A cohesin-based structural platform supporting homologous chromosome pairing in meiosis

The pairing and recombination of homologous chromosomes during the meiotic prophase is necessary for the accurate segregation of chromosomes in meiosis. However, the mechanism by which homologous chromosomes achieve this pairing has remained an open question. Meiotic cohesins have been shown to affect chromatin compaction; however, the impact of meiotic cohesins on homologous pairing and the fine structures of cohesion-based chromatin remain to be determined. A recent report using live-cell imaging and super-resolution microscopy demonstrated that the lack of meiotic cohesins alters the chromosome axis structures and impairs the pairing of homologous chromosomes. These results suggest that meiotic cohesin-based chromosome axis structures are crucial for the pairing of homologous chromosomes.     

Synapsis-dependent and -independent mechanisms stabilize homolog pairing during meiotic prophase in C. elegans

Analysis of Caenorhabditis elegans syp-1 mutants reveals that both synapsis-dependent and -independent mechanisms contribute to stable, productive alignment of homologous chromosomes during meiotic prophase. Early prophase nuclei undergo normal reorganization in syp-1 mutants, and chromosomes initially pair. However, the polarized nuclear organization characteristic of early prophase persists for a prolonged period, and homologs dissociate prematurely; furthermore, the synaptonemal complex (SC) is absent. The predicted structure of SYP-1, its localization at the interface between intimately paired, lengthwise-aligned pachytene homologs, and its kinetics of localization with chromosomes indicate that SYP-1 is an SC structural component. A severe reduction in crossing over together with evidence for accumulated recombination intermediates in syp-1 mutants indicate that initial pairing is not sufficient for completion of exchange and implicates the SC in promoting crossover recombination. Persistence of polarized nuclear organization in syp-1 mutants suggests that SC polymerization may provide a motive force or signal that drives redispersal of chromosomes. Whereas our analysis suggests that the SC is required to stabilize pairing along the entire lengths of chromosomes, striking differences in peak pairing levels for opposite ends of chromosomes in syp-1 mutants reveal the existence of an additional mechanism that can promote local stabilization of pairing, independent of synapsis.     

The Arabidopsis synaptonemal complex protein ZYP1 is required for chromosome synapsis and normal fidelity of crossing over

The duplicated Arabidopsis genes ZYP1a/ZYP1b encode closely related proteins with structural similarity to the synaptonemal complex (SC) transverse filament proteins from other species. Immunolocalization detects ZYP1 foci at late leptotene, which lengthen until at pachytene fluorescent signals extending the entire length of the fully synapsed homologs are observed. Analysis of zyp1a and zyp1b T-DNA insertion mutants indicates that the proteins are functionally redundant. The SC is not formed in the absence of ZYP1 and prophase I progression is significantly delayed suggesting the existence of an intraprophase I surveillance mechanism. Recombination is only slightly reduced in the absence of ZYP1 such that the chiasma frequency at metaphase I is approximately 80% of wild type. Moreover cytological analysis indicates that chiasma distribution within zyp1 bivalents is indistinguishable from wild type, providing evidence that the SC is not required for the imposition of interference. Importantly in the absence of ZYP1, recombination occurs between both homologous and nonhomologous chromosomes suggesting the protein is required to ensure the fidelity of meiotic chromosome associations.     

HTP-1 coordinates synaptonemal complex assembly with homolog alignment during meiosis in C. elegans

During meiosis, the mechanisms responsible for homolog alignment, synapsis, and recombination are precisely coordinated to culminate in the formation of crossovers capable of directing accurate chromosome segregation. An outstanding question is how the cell ensures that the structural hallmark of meiosis, the synaptonemal complex (SC), forms only between aligned pairs of homologous chromosomes. In the present study, we find that two closely related members of the him-3 gene family in Caenorhabditis elegans function as regulators of synapsis. HTP-1 functionally couples homolog alignment to its stabilization by synapsis by preventing the association of SC components with unaligned and immature chromosome axes; in the absence of the protein, nonhomologous contacts between chromosomes are inappropriately stabilized, resulting in extensive nonhomologous synapsis and a drastic decline in chiasma formation. In the absence of both HTP-1 and HTP-2, synapsis is abrogated per se and the early association of SC components with chromosomes observed in htp-1 mutants does not occur, suggesting a function for the proteins in licensing SC assembly. Furthermore, our results suggest that early steps of recombination occur in a narrow window of opportunity in early prophase that ends with SC assembly, resulting in a mechanistic coupling of the two processes to promote crossing over.     

