNA. The action is two-fold: first, it is an important mechanism to repair nicks, gaps, breaks, or stalled forks to prevent chromosome fragility and protect cell health; second, recombination can cause repeat expansions or contractions, which can be deleterious. In this review, we summarize recent developments that illuminate the role of recombination in maintaining genome stability at DNA repeats.     

Overcoming natural replication barriers: differential helicase requirements

DNA sequences that form secondary structures or bind protein complexes are known barriers to replication and potential inducers of genome instability. In order to determine which helicases facilitate DNA replication across these barriers, we analyzed fork progression through them in wild-type and mutant yeast cells, using 2-dimensional gel-electrophoretic analysis of the replication intermediates. We show that the Srs2 protein facilitates replication of hairpin-forming CGG/CCG repeats and prevents chromosome fragility at the repeat, whereas it does not affect replication of G-quadruplex forming sequences or a protein-bound repeat. Srs2 helicase activity is required for hairpin unwinding and fork progression. Also, the PCNA binding domain of Srs2 is required for its in vivo role of replication through hairpins. In contrast, the absence of Sgs1 or Pif1 helicases did not inhibit replication through structural barriers, though Pif1 did facilitate replication of a telomeric protein barrier. Interestingly, replication through a protein barrier but not a DNA structure barrier was modulated by nucleotide pool levels, illuminating a different mechanism by which cells can regulate fork progression through protein-mediated stall sites. Our analyses reveal fundamental differences in the replication of DNA structural versus protein barriers, with Srs2 helicase activity exclusively required for fork progression through hairpin 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.     

Dinucleotide repeat expansion catalyzed by bacteriophage T4 DNA polymerase in vitro

DNA replication normally occurs with high fidelity, but certain "slippery" regions of DNA with tracts of mono-, di-, and trinucleotide repeats are frequently mutation hot spots. We have developed an in vitro assay to study the mechanism of dinucleotide repeat expansion. The primer-template resembles a base excision repair substrate with a single nucleotide gap centered opposite a tract of nine CA repeats; nonrepeat sequences flank the dinucleotide repeats. DNA polymerases are expected to repair the gap, but further extension is possible if the DNA polymerase can displace the downstream oligonucleotide. We report here that the wild type bacteriophage T4 DNA polymerase carries out gap and strand displacement replication and also catalyzes a dinucleotide expansion reaction. Repeat expansion was not detected for an exonuclease-deficient T4 DNA polymerase or for Escherichia coli DNA polymerase I. The dinucleotide repeat expansion reaction catalyzed by wild type T4 DNA polymerase required a downstream oligonucleotide to "stall" replication and 3' --> 5' exonuclease activity to remove the 3'-nonrepeat sequence adjacent to the repeat tract in the template strand. These results suggest that dinucleotide repeat expansion may be stimulated in vivo during DNA repair or during processing of Okazaki fragments.     

Identification of DNA cis elements essential for expansion of ribosomal DNA repeats in Saccharomyces cerevisiae

Saccharomyces cerevisiae carries approximately 150 ribosomal DNA (rDNA) copies in tandem repeats. Each repeat consists of the 35S rRNA gene, the NTS1 spacer, the 5S rRNA gene, and the NTS2 spacer. The FOB1 gene was previously shown to be required for replication fork block (RFB) activity at the RFB site in NTS1, for recombination hot spot (HOT1) activity, and for rDNA repeat expansion and contraction. We have constructed a strain in which the majority of rDNA repeats are deleted, leaving two copies of rDNA covering the 5S-NTS2-35S region and a single intact NTS1, and whose growth is supported by a helper plasmid carrying, in addition to the 5S rRNA gene, the 35S rRNA coding region fused to the GAL7 promoter. This strain carries a fob1 mutation, and an extensive expansion of chromosomal rDNA repeats was demonstrated by introducing the missing FOB1 gene by transformation. Mutational analysis using this system showed that not only the RFB site but also the adjacent approximately 400-bp region in NTS1 (together called the EXP region) are required for the FOB1-dependent repeat expansion. This approximately 400-bp DNA element is not required for the RFB activity or the HOT1 activity and therefore defines a function unique to rDNA repeat expansion (and presumably contraction) separate from HOT1 and RFB activities.     

Effects of temperature, Mg2+ concentration and mismatches on triplet-repeat expansion during DNA replication in vitro.

