Intermediates of yeast meiotic recombination contain heteroduplex DNA.

The formation of heteroduplex DNA features prominently in all models for homologous recombination. A central intermediate in the current double-strand break repair model contains two Holliday junctions flanking a region of heteroduplex DNA. Studies of yeast meiosis have identified such intermediates but failed to detect associated heteroduplex DNA. We show here that these intermediates contain heteroduplex DNA, providing an important validation of the double-strand break repair model. However, we also detect intermediates where both Holliday junctions are to one side of the initiating DSB site, while the intervening region shows no evidence of heteroduplex DNA. Such structures are not easily accommodated by the canonical version of the double-strand break repair model.

Differential timing and control of noncrossover and crossover recombination during meiosis.

Unitary models of meiotic recombination postulate that a central intermediate containing Holliday junctions is resolved to generate either noncrossover or crossover recombinants, both of which contain heteroduplex DNA. Contrary to this expectation, we find that during meiosis in Saccharomyces cerevisiae, noncrossover heteroduplex products are formed at the same time as Holliday junction intermediates. Crossovers appear later, when these intermediates are resolved. Furthermore, noncrossover and crossover recombination are regulated differently. ndt80 mutants arrest in meiosis with unresolved Holliday junction intermediates and very few crossovers, while noncrossover heteroduplex products are formed at normal levels and with normal timing. These results suggest that crossovers are formed by resolution of Holliday junction intermediates, while most noncrossover recombinants arise by a different, earlier pathway.

Meiotic recombination: breaking the genome to save it.

Recombination ensures the correct segregation of chromosomes to gametes during meiosis. Recent studies point to a universal mechanism for initiating meiotic recombination: the formation of double-strand DNA breaks by Spo11p.

Global mapping of meiotic recombination hotspots and coldspots in the yeast Saccharomyces cerevisiae.

In the yeast Saccharomyces cerevisiae, meiotic recombination is initiated by double-strand DNA breaks (DSBs). Meiotic DSBs occur at relatively high frequencies in some genomic regions (hotspots) and relatively low frequencies in others (coldspots). We used DNA microarrays to estimate variation in the level of nearby meiotic DSBs for all 6,200 yeast genes. Hotspots were nonrandomly associated with regions of high G + C base composition and certain transcriptional profiles. Coldspots were nonrandomly associated with the centromeres and telomeres.

Direct coupling between meiotic DNA replication and recombination initiation.

During meiosis in Saccharomyces cerevisiae, DNA replication occurs 1. 5 to 2 hours before recombination initiates by DNA double-strand break formation. We show that replication and recombination initiation are directly linked. Blocking meiotic replication prevented double-strand break formation in a replication-checkpoint-independent manner, and delaying replication of a chromosome segment specifically delayed break formation in that segment. Consequently, the time between replication and break formation was held constant in all regions. We suggest that double-strand break formation occurs as part of a process initiated by DNA replication, which thus determines when meiotic recombination initiates on a regional rather than a cell-wide basis.

Restriction of ectopic recombination by interhomolog interactions during Saccharomyces cerevisiae meiosis.

In Saccharomyces cerevisiae meiosis, recombination occurs frequently between sequences at the same location on homologs (allelic recombination) and can take place between dispersed homologous sequences (ectopic recombination). Ectopic recombination occurs less often than does allelic, especially when homologous sequences are on heterologous chromosomes. To account for this, it has been suggested that homolog pairing (homolog colocalization and alignment) either promotes allelic recombination or restricts ectopic recombination. The latter suggestion was tested by examining ectopic recombination in two cases where normal interhomolog relationships are disrupted. In the first case, one member of a homolog pair was replaced by a homologous (related but not identical) chromosome that has diverged sufficiently to prevent allelic recombination. In the second case, ndj1 mutants were used to delay homolog pairing and synapsis. Both circumstances resulted in a substantial increase in the frequency of ectopic recombination between arg4-containing plasmid inserts located on heterologous chromosomes. These findings suggest that, during normal yeast meiosis, progressive homolog colocalization, alignment, synapsis, and allelic recombination restrict the ability of ectopically located sequences to find each other and recombine. In the absence of such restrictions, the meiotic homology search may encompass the entire genome.