HTP-1-dependent constraints coordinate homolog pairing and synapsis and promote chiasma formation during C. elegans meiosis

Synaptonemal complex (SC) assembly must occur between correctly paired homologous chromosomes to promote formation of chiasmata. Here, we identify the Caenorhabditis elegans HORMA-domain protein HTP-1 as a key player in coordinating establishment of homolog pairing and synapsis in C. elegans and provide evidence that checkpoint-like mechanisms couple these early meiotic prophase events. htp-1 mutants are defective in the establishment of pairing, but in contrast with the pairing-defective chk-2 mutant, SC assembly is not inhibited and generalized nonhomologous synapsis occurs. Extensive nonhomologous synapsis in htp-1; chk-2 double mutants indicates that HTP-1 is required for the inhibition of SC assembly observed in chk-2 gonads. htp-1 mutants show a decreased abundance of nuclei exhibiting a polarized organization that normally accompanies establishment of pairing; analysis of htp-1; syp-2 double mutants suggests that HTP-1 is needed to prevent premature exit from this polarized nuclear organization and that this exit stops homology search. Further, based on experiments monitoring the formation of recombination intermediates and crossover products, we suggest that htp-1 mutants are defective in preventing the use of sister chromatids as recombination partners. We propose a model in which HTP-1 functions to establish or maintain multiple constraints that operate to ensure coordination of events leading to chiasma formation.     

Mug20, a novel protein associated with linear elements in fission yeast meiosis

In the fission yeast, Schizosaccharomyces pombe, homologous chromosomes efficiently pair and recombine during meiotic prophase without forming a canonical synaptonemal complex (SC). Instead, it features simpler filamentous structures, the so-called linear elements (LinEs), which bear some resemblance to the axial/lateral element subunits of the SC. LinEs are required for wild-type recombination frequency. Here, we recognized Mug20, the product of a meiotically upregulated gene, as a LinE-associated protein. GFP-tagged Mug20 and anti-Mug20 antibody co-localized completely with Rec10, one of the major constituents of LinEs. In the absence of Mug20, LinEs failed to elongate beyond their initial state of nuclear dots. Foci of recombination protein Rad51 and genetic recombination were reduced. Since meiotic DNA double-strand breaks (DSBs), which initiate recombination, are induced at sites of preformed LinEs, we suggest that reduced recombination is a consequence of incomplete LinE extension. Therefore, we propose that Mug20 is required to extend LinEs from their sites of origin and thereby to increase DSB proficient regions on chromosomes.     

The preference for GT-rich DNA by the yeast Rad51 protein defines a set of universal pairing sequences

The Rad51 protein of Saccharomyces cerevisiae is a eukaryotic homolog of the RecA protein, the prototypic DNA strand-exchange protein of Escherichia coli. RAD51 gene function is required for efficient genetic recombination and for DNA double-strand break repair. Recently, we demonstrated that RecA protein has a preferential affinity for GT-rich DNA sequences—several of which exhibit enhanced RecA protein-promoted homologous pairing activity. The fundamental similarity between the RecA and Rad51 proteins suggests that Rad51 might display an analogous bias. Using in vitro selection, here we show that the yeast Rad51 protein shares the same preference for GT-rich sequences as its prokaryotic counterpart. This bias is also manifest as an increased ability of Rad51 protein to promote the invasion of supercoiled DNA by homologous GT-rich single-stranded DNA, an activity not previously described for the eukaryotic pairing protein. We propose that the preferred utilization of GT-rich sequences is a conserved feature among all homologs of RecA protein, and that GT-rich regions are loci for increased genetic exchange in both prokaryotes and eukaryotes.     

Strand pairing by Rad54 and Rad51 is enhanced by chromatin

We investigated the role of chromatin in the catalysis of homologous strand pairing by Rad54 and Rad51. Rad54 is related to the ATPase subunits of chromatin-remodeling factors, whereas Rad51 is related to bacterial RecA. In the absence of superhelical tension, we found that the efficiency of strand pairing with chromatin is >100-fold higher than that with naked DNA. In addition, we observed that Rad54 and Rad51 function cooperatively in the ATP-dependent remodeling of chromatin. These findings indicate that Rad54 and Rad51 have evolved to function with chromatin, the natural substrate, rather than with naked DNA.     

