The impact of sequence divergence and DNA mismatch repair on homeologous recombination in Arabidopsis

We examined the effects of substrate divergence and DNA mismatch repair (MMR) on recombination in Arabidopsis thaliana. Relative to the frequency observed in plants with a homologous construct (0% divergence), recombination was decreased 4.1-, 9.6-, 11.7- or 20.3-fold, respectively, in lines with constructs containing 0.5%, 2%, 4% or 9% divergence between the recombination substrates. To evaluate the contribution of the MMR system in this decrease, 12 independent reporter lines (two or three lines per reporter construct) were crossed to an AtMSH2 T-DNA insertional mutant. We examined the recombination frequency in progeny homozygous for a reporter T-DNA and homozygous either for the wild type or the mutant allele of AtMSH2. The loss of MMR activity led to a two- to ninefold increase in homeologous recombination and the size of the increase did not seem to correlate with the amount of divergence. Inversely, complementation of the insertional mutant with a wild-type cDNA of AtMSH2 reduced recombination. Our results demonstrate clearly that sequence divergence can dramatically reduce the recombination frequency in plants and that the MMR system plays a part in this decrease.     

Homologous recombination in Agrobacterium: potential implications for the genomic species concept in bacteria

According to current taxonomical rules, a bona fide bacterialspecies is a genomic species characterized by the genomic similarityof its members. It has been proposed that the genomic cohesionof such clusters may be related to sexual isolation, which limitsgene flow between too divergent bacteria. Homologous recombinationis one of the most studied mechanisms responsible for this geneticisolation. Previous studies on several bacterial models showedthat recombination frequencies decreased exponentially withincreasing DNA sequence divergence. In the present study, weinvestigated this relationship in the Agrobacterium tumefaciensspecies complex, which allowed us to focus on sequence divergencein the vicinity of the genetic boundaries of genomic species.We observed that the sensitivity of the recombination frequencyto DNA divergence fitted a log-linear function until approximately10% sequence divergence. The results clearly revealed that therewas no sharp drop in recombination frequencies at the pointwhere the sequence divergence distribution showed a "gap" delineatinggenomic species. The ratio of the recombination frequency inhomogamic conditions relative to this frequency in heterogamicconditions, that is, sexual isolation, was found to decreasefrom 8 between the most distant strains within a species to9 between the most closely related species, for respective increasesfrom 4.3% to 6.4% mismatches in the marker gene chvA. This meansthat there was only a 1.13-fold decrease in recombination frequenciesfor recombination events at both edges of the species border.Hence, from the findings of this investigation, we concludethat—at least in this taxon—sexual isolation basedon homologous recombination is likely not high enough to stronglyhamper gene flow between species as compared with gene flowbetween distantly related members of the same species. The 70%relative binding ratio cutoff used to define bacterial speciesis likely correlated to only minor declines in homologous recombinationfrequencies. Consequently, the sequence diversity, as a mechanisticfactor for the efficiency of recombination (as assayed in thelaboratory), appears to play little role in the genetic cohesionof bacterial species, and thus, the genomic species definitionfor prokaryotes is definitively not reconcilable with the biologicalspecies concept for eukaryotes.     

The Arabidopsis DNA mismatch repair gene <Emphasis Type="Italic">PMS1</Emphasis> restricts somatic recombination between homeologous sequences

The eukaryotic DNA mismatch repair (MMR) system contributes to maintaining the fidelity of genetic information by correcting replication errors and preventing illegitimate recombination events. This study aimed to examine the function(s) of the Arabidopsis thaliana PMS1 gene (AtPMS1), one of three homologs of the bacterial MutL gene in plants. Two independent mutant alleles (Atpms1-1 and Atpms1-2) were obtained and one of these (Atpms1-1) was studied in detail. The mutant exhibited a reduction in seed set and a bias against the transmission of the mutant allele. Somatic recombination, both homologous and homeologous, was examined using a set of reporter constructs. Homologous recombination remained unchanged in the mutant while homeologous recombination was between 1.7- and 4.8-fold higher than in the wild type. This increase in homeologous recombination frequency was not correlated with the degree of sequence divergence. In RNAi lines, a range of increases in homeologous recombination were observed with two lines showing a 3.3-fold and a 3.6-fold increase. These results indicate that the AtPMS1 gene contributes to an antirecombination activity aimed at restricting recombination between diverged sequences. Liangliang Li, Eric Dion contributed equally to this work.     

