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.     

Alternate strand recognition of double-helical DNA by (T,G)-containing oligonucleotides in the presence of a triple helix-specific ligand.

Triple helix formation requires a polypurine- polypyrimidine sequence in the target DNA. Recent works have shown that this constraint can be circumvented by using alternate strand triplex-forming oligonucleotides. We have previously demonstrated that (T,G)-containing triplex- forming oligonucleotides may adopt a parallel or an antiparallel orientation with respect to an oligopurine target, depending upon the sequence and, in particular, upon the number of 5'-GpT-3' and 5'-TpG-3' steps [Sun et al. (1991) C.R. Acad. Sci. Paris Ser III, 313, 585-590]. A single (T,G)-containing oligonucleotide can therefore interact with two oligopurine stretches which alternate on the two strands of the target DNA. The (T,G) switch oligonucleotide contains a 5'-part targeted to one of the oligopurine sequences in a parallel orientation followed by a 3'-part that adopts an antiparallel orientation with respect to the second oligopurine sequence. We show that a limitation to the stability of such a triplex may arise from the instability of the antiparallel part, composed of reverse-Hoogsteen C.GxG and T.AxT base triplets. Using DNase I footprinting and ultraviolet absorption experiments, we report that a benzo[e]pyridoindole derivative [(3-methoxy- 7H-8-methyl-11-[(3'-amino-propyl) amino] benzo[e]pyrido [4,3-b]indole (BePI)], a drug interacting more tightly with a triplex than with a duplex DNA, strongly stabilizes triplexes with reverse-Hoogsteen C.GxG and T.AxT triplets thus allowing a stabilization of the triplex-forming switch (T,G) oligonucleotide on alternating oligopurine- oligopyrimidine 5'-(Pu)14(Py)14-3' duplex sequences. These results lead to an extension of the range of oligonucleotide sequences for alternate strand recognition of duplex DNA.     

Exploration of long and short repetitive sequence relationships in the sea urchin genome.

Long and short repetitive sequences of sea urchin DNA were prepared by reassociation of 2000 nucleotide long fragments to Cot 4 and digestion with the single strand specific nuclease S1. The S1 resistant duplexes were separated into long repetitive and short repetitive fractions on Agarose A50. The extent of shared sequences was studied by reassociating a labeled preparation of short repetitive DNA with an excess of unlabeled long repetitive DNA. Less than 10% of the long repetitive DNA preparation was able to reassociate with the short repetitive DNA. Thus the long and short repetitive elements appear to be principally independent sequence classes in sea urchin DNA. Precisely reassociating repetitive DNA was prepared by four successive steps of reassociation and thermal chromatography on hydroxyapatite. This fraction (3% of the genome) was reassociated by itself or with a great excess of total sea urchin DNA. The thermal stability of the products was identical in both cases (Tm=81 degrees C), indicating that precisely repeated sequences do not have many imprecise copies in sea urchin DNA.     

Extrachromosomal circular DNAs and genomic sequence plasticity in eukaryotic cells

The ability of eukaryotic organisms of the same genotype to vary in developmental pattern or in phenotype according to varying environmental conditions is frequently associated with changes in extrachromosomal circular DNA (eccDNA) sequences. Although variable in size, sequence complexity, and copy number, the best characterized of these eccDNAs contain sequences homologous to chromosomal DNA which indicates that they might arise from genetic rearrangements, such as homologous recombination. The abundance of repetitive sequence families in eccDNAs is consistent with the notion that tandem repeats and dispersed repetitive elements participate in intrachromosomal recombination events. There is also evidence that a fraction of this DNA has characteristics similar to retrotransposons. It has been suggested that eccDNAs could reflect altered patterns of gene expression or an instability of chromosomal sequences during development and aging. This article reviews some of the findings and concepts regarding eccDNAs and sequence plasticity in eukaryotic genomes.     

