Generation of DNA double-strand breaks by two independent enzymatic activities in nuclear extracts

We have reported the existence in rat nuclear extracts of a specific cleavage activity on a DNA fragment containing the human minisatellite MsH42 region (minisatellite plus its flanking sequences). Here, we have developed a system to analyse the nature of the cleavage products from the MsH42 region generated by the nuclear extracts. Our results demonstrated the formation of DNA double-strand breaks (DSB) in the MsH42 region by two different enzymatic activities, and that their distribution along this fragment changes depending on the presence of Mg2+. In the assays with Mg2+, the DSB were located in the minisatellite and its 3'-flanking region, showing preference for G-rich stretches. Oligonucleotide mutagenesis analysis confirmed that this enzymatic activity has a strong preference for G-tracts and that the recognition site is polarized towards the 3' end. Moreover, this activity cuts GC palindromes efficiently. In contrast, in the experiments without Mg2+, most DSB were mapped within the minisatellite flanking sequences. The analysis with oligonucleotides showed that G-tracts are recognized by this endonuclease activity, but with differences in the cleavage behaviour with respect to the reactions observed with Mg2+. The existence of two separate activities (Mg2+-dependent and Mg2+-independent) for the production of DSB was confirmed by analysing the effect of EGTA, N-ethyl maleimide, ionic strength, and by preincubations of the nuclear extracts at different temperatures. The tissue distribution of both DSB-producing activities was also different. The in vitro system used in the present work may be a useful tool for studying the formation of DSB and for investigation of the mechanisms of DNA repair.     

Birth and evolutionary history of a human minisatellite

One of the most exciting challenges in human biology is the understanding of how our genome was constructed during evolution. Here we explore the evolutionary history of the low polymorphic human minisatellite MsH42 and its flanking sequences. We show that the evolutionary birth of MsH42 took place within an intron, early in primate lineage evolution, more than 40 MYA. Then, single base-pair changes and duplications/deletions of repeat blocks by mispairing were probably the main forces governing the generation of this minisatellite and its polymorphism throughout primate evolution. Moreover, we detected several phylogenetic footprints at both sides of MsH42. We believe that our findings will contribute to the understanding of low-variability minisatellite evolution.     

Inhibition of DNA synthesis by K+-stabilised G-quadruplex promotes allelic preferential amplification

PCR preferential amplification consists of the inefficient amplification of one allele in a heterozygous sample. Here, we report the isolation of a GC-rich human minisatellite, MsH43, that undergoes allelic preferential amplification during PCR. This effect requires the existence of a (TGGGGC)(4) motif that is able to form a G-quadruplex in the presence of K(+). This structure interferes with the DNA synthesis of the alleles harbouring this motif during PCR The present results are the first demonstration that the formation of G-quadruplex can be one of the mechanisms involved in some kinds of preferential amplification.     

Evolution of a complex minisatellite DNA sequence

Minisatellites are tandem repeats of short DNA units widely distributed in genomes. However, the information on their dynamics in a phylogenetic context is very limited. Here we have studied the organization of the MsH43 locus in several species of primates and from these data we have reconstructed the evolutionary history of this complex minisatellite. Overall, with the exception of gibbon, MsH43 has an organization that is asymmetric, since the distribution of repeats is distinct between the 5' and 3' halves, and heterogeneous since there are many different repeats, some of them characteristic of each species. Inspection of the MsH43 arrays showed the existence of many duplications and deletions, suggesting the implication of slippage processes in the generation of polymorphism. Concerning the evolutionary history of this minisatellite, we propose that the birth of MsH43 may be situated before the divergence of Old World Monkeys since we found the existence of some MsH43 repeat motifs in prosimians and New World Monkeys. The analysis of MsH43 in apes revealed the existence of an evolutionary breakpoint in the pathway that originated African great apes and humans. Remarkably, human MsH43 is more homologous to orang-utan than to the corresponding sequence in gorilla and chimpanzee. This finding does not comply with the evolutionary paradigm that continuous alterations occur during the course of genome evolution. To adjust our results to the standard phylogeny of primates, we propose the existence of a wandering allele that was maintained almost unaltered during the period that extends between orang-utan and humans.     