Chromosome polymorphisms close to the cm-ADE1 locus of Candida maltosa

The imperfect yeast Candida maltosa has an ill-defined genetic constitution; it is nominally diploid, but probably highly aneuploid, in nature. We report on polymorphisms specifically affecting those chromosomes which bear the cm-ADE1 gene. This gene encodes phosphoribosylaminoimidazole-succinocarboxamide synthetase, an enzyme in the adenine biosynthetic pathway. By electrophoretic karyotype analysis, three differently sized chromosomes were demonstrated to carry cm-ADE; the size (but not the number) of these chromosomes was also found to vary, both between strains and during the mitotic growth of a single strain. Four different alleles of cm-ADE1 have been cloned and sequenced from one prototrophic strain. DNA sequence divergence between these different alleles is as high as 8%, with the greatest divergence being found in the upstream region. Mitotic recombination events that led to changes in the karyotype were followed by using cm-ADE1 DNA as an hybridization probe. A recombination hot-spot in the neighbourhood of the gene appears to be responsible for the instability of the chromosomes on which it resides.     

Accurate homologous recombination is a prominent double-strand break repair pathway in mammalian chromosomes and is modulated by mismatch repair protein Msh2

We designed DNA substrates to study intrachromosomal recombination in mammalian chromosomes. Each substrate contains a thymidine kinase (tk) gene fused to a neomycin resistance (neo) gene. The fusion gene is disrupted by an oligonucleotide containing the 18-bp recognition site for endonuclease I-SceI. Substrates also contain a “donor” tk sequence that displays 1% or 19% sequence divergence relative to the tk portion of the fusion gene. Each donor serves as a potential recombination partner for the fusion gene. After stably transfecting substrates into mammalian cell lines, we investigated spontaneous recombination and double-strand break (DSB)-induced recombination following I-SceI expression. No recombination events between sequences with 19% divergence were recovered. Strikingly, even though no selection for accurate repair was imposed, accurate conservative homologous recombination was the predominant DSB repair event recovered from rodent and human cell lines transfected with the substrate containing sequences displaying 1% divergence. Our work is the first unequivocal demonstration that homologous recombination can serve as a major DSB repair pathway in mammalian chromosomes. We also found that Msh2 can modulate homologous recombination in that Msh2 deficiency promoted discontinuity and increased length of gene conversion tracts and brought about a severalfold increase in the overall frequency of DSB-induced recombination.     

The influence of sequence divergence between alleles of the human MS205 minisatellite incorporated into the yeast genome on length-mutation rates and lethal recombination events during meiosis

Certain minisatellites exhibit hypervariability with respect to the number of repeat units and, thus, allele length. Such polymorphism is generated by germline-specific recombinational events that occur at high frequencies and lead to the gain or loss of repeat units. In order to elucidate the molecular details of mutagenesis in minisatellites, we have integrated human minisatellites into the yeast genome in the vicinity of a hotspot for meiotic double-strand breaks (DSBs). Here, we describe the results of tetrad analyses of mutations in the human MS205 minisatellite in yeast strains heterozygous for alleles composed of 51 and 31 repeat units, as well as in a strain homozygous for the same 51 repeat unit allele. The length-mutation rate was twice as high in the heterozygous strain as in the homozygous strain, suggesting that sequence divergence between alleles enhances the generation of length mutations. In the case of heterozygotes, the frequency of length mutants resulting from inter-allelic exchange was significantly higher in tetrads with three viable spores than in tetrads with four viable spores, indicating that there is a higher probability for spore mortality in tetrads originating from meioses during which inter-allelic exchange of repeat units occurs. In an attempt to explain these findings, we propose a model for minisatellite mutation involving recombination, in which sequence divergence between alleles results in a heteroduplex containing numerous mismatches. We suggest that convergent mismatch-repair tracts in this heteroduplex give rise to a DSB that may be repaired by an additional round of recombination resulting in mutation of a third allele, or be lethal if such recombination fails. It appears probable that the formation of such additional mutants is the major explanation for the difference in meiotic length-mutation rates between the heterozygous and homozygous yeast strains, and that this phenomenon contributes to high germline length-mutation frequencies at minisatellites in humans.     