Short loop length and high thermal stability determine genomic instability induced by G‐quadruplex‐forming minisatellites

G‐quadruplexes (G4) are polymorphic four‐stranded structures formed by certain G‐rich nucleic acids, with various biological roles. However, structural features dictating their formation and/or function in vivo are unknown. In S. cerevisiae, the pathological persistency of G4 within the CEB1 minisatellite induces its rearrangement during leading‐strand replication. We now show that several other G4‐forming sequences remain stable. Extensive mutagenesis of the CEB25 minisatellite motif reveals that only variants with very short (≤ 4 nt) G4 loops preferentially containing pyrimidine bases trigger genomic instability. Parallel biophysical analyses demonstrate that shortening loop length does not change the monomorphic G4 structure of CEB25 variants but drastically increases its thermal stability, in correlation with the in vivo instability. Finally, bioinformatics analyses reveal that the threat for genomic stability posed by G4 bearing short pyrimidine loops is conserved in C. elegans and humans. This work provides a framework explanation for the heterogeneous instability behavior of G4‐forming sequences in vivo, highlights the importance of structure thermal stability, and questions the prevailing assumption that G4 structures with short or longer loops are as likely to form in vivo.     

R环的形成及对基因组稳定性的影响

R-环是由一个RNA:DNA杂交体和一条单链状态的DNA分子共同组成的三链核酸结构。其中, RNA:DNA杂交体的形成起因于基因转录所合成的RNA分子不能与模板分开, 或RNA分子重新与一段双链DNA分子中的一条链杂交。在基因转录过程中, 当转录泡遇到富含G碱基的非模板链区或位于某些与人类疾病有关的三核苷酸卫星DNA时, 转录泡后方累积的负超螺旋可促进R环形成。同时, 新生RNA分子未被及时加工、成熟或未被快速转运到细胞质等因素也会催生R环。研究表明, 细胞拥有多种管理R环的方法, 可以有效地管理R环的形成和处理已经形成的R环, 以尽量避免R环对DNA复制、基因突变和同源重组产生不利影响。文章重点分析了R-环的形成机制及R环对DNA复制、基因突变和同源重组的影响, 并针对R-环诱导的DNA复制在某些三核苷酸重复扩增有关的神经肌肉退行性疾病发生过程中的作用进行了分析和讨论。     

Mutations predetermined by the primary structure of DNA

This study is concerned with an experimental verification of hypotheses postulating the involvement of self-complementary nucleotide sequences in the formation of deletions and insertions. It was suggested that deletions can arise in the regions of self-complementary nucleotide sequences, which allows the formation of the hairpin structures in a single-stranded DNA, arising during excision repair. These hairpin structures can be eliminated by nucleases or during DNA replication. Insertions can arise as a result of homologous recombination, when a migrating DNA strand contains a self-complementary sequence which forms hairpin structure. Model experiments were carried out with the pBR322 plasmid. A plasmid DNA with premutational damage in the palindrome-containing region was constructed by in vitro dimethylsulfate modification of one strand of EcoRI-BamHI restriction fragment. The plasmid was used for transformation of Escherichia coli. Restriction mapping and nucleotide analysis of the mutant DNAs demonstrated that they all contained deletions. The end points of the deletions coincide with the palindrome. To model homologous recombination, a plasmid with D-loop was constructed. A single-stranded DNA fragment containing palindrome forming a hairpin structure was introduced into the plasmid DNA and covalently fixed in the complex. When E. coli cells were transfected with this DNA, plasmid mutants containing insertions predetermined by palindromic structure arose. The evolutionary role of mutations predetermined by primary DNA structure is discussed.     

Formation of extrachromosomal circular DNA in HeLa cells by nonhomologous recombination.

Extrachromosomal circular DNA (eccDNA) generated from chromosomal DNA is found in all mammalian cells and increases with cell stress or aging. Studies of eccDNA structure and mode of formation provide insight into mechanisms of instability of the mammalian genome. Previous studies have suggested that eccDNA is generated through a process involving recombination between repetitive sequences. However, we observed that approximately one half of the small eccDNA fragments cloned from HeLa S3 cells were composed entirely of nonrepetitive or low-copy DNA sequences. We analyzed four of these fragments by polymerase chain reaction and nucleotide sequencing and found that they were complete eccDNAs. We then screened a human genomic library with the eccDNAs to isolate the complementary chromosomal sequences. Comparing the recombination junctions within the eccDNAs with the chromosomal sequences from which they were derived revealed that nonhomologous recombination was involved in their formation. One of the eccDNAs was composed of two separate sequences from different parts of the genome. These results suggest that rejoining of ends of fragmented DNA is responsible for the generation of a substantial portion of the eccDNAs found in HeLa S3 cells.