Mismatch Repair-Induced Meiotic Recombination Requires the Pms1 Gene Product

The presence of multiple heterologies in a 9-kilobase (kb) interval results in a decrease in meiotic crossovers from 26.0% to 10.1%. There is also an increase from 3.5% to 11.1% in gene conversions and ectopic recombinations between the flanking homologous MAT loci. The hypothesis that mismatch repair of heteroduplex DNA containing several heterologies would lead to a second round of recombination has now been tested by examining the effect of a mutation that reduces mismatch correction. The repair-defective pms1-1 allele restores the pattern of recombination to nearly that seen in congenic diploids without the heterologies. Mismatch repair-induced recombination causes a significant increase in MAT conversions and ectopic recombination events with as few as two heterozygosities separated by 0.3-0.7 kb, but not when the mismatches are separated by greater than 1 kb. The frequency of these events depends on both the number and position of the heterozygosities relative to the flanking homologous MAT loci used to detect the events. The creation of recombinogenic lesions by mismatch repair in yeast could be analogous to the creation of recombinogenic lesions in dam- Escherichia coli. We suggest that the repair of heteroduplex DNA containing multiple mismatches may produce chromosomal rearrangements and gamete inviability when naturally polymorphic chromosomes undergo meiotic recombination.     

The Chi-like sites free minisatellite insertion in plasmids of pSV2neo family directs conversion of reporter neo gene in LM cell line

Minisatellite loci show variability in copy number of repeat units probably due to their recombinogenic activity. In the presence of minisatellites with Chi-similar sites in plasmids the enhanced frequency of homologous recombination of defective plasmids copies of selectable gene was shown. In this work we have estimated recombinogenic activity of minisatellite DNAs without Chi-similar sites. The restoration frequency of a neo gene and the ratio of restored and not restored copies of this gene in genomic DNA of transformed clones was quantitatively estimated. We conclude that the presence of minisatellite insertion without Chi-similar sites stimulates events of gene conversion in adjacent DNA of plasmids. Plasmids with minisatellites act as acceptors of genetic information.     

Repeat instability at human minisatellites arising from meiotic recombination.

Little is known about the role of meiotic recombination processes such as unequal crossover in driving instability at tandem repeat DNA. Methods have therefore been developed to detect meiotic crossovers within two different GC-rich minisatellite repeat arrays in humans, both in families and in sperm DNA. Both loci normally mutate in the germline by complex conversion-like transfer of repeats between alleles. Analysis shows that inter-allelic unequal crossovers also occur at both loci, although at low frequency, to yield simple recombinant repeat arrays with exchange of flanking markers. Equal crossovers between aligned alleles, resulting in recombinant alleles but without change in repeat copy number, also occur in sperm at a similar frequency to unequal crossovers. Both crossover and conversion show polarity in the repeat array and are co-suppressed in an allele showing unusual germline stability. This provides evidence that minisatellite conversion and crossover arise by a common mechanism, perhaps by alternative processing of a meiotic recombination initiation complex, and implies that minisatellite instability is a by-product of meiotic recombination in repeat DNA. While minisatellite recombination is infrequent, crossover rates indicate that the unstable end of a human minisatellite can act as a recombination warm-spot, even between sequence-heterologous alleles.     

Ac Induces Homologous Recombination at the Maize P Locus

The maize P gene conditions red phlobaphene pigmentation to the pericarp and cob. Starting from two unstable P alleles which carry insertions of the transposable element Ac, we have derived 51 P null alleles; 47 of the 51 null alleles have a 17-kb deletion which removes the 4.5-kb Ac element and 12.5 kb of P sequences flanking both sides of Ac. The deletion endpoints lie within two 5.2-kb homologous direct repeats which flank the P gene. A P allele which contains the direct repeats, but does not have an Ac insertion between the direct repeats, shows very little sporophytic or gametophytic instability. The apparent frequency of sporophytic mutations was not increased when Ac was introduced in trans. Southern analysis of DNA prepared from the pericarp tissue demonstrates that the deletions can occur premeiotically, in the somatic cells during development of the pericarp. Evidence is presented that the deletions occurred by homologous recombination between the two direct repeats, and that the presence of an Ac element at the P locus is associated with the recombination/deletion. These results add another aspect to the spectrum of activities of Ac: the destabilization of flanking direct repeat sequences.     