A method for preparing genomic DNA that restrains branch migration of Holliday junctions.

The Holliday junction is a central intermediate in genetic recombination. This four-stranded DNA structure is capable of spontaneous branch migration, and is lost during standard DNA extraction protocols. In order to isolate and characterize recombination intermediates that contain Holliday junctions, we have developed a rapid protocol that restrains branch migration of four-way DNA junctions. The cationic detergent hex-adecyltrimethylammonium bromide is used to lyse cells and precipitate DNA. Manipulations are performed in the presence of the cations hexamine cobalt(III) or magnesium, which stabilize Holliday junctions in a stacked-X configuration that branch migrates very slowly. This protocol was evaluated using a sensitive assay for spontaneous branch migration, and was shown to preserve both artificial Holliday junctions and meiotic recombination intermediates containing four-way junctions.

Saccharomyces cerevisiae checkpoint genes MEC1, RAD17 and RAD24 are required for normal meiotic recombination partner choice.

Checkpoint gene function prevents meiotic progression when recombination is blocked by mutations in the recA homologue DMC1. Bypass of dmc1 arrest by mutation of the DNA damage checkpoint genes MEC1, RAD17, or RAD24 results in a dramatic loss of spore viability, suggesting that these genes play an important role in monitoring the progression of recombination. We show here that the role of mitotic checkpoint genes in meiosis is not limited to maintaining arrest in abnormal meioses; mec1-1, rad24, and rad17 single mutants have additional meiotic defects. All three mutants display Zip1 polycomplexes in two- to threefold more nuclei than observed in wild-type controls, suggesting that synapsis may be aberrant. Additionally, all three mutants exhibit elevated levels of ectopic recombination in a novel physical assay. rad17 mutants also alter the fraction of recombination events that are accompanied by an exchange of flanking markers. Crossovers are associated with up to 90% of recombination events for one pair of alleles in rad17, as compared with 65% in wild type. Meiotic progression is not required to allow ectopic recombination in rad17 mutants, as it still occurs at elevated levels in ndt80 mutants that arrest in prophase regardless of checkpoint signaling. These observations support the suggestion that MEC1, RAD17, and RAD24, in addition to their proposed monitoring function, act to promote normal meiotic recombination.

Use of a recombination reporter insert to define meiotic recombination domains on chromosome III of Saccharomyces cerevisiae.

In Saccharomyces cerevisiae, meiotic recombination is initiated by DNA double-strand breaks (DSBs). DSBs usually occur in intergenic regions that display nuclease hypersensitivity in digests of chromatin. DSBs are distributed nonuniformly across chromosomes; on chromosome III, DSBs are concentrated in two "hot" regions, one in each chromosome arm. DSBs occur rarely in regions within about 40 kb of each telomere and in an 80-kb region in the center of the chromosome, just to the right of the centromere. We used recombination reporter inserts containing arg4 mutant alleles to show that the "cold" properties of the central DSB-deficient region are imposed on DNA inserted in the region. Cold region inserts display DSB and recombination frequencies that are substantially less than those seen with similar inserts in flanking hot regions. This occurs without apparent change in chromatin structure, as the same pattern and level of DNase I hypersensitivity is seen in chromatin of hot and cold region inserts. These data are consistent with the suggestion that features of higher-order chromosome structure or chromosome dynamics act in a target sequence-independent manner to control where recombination events initiate during meiosis.

Competitive inactivation of a double-strand DNA break site involves parallel suppression of meiosis-induced changes in chromatin configuration.