The Z-DNA motif d(TG)30 promotes reception of information during gene conversion events while stimulating homologous recombination in human cells in culture.

Tracts of the alternating dinucleotide polydeoxythymidylic-guanylic [d(TG)].polydeoxyadenylic-cytidylic acid [d(AC)], present throughout the human genome, are capable of readily forming left-handed Z-DNA in vitro. We have analyzed the effects of the Z-DNA motif d(TG)30 upon homologous recombination between two nonreplicating plasmid substrates cotransfected into human cells in culture. In this study, the sequence d(TG)30 is shown to stimulate homologous recombination up to 20-fold. Enhancement is specific to the Z-DNA motif; a control DNA fragment of similar size does not alter the recombination frequency. The stimulation of recombination is observed at a distance (237 to 1,269 base pairs away from the Z-DNA motif) and involves both gene conversion and reciprocal exchange events. Maximum stimulation is observed when the sequence is present in both substrates, but it is capable of stimulating when present in only one substrate. Analysis of recombination products indicates that the Z-DNA motif increases the frequency and alters the distribution of multiple, unselected recombination events. Specifically designed crosses indicate that the substrate containing the Z-DNA motif preferentially acts as the recipient of genetic information during gene conversion events. Models describing how left-handed Z-DNA sequences might promote the initiation of homologous recombination are presented.     

DOES RECOMBINATION CONSTRAIN NEUTRAL DIVERGENCE AMONG BACTERIAL TAXA?

A coalescence model for predicting the fate of neutral divergence among closely related taxa distinguishable as separate DNA sequence clusters is presented here. The model simulates iteratively the positive feedback between sequence divergence and sexual isolation among taxa, where increases in sequence divergence result in reduced recombination, and reduced recombination results in increased sequence divergence. Iteration of this feedback is continued until sequence divergence either converges on a steady state or reaches a runaway process. The eventual outcome of sequence divergence was shown to depend on four estimable population-genetic parameters: the expected intrataxon sequence diversity, the baseline rate of intertaxon recombination, the sensitivity of the recombination rate to sequence divergence, and the neutral mutation rate. The model can be used to determine whether neutral divergence among actual taxa is destined to stop at an equilibrium level, or whether neutral divergence will reach a runaway process. Application of the model to the group of taxa containing Bacillus subtilis and its closest relatives showed these taxa to be on a trajectory of unbounded neutral divergence from one another.     

Population and evolutionary dynamics of Helitron transposable elements in Arabidopsis thaliana

Helitrons, a recently discovered superfamily of DNA transposons that capture host gene fragments, constitute up to 2% of the Arabidopsis thaliana genome. In this study, we identified 565 insertions of a family of nonautonomous Helitrons, known as Basho elements. We aligned subsets of these elements, estimated their phylogenetic relationships, and used branch lengths to yield insight into the age of each Basho insertion. The age distribution suggests that 87% of Bashos inserted within 5 Myr, subsequent to the divergence between A. thaliana and its sister species Arabidopsis lyrata. We screened 278 of these insertions for their presence or absence in a sample of 47 A. thaliana accessions. With both phylogenetic and population frequency data, we investigated the effects of gene density, recombination rate, and element length on Basho persistence. Our analyses suggested that longer Basho copies are less likely to persist in the genome, consistent with selection against the deleterious effects of ectopic recombination between Basho elements. Furthermore, we determined that 39% of Basho elements contain fragments of expressed protein-coding genes, but all of these fragments were explained by only 5 gene-capture events. Overall, the picture of A. thaliana Helitron evolution is one of rapid expansion, relatively few gene-capture events, and weak selection correlated with element length.     