Minisatellite variants generated in yeast meiosis involve DNA removal during gene conversion

Two yeast minisatellite alleles were cloned and inserted into a genetically defined interval in Saccharomyces cerevisiae. Analysis of flanking markers in combination with sequencing allowed the determination of the meiotic events that produced minisatellites with altered lengths. Tetrad analysis revealed that gene conversions, deletions, or complex combinations of both were involved in producing minisatellite variants. Similar changes were obtained following selection for nearby gene conversions or crossovers among random spores. The largest class of events involving the minisatellite was a 3:1 segregation of parental-size alleles, a class that would have been missed in all previous studies of minisatellites. Comparison of the sequences of the parental and novel alleles revealed that DNA must have been removed from the recipient array while a newly synthesized copy of donor array sequences was inserted. The length of inserted sequences did not appear to be constrained by the length of DNA that was removed. In cases where one or both sides of the insertion could be determined, the insertion endpoints were consistent with the suggestion that the event was mediated by alignment of homologous stretches of donor/recipient DNA.     

Inhibition of DNA topoisomerase II may trigger illegitimate recombination in living cells: experiments with a model system

We have developed a plasmid test system to study recombination in vitro and in mammalian cells in vivo, and to analyze the possible role of DNA topoisomerase II. The system is based on a plasmid construct containing an inducible marker gene ccdB ("killer" (KIL) gene) whose product is lethal for bacterial cells, flanked by two different potentially recombinogenic elements. The plasmids were subjected to recombinogenic conditions in vitro or in vivo after transient transfection into COS-1 cells, and subsequently transformed into E. coli which was then grown in the presence of the ccdB gene inducer. Hence, all viable colonies contained recombinant plasmids since only recombination between the flanking regions could remove the KIL gene. Thus, it was possible to detect recombination events and to estimate their frequency. We found that the frequency of topoisomerase II-mediated recombination in vivo is significantly higher than in a minimal in vitro system. The presence of VM-26, an inhibitor of the religation step of the topoisomerase II reaction, increased the recombination frequency by 60%. We propose that cleavable complexes of topoisomerase II are either not religated, triggering error-prone repair of the DNA breaks, or are incorrectly religated resulting in strand exchange. We also studied the influence of sequences known to contain preferential breakpoints for recombination in vivo after chemotherapy with topoisomerase II-targeting drugs, but no preferential stimulation of recombination by these sequences was detected in this non-chromosomal context.     

Positive selection and interallelic recombination at the merozoite surface antigen-1 (MSA-1) locus of Plasmodium falciparum.

DNA sequences of alleles at the merozoite surface antigen-1 (MSA-1) gene locus of the malaria parasite Plasmodium falciparum show evidence of repeated past recombination events between alleles. These include both (1) nonreciprocal recombination events that have homogenized certain gene regions among alleles and (2) reciprocal recombination events that have combined allelic segments with divergent evolutionary histories, thereby enhancing allelic diversity. In three different gene regions, the rate of nonsynonymous nucleotide substitution significantly exceeds that of synonymous nucleotide substitution, implying that positive Darwinian selection has acted to diversify alleles at the amino acid level. The MSA-1 polymorphism seems to be quite ancient; the two major allelic types have been maintained for approximately 35 Myr.     

Meiotic interallelic conversion at the human minisatellite MS32 in yeast triggers recombination in several chromatids

Tandem repetitive DNA sequences such as minisatellites include the most polymorphic loci yet identified in the human genome. The high mutation rates at many of these loci are driven by incompletely understood recombination-based mechanisms that operate in the germline. To analyse aspects of minisatellite mutation processes and general eukaryotic recombination in meiosis that cannot be studied in humans or other mammals, including crosstalk and interplay between all four chromatids, we have previously constructed a eukaryotic model system, enabling the analysis of all four products of meiosis. In this system we have integrated alleles of the human minisatellite MS32, flanked by synthetic markers, in the vicinity of a meiotic recombination hot spot in chromosome III of Saccharomyces cerevisiae. In the present study, tetrad analysis showed that gene conversion is the predominant and possibly the universal pathway leading to interallelic transfer of repeats, with or without exchange of flanking regions. The data also suggest a hyper-recombinogenic state, triggered by interallelic mutation processes which generate a cascade of mutant alleles in the same meiosis. A number of tetrads contained identical mutant alleles of meiotic origin. Several tetrads could not be explained by the current models for minisatellite mutation. Accordingly, we here present a modified model based on the successive repair of multiple double-strand breaks.     