The human genome contains many simple tandem repeats that are widely dispersed and highly polymorphic. At least one group of simple tandem repeats, the DNA trinucleotide repeats, can dramaticallyexpand in size during transmission from one generation to the next to cause disease by a process known as dynamic mutation. We investigated the ability of trinucleotide repeats AAT and CAG to expand in size during DNA replication using a minimal in vitro system composed of the repeat tract, with and without unique flanking sequences, and DNA polymerase. Varying Mg2+concentration and temperature gave dramatic expansions of repeat size during DNA replication in vitro. Expansions of up to 1000-fold were observed. Mismatches partially stabilized the repeat tracts against expansion. Expansions were only detected when the primer was complementary to the repeat tract rather than the flanking sequence. The results imply that cellular environment and whether the growing strand contains a nick or gap are important factors for the expansion process in vivo.     

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.     

Relationship among location of T-antigen-induced DNA distortion,auxiliary sequences,and DNA replication efficiency

T-antigen-induced DNA distortion was studied in a series of simian virus 40 (SV40) plasmid constructs whose relative replication efficiency ranges from 0.2 to 36. Bending was detected in the wild-type SV40 regulatory region consisting of three copies of the GC-rich 21-bp repeat but not in constructs with only one or two copies of the 21-bp repeat. In a construct with enhanced replication efficiency, bending occurred in a 69-bp cellular sequence located upstream of a single copy of the 21-bp repeat. Bending occurred both upstream of ori and in the three 21-bp repeats located downstream of ori in a construct with reduced replication efficiency. In a construct with no 21-bp repeats, DNA distortion occurred downstream of ori. The results indicate that SV40 DNA replication is enhanced when the structure of the regulatory region allows the DNA to form a bent structure upstream of the initial movement of the replication fork.     

Inhibition of DNA synthesis facilitates expansion of low‐complexity repeats

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. This minireview is dedicated to the FASEB‐2012 meeting “Dynamic DNA Structures in Biology”, organized by Nancy Maizels and Sergei Mirkin.     

No evidence of expansion of CAG or GAA repeats in schizophrenia families and monozygotic twins

Many diseases caused by trinucleotide expansion exhibit increased severity and decreased age of onset (genetic anticipation) in successive generations. Apparent evidence of genetic anticipation in schizophrenia has led to a search for trinucleotide repeat expansions. We have used several techniques, including Southern blot hybridization, repeat expansion detection (RED) and locus-specific PCR to search for expanded CAG/CTG repeats in 12 families from the United Kingdom and 11 from Iceland that are multiplex for schizophrenia and demonstrate anticipation. The unstable DNA theory could also explain discordance of phenotype for schizophrenia in pairs of monozygotic twins, where the affected twin has a greater number of repeats than the unaffected twin. We used these techniques to look for evidence of different CAG/CTG repeat size in 27 pairs of monozygotic twins who are either concordant or discordant for schizophrenia. We have found no evidence of an increase in CAG/CTG repeat size for affected members in the families, or for the affected twins in the MZ twin sample. Southern hybridization and RED analysis were also performed for the twin and family samples to look for evidence of expansion of GAA/TTC repeats. However, no evidence of expansion was found in either sample. Whilst these results suggest that these repeats are not involved in the etiology of schizophrenia, the techniques used for detecting repeat expansions have limits to their sensitivity. The involvement of other trinucleotide repeats or other expandable repeat sequences cannot be ruled out. Received: 8 September 1997 / Accepted: 13 March 1998     

Formation of linear inverted repeat amplicons following targeting of an essential gene in Leishmania

Attempts to inactivate an essential gene in the protozoan parasite Leishmania have often led to the generation of extra copies of the wild-type alleles of the gene. In experiments with Leishmania tarentolae set up to disrupt the gene encoding the J-binding protein 1 (JBP1), a protein binding to the unusual base beta-D-glucosyl-hydroxymethyluracil (J) of Leishmania, we obtained JBP1 mutants containing linear DNA elements (amplicons) of approximately 100 kb. These amplicons consist of a long inverted repeat with telomeric repeats at both ends and contain either the two different targeting cassettes used to inactivate JBP1, or one cassette and one JBP1 gene. Each long repeat within the linear amplicons corresponds to sequences covering the JBP1 locus, starting at the telomeres upstream of JBP1 and ending in a approximately 220 bp sequence repeated in an inverted (palindromic) orientation downstream of the JBP1 locus. We propose that these amplicons have arisen by a template switch inside a DNA replication fork involving the inverted DNA repeats and helped by the gene targeting.