In Saccharomyces cerevisiae, DNA double-strand breaks (DSBs) initiate meiotic recombination at open sites in chromatin, which display a meiosis-specific increase in micrococcal nuclease (MNase) sensitivity. The arg4 promoter contains such a DSB site. When arg4 sequences are placed in a pBR322-derived insert at HIS4 (his4 :: arg4 ), the presence of strong DSB sites in pBR322 sequences leads to an almost complete loss of breaks from the insert-borne arg4 promoter region. Most of the MNase-sensitive sites occurred at similar positions in insert-borne and in normal ARG4 sequences, indicating that hotspot inactivation is not a consequence of changes in nucleosome positioning. However, a meiosis-specific increase in MNase hypersensitivity was no longer detected at the inactive insert-borne arg4 DSB site. Elimination of pBR322 sequences restored DSBs to the insert-borne arg4 promoter region and also restored the meiotic induction of MNase hypersensitivity. Thus, the meiotic induction of MNase hypersensitivity at the DSB sites is suppressed and activated in parallel to DSBs themselves, without changes in the underlying DNA sequence or nucleosome positioning. We suggest that meiosis-specific changes in chromatin at a DSB site are a signal reflecting a pivotal step in DSB formation.

The efficiency of meiotic recombination between dispersed sequences in Saccharomyces cerevisiae depends upon their chromosomal location.

To examine constrains imposed on meiotic recombination by homologue pairing, we measured the frequency of recombination between mutant alleles of the ARG4 gene contained in pBR322-based inserts. Inserts were located at identical loci on homologues (allelic recombination) or at different loci on either homologous or heterologous chromosomes (ectopic recombination). Ectopic recombination between interstitially located inserts on heterologous chromosomes had an efficiency of 6-12% compared to allelic recombination. By contrast, ectopic recombination between interstitial inserts located on homologues had relative efficiencies of 47-99%. These findings suggest that when meiotic ectopic recombination occurs, homologous chromosomes are already colocalized. The efficiency of ectopic recombination between inserts on homologues decreased as the physical distance between insert sites was increased. This result is consistent with the suggestion that during meiotic recombination, homologues are not only close to each other, but also are aligned end to end. Finally, the efficiency of ectopic recombination between inserts near telomeres (within 16 kb) was significantly greater than that observed with inserts > 50 kb from the nearest telomere. Thus, at the time of recombination, there may be a special relationship between the ends of chromosomes not shared with interstitial regions.

The location and structure of double-strand DNA breaks induced during yeast meiosis: evidence for a covalently linked DNA-protein intermediate.

We have determined the precise location and structure of the double-strand DNA breaks (DSBs) formed during Saccharomyces cerevisiae meiosis. Breaks were examined at two recombination hot spots in both wild-type and rad50S mutant cells. At both loci, breaks occurred at multiple, irregularly spaced sites in a approximately 150 nucleotide interval contained within an area of nuclease-hypersensitive chromatin. No consensus sequence could be discerned at or around break sites. Patterns of cleavage observed on individual strands indicated that breaks initially form with a two nucleotide 5' overhang. Broken strands from rad50S mutant cells contained tightly bound protein at their 5' ends. We suggest that, in S.cerevisiae, meiotic recombination is initiated by a DSB-forming activity that creates a covalently linked protein-DNA intermediate.

Factors that affect the location and frequency of meiosis-induced double-strand breaks in Saccharomyces cerevisiae.

Double-strand DNA breaks (DSBs) initiate meiotic recombination in Saccharomyces cerevisiae. DSBs occur at sites that are hypersensitive in nuclease digests of chromatin, suggesting a role for chromatin structure in determining DSB location. We show here that the frequency of DSBs at a site is not determined simply by DNA sequence or by features of chromatin structure. An arg4-containing plasmid was inserted at several different locations in the yeast genome. Meiosis-induced DSBs occurred at similar sites in pBR322-derived portions of the construct at all insert loci, and the frequency of these breaks varied in a manner that mirrored the frequency of meiotic recombination in the arg4 portion of the insert. However, DSBs did not occur in the insert-borne arg4 gene at a site that is frequently broken at the normal ARG4 locus, even though the insert-borne arg4 gene and the normal ARG4 locus displayed similar DNase I hypersensitivity patterns. Deletions that removed active DSB sites from an insert at HIS4 restored breaks to the insert-borne arg4 gene and to a DSB site in flanking chromosomal sequences. We conclude that the frequency of DSB at a site can be affected by sequences several thousand nucleotides away and suggest that this is because of competition between DSB sites for locally limited factors.

Meiotic recombination hotspots.