Mutations at the human minisatellite MS32 integrated in yeast occur with high frequency in meiosis and involve complex recombination events

Minisatellites are composed of tandem repetitive DNA sequences and are present at many positions in the human genome. They frequently mutate to new length alleles in the germline, by complex and incompletely understood recombination mechanisms which may operate during meiosis. In several minisatellites the mutation events are restricted to one end of the repeat array, indicating a possible association with elements that act in cis. Mutant alleles do not show exchange of flanking regions. To construct a model system suitable for further investigations of the mutation process, we have integrated the human minisatellite MS32, flanked by synthetic markers, in the vicinity of a meiotic recombination hot spot upstream of the LEU2 locus in the yeast Saccharomyces cerevisiae. Here we provide direct evidence for a meiotic origin of MS32 mutations. Mutation events were polarised towards both ends of the minisatellite and varied from simple duplications and deletions to complex intra- and interallelic events. Interallelic events were frequently accompanied by exchange of regions flanking the minisatellite. The results also support the notion that cis-acting elements are involved in the mutational process. The fact that MS32 mutant structures are similar in yeast and human shows that meiotic recombination plays a crucial role in both organisms and emphasises the usefulness of yeast strains harbouring minisatellites as a model system for the study of minisatellite mutation. Received: 1 March 1997 / Accepted: 16 May 1997     

Unequal crossingover between homologous chromosomes is not the major mechanism involved in the generation of new alleles at VNTR loci

To investigate the hypothesis that unequal exchange between homologous chromosomes is involved when new alleles are generated at VNTR loci, we used genetic linkage maps to identify flanking markers surrounding a VNTR marker locus. The minisatellite probe lambda MS1 was selected, as the hypervariable locus it detects undergoes spontaneous generation of new alleles in the germline at a rate of approximately 5%. Multipoint linkage analysis placed lambda MS1 within a cluster of polymorphic marker loci on chromosome 1p. Using the two closest flanking markers, CMM8 and YNZ2, we were able to characterize 12 new-allele events in terms of crossingover between the flanking markers. Statistical analysis of these data has allowed us to reject the model that assumes that events generating new alleles always involve unequal exchange between homologous chromosomes at meiosis.     

Mechanisms of human minisatellite mutation in yeast

Minisatellites are tandem repeat loci, with repeat units ranging in size from 5 bp to 100 bp. The total lengths of repeat arrays vary from about 0.5 kb to 30 kb, and excessive variability in allele length at human minisatellite loci is the result of germline-specific complex recombination events generating new length alleles. Minisatellite alleles also mutate to new lengths in somatic cells, but this occurs at a much lower rate than in the germline. Since recombination is involved in minisatellite mutation, the yeast Saccharomyces cerevisiae is a suitable model organism that has been employed to further dissect the molecular basis of mutation events at human minisatellites. These studies have shown that the mutational behaviour of a minisatellite in meiosis is not determined by the intrinsic properties of the repeat array, but are highly dependent on the position of the minisatellite in the genome. The processes for minisatellite mutation in yeast and humans are identical in the sense that mutation is indeed driven by meiotic recombination, but differ with regard to the types of structural changes that are generated by the recombination events. Tetrad analyses showed that inter-allelic transfers of repeats occur by conversion and not crossing over, and that several chromatids can be involved in successive recombination events in one meiosis, resulting in mutant alleles in several spores. It has been demonstrated that the genes SPO11 and RAD50, involved in the initiation of recombination events, are required for human minisatellite mutation in yeast meiosis. Intrinsic properties of the repeat array appear to determine the stability of human minisatellites in yeast mitosis, since mitotic mutation rates in yeast are highly variable between minisatellites. The repair genes RAD27 and DNA2 stabilise human minisatellites in yeast mitosis, while RAD5 has no effect on mitotic stability. MSH2 depresses human minisatellite frequency in meiotic cells of yeast.     