A model for chromosome structure during the mitotic and meiotic cell cycles

The chromosome scaffold model in which loops of chromatin are attached to a central, coiled chromosome core (scaffold) is the current paradigm for chromosome structure. Here we present a modified version of the chromosome scaffold model to describe chromosome structure and behavior through the mitotic and meiotic cell cycles. We suggest that a salient feature of chromosome structure is established during DNA replication when sister loops of DNA extend in opposite directions from replication sites on nuclear matrix strands. This orientation is maintained into prophase when the nuclear matrix strand is converted into two closely associated sister chromatid cores with sister DNA loops extending in opposite directions. We propose that chromatid cores are contractile and show, using a physical model, that contraction of cores during late prophase can result in coiled chromatids. Coiling accounts for the majority of chromosome shortening that is needed to separate sister chromatids within the confines of a cell. In early prophase I of meiosis, the orientation of sister DNA loops in opposite directions from axial elements assures that DNA loops interact preferentially with homologous DNA loops rather than with sister DNA loops. In this context, we propose a bar code model for homologous presynaptic chromosome alignment that involves weak paranemic interactions of homologous DNA loops. Opposite orientation of sister loops also suppresses crossing over between sister chromatids in favor of crossing over between homologous non-sister chromatids. After crossing over is completed in pachytene and the synaptonemal complex breaks down in early diplotene (= diffuse stage), new contractile cores are laid down along each chromatid. These chromatid cores are comparable to the chromatid cores in mitotic prophase chromosomes. As an aside, we propose that leptotene through early diplotene represent the missing G2 period of the premeiotic interphase. The new chromosome cores, along with sister chromatid cohesion, stabilize chiasmata. Contraction of cores in late diplotene causes chromosomes to coil in a configuration that encourages subsequent syntelic orientation of sister kinetochores and amphitelic orientation of homologous kinetochore pairs on the spindle at metaphase I.     

Mutational analyses of the human Rad51-Tyr315 residue, a site for phosphorylation in leukaemia cells

The human Rad51 protein, which plays a central role in homologous recombination, catalyses homologous pairing. The Rad51-Tyr315 residue is known to be constitutively phosphorylated in leukaemia cells and is thought to reside within the subunit-subunit interface of the Rad51 filament. To study the function of the Tyr315 residue, we purified five Rad51 mutants, Y315D, Y315E, Y315R, Y315A and Y315F, in which the Tyr315 residue was replaced by Asp, Glu, Arg, Ala and Phe, respectively. Biochemical studies of these Rad51 mutants revealed that the Y315D and Y315E mutants are defective in homologous pairing due to their impaired ssDNA binding, but their dsDNA binding remained unaffected. The Y315D, Y315E and Y315R mutants are defective in dsDNA unwinding, which depends on Rad51-filament formation, suggesting that these mutants are defective in filament formation on dsDNA. Therefore, the Rad51-Tyr315 residue plays important roles in ssDNA binding and filament formation.     

A role for Ddc1 in signaling meiotic double-strand breaks at the pachytene checkpoint

The pachytene checkpoint prevents meiotic cell cycle progression in response to unrepaired recombination intermediates. We show that Ddc1 is required for the pachytene checkpoint in Saccharomyces cerevisiae. During meiotic prophase, Ddc1 localizes to chromosomes and becomes phosphorylated; these events depend on the formation and processing of double-strand breaks (DSBs). Ddc1 colocalizes with Rad51, a DSB-repair protein, indicating that Ddc1 associates with sites of DSB repair. The Rad24 checkpoint protein interacts with Ddc1 and with recombination proteins (Sae1, Sae2, Rad57, and Msh5) in the two-hybrid protein system, suggesting that Rad24 also functions at DSB sites. Ddc1 phosphorylation and localization depend on Rad24 and Mec3, consistent with the hypothesis that Rad24 loads the Ddc1/Mec3/Rad17 complex onto chromosomes. Phosphorylation of Ddc1 depends on the meiosis-specific kinase Mek1. In turn, Ddc1 promotes the stable association of Mek1 with chromosomes and is required for Mek1-dependent phosphorylation of the meiotic chromosomal protein Red1. Ddc1 therefore appears to operate in a positive feedback loop that promotes Mek1 function.     

Meiotic recombination in <Emphasis Type="Italic">Caenorhabditis elegans</Emphasis>

The faithful segregation of homologous chromosomes during meiosis is dependent on the formation of physical connections (chiasma) that form following reciprocal exchange of DNA molecules during meiotic recombination. Here we review the current knowledge in the Caenorhabditis elegans meiotic recombination field. We discuss recent developments that have improved our understanding of the crucial steps that must precede the initiation and propagation of meiotic recombination. We summarize the pathways that impact on meiotic prophase entry and the current understanding of how chromosomes reorganize and interact to promote homologous chromosome pairing and subsequent synapsis. We pay particular attention to the mechanisms that contribute to meiotic DNA double-strand break (DSB) formation and strand exchange processes, and how the C. elegans system compares with other model organisms. Finally, we highlight current and future areas of research that are likely to further our understanding of the meiotic recombination process.     

c(3)G encodes a Drosophila synaptonemal complex protein.