Meiotic recombination occurs more frequently in some regions of the eukaryotic genome than in others, with variations of several orders of magnitude observed in frequencies of meiotic exchange per unit physical distance. This article reviews what is known abut meiotic recombination hotspots loci, or regions that display a greater than average frequency of meiotic exchange. Hotspots have been most intensively studied in Saccharomyces cerevisiae, which is a major focus of this article. Also reviewed is the current state of knowledge regarding hotspots in other fungi, in maize, in nematodes, in mice, and in humans.

Meiosis-induced double-strand break sites determined by yeast chromatin structure.

Double-strand DNA breaks (DSBs) occur at recombination hotspots during Saccharomyces cerevisiae meiosis and are thought to initiate exchange at these loci. Analysis of DSB sites in three regions of the yeast genome indicated that breaks occur at or near many potential transcription promoters and that DSBs initiate most, if not all, meiotic recombination. DSB sites displayed deoxyribonuclease I hypersensitivity in chromatin from mitotic and meiotic cells, and changes in chromatin structure produced parallel changes in the occurrence of DSBs. Thus, features of chromatin structure that are established before meiosis play a role in determining where meiotic recombination events initiate.

Identification of two divergently transcribed genes centromere-proximal to the ARG4 locus on chromosome VIII of Saccharomyces cerevisiae.

We have sequenced a 3296 bp segment of the chromosome VIII adjacent to the 3' end of the ARG4 gene. This segment contains two divergently oriented open reading frames (YSC83 and YSC84). Northern blot analysis showed the presence of transcripts corresponding to these two open reading frames in vegetative cells. Levels of these transcripts increase five to ten-fold during sporulation. These two genes are not essential for vegetative growth or sporulation. Analysis of the putative protein products on the SwissProt database revealed that the C-terminal region of the Ysc84 protein contains a putative SH3 domain.

Timing of molecular events in meiosis in Saccharomyces cerevisiae: stable heteroduplex DNA is formed late in meiotic prophase.

To better understand the means by which chromosomes pair and recombine during meiosis, we have determined the time of appearance of heteroduplex DNA relative to the times of appearance of double-strand DNA breaks and of mature recombined molecules. Site-specific double-strand breaks appeared early in meiosis and were formed and repaired with a timing consistent with a role for breaks as initiators of recombination. Heteroduplex-containing molecules appeared about 1 h after double-strand breaks and were followed shortly by crossover products and the first meiotic nuclear division. We conclude that parental chromosomes are stably joined in heteroduplex-containing structures late in meiotic prophase and that these structures are rapidly resolved to yield mature crossover products. If the chromosome pairing and synapsis observed earlier in meiotic prophase is mediated by formation of biparental DNA structures, these structures most likely either contain regions of non-Watson-Crick base pairs or contain regions of heteroduplex DNA that either are very short or dissociate during DNA purification. Two loci were examined in this study: the normal ARG4 locus, and an artificial locus consisting of an arg4-containing plasmid inserted at MAT. Remarkably, sequences in the ARG4 promoter that suffered double-strand cleavage at the normal ARG4 locus were not cut at significant levels when present at MAT::arg4. These results indicate that the formation of double-strand breaks during meiosis does not simply involve the specific recognition and cleavage of a short nucleotide sequence.

The frequency of meiotic recombination in yeast is independent of the number and position of homologous donor sequences: implications for chromosome pairing.

We constructed diploids of Saccharomyces cerevisiae homozygous for LEU2 and carrying one, two, or four copies of leu2 at ectopic locations and determined the frequency of 3+:1- (LEU2:leu2) meiotic tetrads. Gene conversion between a LEU2 recipient and a leu2 ectopic donor occurred at the same frequency as did gene conversion between allelic copies of LEU2 and leu2. An increase in the number of possible ectopic donor loci did not lead to a proportional increase in the level of ectopic gene conversion. We suggest that the limiting step in meiotic recombination is the activation of a locus to become a recipient in recombination and that once activated, a locus can search the entire genome for a homologous partner with which to recombine. In this respect, this search for a homologous partner resembles the efficient premeiotic methylation/inactivation of duplicated sequences in Ascobolus and Neurospora. These observations support models in which strand exchange serves to align homologous chromosomes prior to their becoming much more fully synapsed by the elaboration of the synaptonemal complex.