The construction of a cloning vector designed for gene replacement in Bordetella pertussis

We report here the construction of a plasmid cloning vector, pRTP1, designed to facilitate exchange of cloned and chromosomal alleles of the human bacterial pathogen Bordetella pertussis. pRTP1 provides the ability to successively select two homologous recombination events within the cloned sequences. The first is by selection for maintenance of the ampicillin-resistance gene on the plasmid which is unable to replicate autonomously after transfer via conjugation. The second selection, via streptomycin (Sm) selection, is against the maintenance of vector sequences which contain a gene encoding the Sm-sensitive allele of the gene for ribosomal protein S12 thus rendering an otherwise Sm-resistant strain Sm-sensitive. We demonstrate the use of this vector to introduce an unmarked mutation, constructed in vitro, into the chromosomal locus encoding pertussis toxin.     

Use of two gRNAs for CRISPR/Cas9 improves bi‐allelic homologous recombination efficiency in mouse embryonic stem cells

Targeted genome editing in mouse embryonic stem cells (ESCs) is a powerful resource to functionally characterize genes and regulatory elements. The use of the CRISPR/Cas9 genome editing approach has remarkably improved the time and efficiency of targeted recombination. However, the efficiency of this protocol is still far from ideal when aiming for bi‐allelic homologous recombination, requiring at least two independent targeting recombination events. Here we describe an improved protocol that uses two gRNAs flanking the selected targeted region, leading to highly efficient homologous recombination in mouse ESCs. The bi‐allelic recombination targeting efficiency is over 90% when using two gRNAs together with the inhibition of non‐homologous end‐joint repair. Moreover, this technique is compatible with the generation of knocked‐in mice and the use of ESC‐derived differentiation protocols, therefore facilitating and accelerating the gene targeting in mice and ESCs.     

Mitotic gene conversion lengths, coconversion patterns, and the incidence of reciprocal recombination in a Saccharomyces cerevisiae plasmid system.

Plasmids capable of undergoing genetic exchange in mitotically dividing Saccharomyces cerevisiae cells were used to measure the length of gene conversion events, to determine patterns of coconversion when multiple markers were present, and to correlate the incidence of reciprocal recombination with the length of conversion tracts. To construct such plasmids, restriction site linkers were inserted both within the HIS3 gene and in the flanking sequences, and two different his3- alleles were placed in a vector. Characterization of the genetic exchanges in these plasmids showed that most occur with the conversion of one his3- allele. Many of these events included coconversions in which more than one marker along the allelic sequence was replaced. The frequency of coconversion decreased with the distance between two markers such that markers further than 1 kilobase apart were infrequently coconverted. From these results the average length of conversion was determined to be approximately 0.5 kilobase. Examination of coconversions involving three or more markers revealed an almost obligatory, simultaneous coconversion pattern of all markers. Thus, when two markers which flank an intervening marker are converted, the intervening marker is 20 times more likely to be converted than to remain unchanged. The results of these studies also showed that the incidence of reciprocal recombination, which accompanies more than 20% of the conversion events, is more frequent when the conversion tract is longer than average.     

Alleles of the hotspot cog are codominant in effect on recombination in the his-3 region of Neurospora

There are two naturally occurring functional alleles of the recombination hotspot cog, which is located 3.5 kb from the his-3 locus of Neurospora crassa. The presence of the cog+ allele in a cross significantly increases recombination in the his-3 region compared to a cross homozygous for the cog allele. Data obtained shortly after discovery of cog+ suggested that it was fully dominant to cog. However, a dominant cog+ conflicts with observations of hotspots in Saccharomyces cerevisiae and Schizosaccharomyces pombe, in which recombination is initiated independently of homolog interactions, and suggests recombination mechanisms may differ in Neurospora and yeast. We present evidence that cog alleles are codominant in effect on both allelic recombination in his-3 and crossing over between loci flanking his-3. In addition, we show that genetic background variation has at least a twofold effect on allelic recombination. We speculate that variation in genetic background, together with the complexities of recombination in crosses bearing close mutant alleles, accounts for the previous conclusion that cog+ is dominant to cog.