The meiotic mutant c(3)G (crossover suppressor on 3 of Gowen) abolishes both synaptonemal complex (SC) formation and meiotic recombination, whereas mutations in the mei-W68 and mei-P22 genes prevent recombination but allow normal SC to form. These data, as well as a century of cytogenetic studies, support the argument that meiotic recombination between homologous chromosomes in Drosophila females requires synapsis and SC formation. We have cloned the c(3)G gene and shown that it encodes a protein that is structurally similar to SC proteins from yeast and mammals. Immunolocalization of the C(3)G protein, as well as the analysis of a C(3)G-eGFP expression construct, reveals that C(3)G is present in a thread-like pattern along the lengths of chromosomes in meiotic prophase, consistent with a role as an SC protein present on meiotic bivalents. The availability of a marker for SC in Drosophila allowed the investigation of the extent of synapsis in exchange-defective mutants. These studies indicate that SC formation is impaired in certain meiotic mutants and that the synaptic defect correlates with the exchange defects. Moreover, the observation of interference among the residual exchanges in these mutant oocytes implies that complete SC formation is not required for crossover interference in Drosophila.     

Discontinuities and unsynapsed regions in meiotic chromosomes have a cis effect on meiotic recombination patterns in normal human males

During meiosis, homologous chromosome pairing is essential for subsequent meiotic recombination (crossover). Discontinuous chromosome regions (gaps) or unsynapsed chromosome regions (splits) in the synaptonemal complex (SC) indicate anomalies in chromosome synapsis. Recently developed immunofluorescence techniques (using antibodies against SC proteins and the crossover-associated MLH1 protein) were combined with fluorescence in situ hybridization (using centromere-specific DNA probes) to identify bivalents with gaps/splits and to examine the effect of gaps/splits on meiotic recombination patterns during the pachytene stage of meiotic prophase from three normal human males. Gaps were observed only in the heterochromatic regions of chromosomes 9 and 1, with 9q gaps accounting for 90% of these events. Most splits were also found in chromosomes 9 and 1, with 58% of splits occurring on 9q. Gaps and splits significantly altered the distribution of MLH1 foci on the SC. On gapped SC 9q, the frequency of MLH1 foci was decreased compared with controls, and single 9q crossovers tended toward a more distal distribution. Furthermore, the larger the gap the more distal the location of the MLH1 focus closest to the q arm's telomere. MLH1 foci on split SC 9 had distributions similar to those of gapped SC 9; however, splits did not change the frequencies of MLH1 foci on SC 9. This is the first demonstration that gaps and splits have an effect on meiotic recombination in humans.     

RadA protein is an archaeal RecA protein homolog that catalyzes DNA strand exchange

With the discovery that the Saccharomyces cerevisiae Rad51 protein is both structurally and functionally similar to the Escherichia coli RecA protein, the RecA paradigm for homologous recombination was extended to the Eucarya. The ubiquitous presence of RecA and Rad51 protein homologs raises the question of whether this archetypal protein exists within the third domain of life, the Archaea. Here we present the isolation of a Rad51/RecA protein homolog from the archaeon Sulfolobus solfataricus, and show that this protein, RadA, possesses the characteristics of a DNA strand exchange protein: The RadA protein is a DNA-dependent ATPase, forms a nucleoprotein filament on DNA, and catalyzes DNA pairing and strand exchange.     

Sub-nuclear localization of Rad51 in response to DNA damage

The repair of DNA double-strand breaks involves the accumulation of key homologous recombination proteins in nuclear foci at the sites of repair. The organization of these foci in relation to non-chromatin nuclear structures is poorly understood. To address this question, we examined the distribution of several recombination proteins in subcellular fractions following treatment of HeLa cells with ionizing radiation and the crosslinking agent mitomycin C. The results showed association of Rad51, Rad54, BRCA1 and BRCA2, but not Rad51C, with the nuclear matrix fraction in response to double-strand breaks induction. The association of Rad51 with the nuclear matrix correlates with the formation of Rad51 nuclear foci as a result of DNA damage. Fractionation in situ confirmed that Rad51 foci remained firmly immobilized within the chromatin-depleted nuclei. Irs1SF cells that are unable to form Rad51 damage-induced nuclear foci did not show accumulation of Rad51 in the nuclear matrix. Similarly, no accumulation of Rad51 in the nuclear matrix could be observed after treatment of HeLa cells with the kinase inhibitor caffeine, which reduces formation of Rad51 foci. The results were compared to the distribution of the phosphorylated histone variant, γ-H2AX. These data suggest a dynamic association and tethering of recombination proteins and surrounding chromatin regions to the nuclear matrix.     