产生无标记农杆菌突变体方法的建立及优化

农杆菌已经用作许多生物过程研究的模型细菌,为了解析这些生物过程的分子机理,对农杆菌的某些基因进行突变就显得非常重要．以自杀性基因sacB作为反向可选择性标记基因,利用同源重组的原理,建立了一种可对农杆菌基因进行准确插入、删除和位点置换的突变方法,所获突变体不带任何不需要的外源DNA序列．通过详细研究同源序列的长度对农杆菌同源重组效率和突变体产生概率的影响,以及对农杆菌中的同源重组机理的分析,提出了优化该突变体产生方法的方案,即通过设计不等长的上下游同源序列和选择其中一种类型的单交换重组体来筛选二次交换重组体的方法,可以显著地提高理想突变体的产生概率．研究结果对如何提高突变体的产生概率和减少突变体筛选的工作量具重要的参考价值．利用该方法成功地获得了两个基因被同时删除而且不含抗性标记的农杆菌突变株．     

Evolution of paralogous genes: Reconstruction of genome rearrangements through comparison of multiple genomes within Staphylococcus aureus

Analysis of evolution of paralogous genes in a genome is central to our understanding of genome evolution. Comparison of closely related bacterial genomes, which has provided clues as to how genome sequences evolve under natural conditions, would help in such an analysis. With species Staphylococcus aureus, whole-genome sequences have been decoded for seven strains. We compared their DNA sequences to detect large genome polymorphisms and to deduce mechanisms of genome rearrangements that have formed each of them. We first compared strains N315 and Mu50, which make one of the most closely related strain pairs, at the single-nucleotide resolution to catalogue all the middle-sized (more than 10 bp) to large genome polymorphisms such as indels and substitutions. These polymorphisms include two paralogous gene sets, one in a tandem paralogue gene cluster for toxins in a genomic island and the other in a ribosomal RNA operon. We also focused on two other tandem paralogue gene clusters and type I restriction-modification (RM) genes on the genomic islands. Then we reconstructed rearrangement events responsible for these polymorphisms, in the paralogous genes and the others, with reference to the other five genomes. For the tandem paralogue gene clusters, we were able to infer sequences for homologous recombination generating the change in the repeat number. These sequences were conserved among the repeated paralogous units likely because of their functional importance. The sequence specificity (S) subunit of type I RM systems showed recombination, likely at the homology of a conserved region, between the two variable regions for sequence specificity. We also noticed novel alleles in the ribosomal RNA operons and suggested a role for illegitimate recombination in their formation. These results revealed importance of recombination involving long conserved sequence in the evolution of paralogous genes in the genome.     

V(D)J recombination frequencies can be profoundly affected by changes in the spacer sequence

Each V, D, and J gene segment is flanked by a recombination signal sequence (RSS), composed of a conserved heptamer and nonamer separated by a 12- or 23-bp spacer. Variations from consensus in the heptamer or nonamer at specific positions can dramatically affect recombination frequency, but until recently, it had been generally held that only the length of the spacer, but not its sequence, affects the efficacy of V(D)J recombination. In this study, we show several examples in which the spacer sequence can significantly affect recombination frequencies. We show that the difference in spacer sequence alone of two V(H)S107 genes affects recombination frequency in recombination substrates to a similar extent as the bias observed in vivo. We show that individual positions in the spacer can affect recombination frequency, and those positions can often be predicted by their frequency in a database of RSS. Importantly, we further show that a spacer sequence that has an infrequently observed nucleotide at each position is essentially unable to support recombination in an extrachromosmal substrate assay, despite being flanked by a consensus heptamer and nonamer. This infrequent spacer sequence RSS shows only a 2-fold reduction of binding of RAG proteins, but the in vitro cleavage of this RSS is approximately 9-fold reduced compared with a good RSS. These data demonstrate that the spacer sequence should be considered to play an important role in the recombination efficacy of an RSS, and that the effect of the spacer occurs primarily subsequent to RAG binding.     

The coupling of crossing over and homologous synapsis in maize inversions

Because fresh initiations of synapsis must occur for homologous synapsis of internal heterozygously inverted chromosome segments, attention has been directed at homologous synapsis and crossing over in overlapping paracentric inversions in the long arm of chromosome 1 of maize. In an earlier study with a relatively short inversion (where double crossovers within the inversion were rare), a recombination nodule (RN) was generally found at pachytene in reverse paired (homologously synapsed) inverted regions. Crossover frequency within the inversion, which could be independently estimated from analysis of bridge and fragment frequency at anaphase I and II, closely corresponded to crossover frequency estimated from observed RN frequency in pachytene inversion loops. These findings were consistent with the interpretation that establishment of homologous synapsis in this case is generally coupled to crossing over. This coupling suggests that there is very early commitment to the form of resolution of recombination intermediates that results in reciprocal recombination events instead of conversion only or other noncrossover events. This study examines another, larger paracentric inversion in the long arm of chromosome 1 that completely overlaps the first inversion. It is sufficiently longer than the first inversion that double crossover events are found within it with substantial frequency and interference considerations are feasible. This study confers additional insight into the interrelationships of synapsis and crossing over and the probable sequence in which the various involved processes usually occur. It raises the strong possibility that crossovers can be initiated during the alignment phase that precedes synapsis.     

The effect of sequence divergence on recombination between direct repeats in Arabidopsis

It is well established that sequence divergence has an inhibitory effect on homologous recombination. However, a detailed analysis of this relationship is missing for most higher eukaryotes. We have measured the rate of somatic recombination between direct repeats as a function of the number, type, and position of divergent nucleotides in Arabidopsis. We show that a minor divergence level of 0.16% (one mutation in otherwise identical 618 bp) has a profound effect, decreasing the recombination rate approximately threefold. A further increase in the divergence level affects the recombination rate to a smaller extent until a "divergence saturation" effect is reached at relatively low levels of divergence ( approximately 0.5%). The type of mismatched nucleotide does not affect recombination rates. The decrease in the rate of recombination caused by a single mismatch was not affected by the position of the mismatch along the repeat. This suggests that most recombination intermediate tracts contain a mismatch and thus are as long as the full length of the 618-bp repeats. Finally, we could deduce an antirecombination efficiency of approximately 66% for the first mismatch in the repeat. Altogether, this work shows some degree of conservation across kingdoms when compared to previous reports in yeast; it also provides new insight into the effect of sequence divergence on homologous recombination.     

The Contribution of Alu Elements to Mutagenic DNA Double-Strand Break Repair

Alu elements make up the largest family of human mobile elements, numbering 1.1 million copies and comprising 11% of the human genome. As a consequence of evolution and genetic drift, Alu elements of various sequence divergence exist throughout the human genome. Alu/Alu recombination has been shown to cause approximately 0.5% of new human genetic diseases and contribute to extensive genomic structural variation. To begin understanding the molecular mechanisms leading to these rearrangements in mammalian cells, we constructed Alu/Alu recombination reporter cell lines containing Alu elements ranging in sequence divergence from 0%-30% that allow detection of both Alu/Alu recombination and large non-homologous end joining (NHEJ) deletions that range from 1.0 to 1.9 kb in size. Introduction of as little as 0.7% sequence divergence between Alu elements resulted in a significant reduction in recombination, which indicates even small degrees of sequence divergence reduce the efficiency of homology-directed DNA double-strand break (DSB) repair. Further reduction in recombination was observed in a sequence divergence-dependent manner for diverged Alu/Alu recombination constructs with up to 10% sequence divergence. With greater levels of sequence divergence (15%-30%), we observed a significant increase in DSB repair due to a shift from Alu/Alu recombination to variable-length NHEJ which removes sequence between the two Alu elements. This increase in NHEJ deletions depends on the presence of Alu sequence homeology (similar but not identical sequences). Analysis of recombination products revealed that Alu/Alu recombination junctions occur more frequently in the first 100 bp of the Alu element within our reporter assay, just as they do in genomic Alu/Alu recombination events. This is the first extensive study characterizing the influence of Alu element sequence divergence on DNA repair, which will inform predictions regarding the effect of Alu element sequence divergence on both the rate and nature of DNA repair events.     

Estimating recombinational parameters in Streptococcus pneumoniae from multilocus sequence typing data

Multilocus sequence typing (MLST) is a highly discriminatory molecular typing method that defines isolates of bacterial pathogens using the sequences of approximately 450-bp internal fragments of seven housekeeping genes. This technique has been applied to 575 isolates of Streptococcus pneumoniae and identifies a number of discrete clonal complexes. These clonal complexes are typically represented by a single group of isolates sharing identical alleles at all seven loci, plus single-locus variants that differ from this group at only one out of the seven loci. As MLST is highly discriminatory, the members of each clonal complex can be assumed to have a recent common ancestor, and the molecular events that give rise to the single-locus variants can be used to estimate the relative contributions of recombination and mutation to clonal divergence. By comparing the sequences of the variant alleles within each clonal complex with the allele typically found within that clonal complex, we estimate that recombination has generated new alleles at a frequency approximately 10-fold higher than mutation, and that a single nucleotide site is approximately 50 times more likely to change through recombination than mutation. We also demonstrate how to estimate the average length of recombinational replacements from MLST data.     