Nuclear reorganization and homologous chromosome pairing during meiotic prophase require C. elegans chk-2

Analysis of mutants defective in meiotic chromosome pairing has uncovered a role for Caenorhabditis elegans chk-2 in initial establishment of pairing between homologous chromosomes during early meiotic prophase. chk-2 is also required for the major spatial reorganization of nuclei that normally accompanies the onset of pairing, suggesting a mechanistic coupling of these two events. Despite failures in pairing, nuclear reorganization, and crossover recombination, chk-2 mutants undergo many other aspects of meiotic chromosome morphogenesis and complete gametogenesis. Although chk-2 encodes a C. elegans ortholog of the Cds1/Chk2 checkpoint protein kinases, germ-line nuclei in chk-2 mutants are competent to arrest proliferation in response to replication inhibition and to trigger DNA damage checkpoint responses to ionizing radiation. However, chk-2 mutants are defective in triggering the pachytene DNA damage checkpoint in response to an intermediate block in the meiotic recombination pathway, suggesting that chk-2 is required either for initiation of meiotic recombination or for monitoring a specific subset of DNA damage lesions. We propose that chk-2 functions during premeiotic S phase to enable chromosomes to become competent for subsequent meiotic prophase events and/or to coordinate replication with entry into prophase.     

Identification and characterisation of a RAD51 gene from Leishmania major.

The RAD51 gene is a homologue of Escherichia coli recA which plays a central role in homologous recombination and DNA repair. This paper describes the identification of the RAD51 gene from the trypanosomatid parasite Leishmania major. The LmRAD51 gene codes for a 377 amino acid polypeptide with a predicted molecular mass of 41259 Da that is highly homologous to the Rad51 family of proteins. Recombinant L. major Rad51 protein (LmRad51) was over-expressed in a bacterial expression system, purified to homogeneity and shown to bind DNA and exhibit DNA-stimulated ATPase activity, consistent with previously reported biochemical characteristics of Rad51 protein. Although LmRad51 expression is below the level of detection in exponentially growing cultures of Leishmania, high levels of LmRad51 mRNA and protein expression can be detected following exposure to the DNA-damaging agent phleomycin. LmRAD51 is one of the first examples of a DNA damage-inducible gene to be characterised in Leishmania, and will be invaluable in studying the contribution of homologous recombination to Leishmania virulence.     

Hed1 regulates Rad51-mediated recombination via a novel mechanism

Two RecA orthologs, Rad51 and Dmc1, mediate homologous recombination in meiotic cells. During budding yeast meiosis, Hed1 coordinates the actions of Rad51 and Dmc1 by down-regulating Rad51 activity. It is thought that Hed1-dependent attenuation of Rad51 facilitates formation of crossovers that are necessary for the correct segregation of chromosomes at the first meiotic division. We purified Hed1 in order to elucidate its mechanism of action. Hed1 binds Rad51 with high affinity and specificity. We show that Hed1 does not adversely affect assembly of the Rad51 presynaptic filament, but it specifically prohibits interaction of Rad51 with Rad54, a Swi2/Snf2-like factor that is indispensable for Rad51-mediated recombination. In congruence with the biochemical results, Hed1 prevents the recruitment of Rad54 to a site-specific DNA double-strand break in vivo but has no effect on the recruitment of Rad51. These findings shed light on the function of Hed1 and, importantly, unveil a novel mechanism for the regulation of homologous recombination.     

Bipartite stimulatory action of the Hop2-Mnd1 complex on the Rad51 recombinase

The HOP2 and MND1 genes are indispensable for meiotic recombination. The products of these genes associate to form a stable heterodimeric complex that binds DNA and stimulates the recombinase activity of Rad51 and Dmc1. Here we conduct molecular studies to delineate the action mechanism of the Hop2-Mnd1 complex. We present evidence to implicate Hop2 as the major DNA-binding subunit and Mnd1 as the prominent Rad51 interaction entity. Hop2-Mnd1 stabilizes the Rad51-single-stranded DNA (ssDNA) nucleoprotein filament, the catalytic intermediate in recombination reactions. We also show that Hop2-Mnd1 enhances the ability of the Rad51-ssDNA nucleoprotein filament to capture duplex DNA, an obligatory step in the formation of the synaptic complex critical for DNA joint formation. Thus, our results unveil a bipartite mechanism of Hop2-Mnd1 in homologous DNA pairing: stabilization of the Rad51 presynaptic filament and duplex DNA capture to enhance synaptic complex formation.