Homologous recombination between plasmid and chromosomal DNA in Bacillus subtilis requires approximately 70 bp of homology

Summary To determine the minimal DNA sequence homology required for recombination in Bacillus subtilis, we developed a system capable of distinguishing between homologous and illegitimate recombination events during plasmid integration into the chromosome. In this system the recombination frequencies were measured between is pE194 derivatives carrying segments of the chromosomal -gluconase gene (bglS) of various lengths and the bacterial chromosome, using selection for erythromycin resistance at the non-permissive temperature. Homologous recombination events, resulting in disruption of the bglS gene, were easily detected by a colorimetric assay for -gluconase activity. A linear dependence of recombination frequency on homology length was observed over an interval of 77 bp. It was found that approximately 70 bp of homology is required for detectable homologous recombination. Homologous recombination was not detected when only 25 by of homology between plasmid and chromosome were provided. The data indicate that homology requirements for recombination in B. subtilis differ from those in Escherichia coli.     

Character compatibility of molecular markers to distinguish asexual and sexual reproduction

Particularly in polyploids, the potential of the high variability of dominant markers such as random amplified polymorphic DNA fragments (RAPDs) and amplified fragment length polymorphisms (AFLPs) in population genetic studies and analysis of breeding systems is reduced due to their dominant nature. In contrast, the criterion of character compatibility is hindered neither by dominance nor by polyploidy as allelic interpretation is not necessary. Character compatibility, which can be used to detect events of genetic exchange (or recombination), is particularly informative if these events are expected to be rare such as in taxa with extensive vegetative reproduction or apomixis. Binary unordered characters such as presence and absence of anonymous DNA markers are incompatible if all four pairwise combinations of character states are present among the individuals studied. Because incompatible character state distributions defy any progenitor–derivative relationship among individuals, they provide strong evidence for genetic exchange. Both the absolute number of incompatible character combinations and the probability of compatibility can be used as a measure of incompatibility. Although these measures may not directly relate to the frequency of genetic exchange, they provide a useful tool to heuristically explore data sets. The most commonly used input for multivariate analyses and analysis of molecular variance in population genetic studies of (dis)similarity of marker distributions are amalgamates of mutation and recombination. Character compatibility can be used to complement these traditional methods of analysis. Advantages and disadvantages of character incompatibility relative to multilocus analysis of modes of reproduction and population genetics are demonstrated with data from RAPDs, isozymes, and restriction fragment length polymorphisms (RFLPs) of the nuclear ribosomal and chloroplast genome.     

The centromere1 (CEN1) region of Arabidopsis thaliana: architecture and functional impact of chromatin

We have analysed the centromere 1 (CEN1) of Arabidopsis thaliana by integration of genetic, sequence and fluorescence in situ hybridisation (FISH) data. CEN1 is considered to include the centromeric core and the flanking left and right pericentromeric regions, which are distinct parts by structural and/or functional properties. CEN1 pericentromeres are composed of different dispersed repetitive elements, sometimes interrupted by functional genes. In contrast the CEN1 core is more uniformly structured harbouring only two different repeats. The presented analysis reveals aspects concerning distribution and effects of the uniformly shaped heterochromatin, which covers all CEN1 regions. A lethal mutation tightly linked to CEN1 enabled us to measure recombination frequencies within the heterochromatin in detail. In the left pericentromere, the change from eu- to heterochromatin is accompanied by a gradual change in sequence composition but by an extreme change in recombination frequency (from normal to 53-fold decrease) which takes place within a small region spanning 15 kb. Generally, heterochromatin is known to suppress recombination. However, the same analysis reveals that left and right pericentromere, though similar in sequence composition, differ markedly in suppression (53-fold versus 10-fold). The centromeric core exhibits at least 200-fold if not complete suppression. We discuss whether differences in (fine) composition reflect quantitative and qualitative differences in binding sites for heterochromatin proteins and in turn render different functional properties. Based on the presented data we estimate the sizes of Arabidopsis centromeres. These are typical for regional centromeres of higher eukaryotes and range from 4.4 Mb (CEN1) to 3.55 Mb (CEN4).