Meiotic chromosome structures constrain and respond to designation of crossover sites

Libuda, Diana E.; Uzawa, Satoru; Meyer, Barbara J; Villeneuve, Anne M.

doi:10.1038/nature12577

Cited by 163 publications

(254 citation statements)

References 32 publications

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“…2). Turning and twisting morphologies of the SC have been observed before in many different organisms, and it has been hypothesized that the twisting may play a role in recombination through an asyet unclear mechanism (3,7,20,29). Although the turning morphologies that we observed do not appear to be regular or helical, it is possible that some of them contain levels of torsion that may be necessary for recombination.…”

Section: Resultscontrasting

confidence: 48%

Superresolution expansion microscopy reveals the three-dimensional organization of theDrosophilasynaptonemal complex

Cahoon

Wang

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

127

117

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The synaptonemal complex (SC), a structure highly conserved from yeast to mammals, assembles between homologous chromosomes and is essential for accurate chromosome segregation at the first meiotic division. In Drosophila melanogaster, many SC components and their general positions within the complex have been dissected through a combination of genetic analyses, superresolution microscopy, and electron microscopy. Although these studies provide a 2D understanding of SC structure in Drosophila, the inability to optically resolve the minute distances between proteins in the complex has precluded its 3D characterization. A recently described technology termed expansion microscopy (ExM) uniformly increases the size of a biological sample, thereby circumventing the limits of optical resolution. By adapting the ExM protocol to render it compatible with structured illumination microscopy, we can examine the 3D organization of several known Drosophila SC components. These data provide evidence that two layers of SC are assembled. We further speculate that each SC layer may connect two nonsister chromatids, and present a 3D model of the Drosophila SC based on these findings.synaptonemal complex | expansion microscopy | meiosis | sister chromatids | structured illumination microscopy

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Section: Resultscontrasting

confidence: 48%

Superresolution expansion microscopy reveals the three-dimensional organization of theDrosophilasynaptonemal complex

Cahoon

Wang

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

127

117

View full text Add to dashboard Cite

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“…This overall pattern also fits with the fact that leptotene is characterized specifically by chromatin expansion, whereas zygotene is characterized specifically by chromosome compaction (20). Indeed, even in Caenorhabditis elegans, in which CO interference occurs after SC formation, recent findings indicate that the chromosomes are under chromatin expansion stress caused by the constraints of the SC, in accord with a role for expansion stress in CO designation (29). ii) In the context of this proposed model, it is easy to envision that, as the designation/interference process progresses, local precursor reactivity will be insufficient to give CO designation; however, if passage of the interference signal implies decreased chromatin expansion, SC nucleation will be progressively favored as the process progresses, thus permitting/ promoting a continued designation process that gives SC nucleations without accompanying CO designation, exactly as suggested by the current analysis.…”

Section: Complex Spatial Patterns Can Arise In a Single Interference-supporting

confidence: 58%

Interference-mediated synaptonemal complex formation with embedded crossover designation

Zhang

Espagne

Muyt

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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Biological systems exhibit complex patterns at length scales ranging from the molecular to the organismic. Along chromosomes, events often occur stochastically at different positions in different nuclei but nonetheless tend to be relatively evenly spaced. Examples include replication origin firings, formation of chromatin loops along chromosome axes and, during meiosis, localization of crossover recombination sites ("crossover interference"). We present evidence in the fungus Sordaria macrospora that crossover interference is part of a broader pattern that includes synaptonemal complex (SC) nucleation. This pattern comprises relatively evenly spaced SC nucleation sites, among which a subset are crossover sites that show a classical interference distribution. This pattern ensures that SC forms regularly along the entire length of the chromosome as required for the maintenance of homolog pairing while concomitantly having crossover interactions locally embedded within the SC structure as required for both DNA recombination and structural events of chiasma formation. This pattern can be explained by a threshold-based designation and spreading interference process. This model can be generalized to give diverse types of related and/or partially overlapping patterns, in two or more dimensions, for any type of object.spatial patterning | synapsis initiation site | recombination/synapsis | crossover designation M eiosis is the specialized cellular cycle that yields haploid gametes for sexual reproduction. A central feature of the meiotic program is recombination (1, 2). DNA/DNA recombination interactions, initiated by programmed double-strand breaks (DSBs), mediate the recognition and juxtaposition (pairing) of homologous chromosomes. A minority subset of these interactions matures into reciprocal crossover recombination products (COs); the remaining majority matures primarily into interhomolog non-crossover products (NCOs). COs promote genetic diversity but also are required for the segregation of homologous chromosomes (homologs) via their role in creating chiasmata (3).A nearly universal feature of meiosis is that COs occur along a particular chromosome at different positions in different meiotic nuclei. Nonetheless, along any given chromosome, COs tend to be evenly spaced. This pattern results from the reduced possibility that a second cross-over will occur if a crossover has occurred nearby. The existence of such a pattern was identified more than a century ago as the genetic phenomenon of CO interference (4, 5). In this phenomenon, occurrence of a CO in one genetic interval is accompanied by a reduced probability that another CO will occur along the same chromosome in a nearby interval. This effect implies the existence of communication along chromosomes, with an event at one position triggering occurrence of an "interference signal" that spreads outward, inhibiting occurrence of subsequent events nearby.A second central feature of the meiotic program is the synaptonemal complex (SC). This prominent structure link...

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“…Recent work has demonstrated that the C. elegans SC central region proteins are important not only for promoting the formation of meiotic COs, but also for limiting their numbers by contributing to CO interference (Hayashi et al 2010;Libuda et al 2013). Inherent in the concept of CO interference is the ability of a nascent CO to change the environment in which it occurs in a manner that inhibits other recombination events in its vicinity from maturing into COs.…”

Section: Implications Of a Two-state View Of The Scmentioning

confidence: 99%

Manipulation of Karyotype inCaenorhabditis elegansReveals Multiple Inputs Driving Pairwise Chromosome Synapsis During Meiosis

2015

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Meiotic chromosome segregation requires pairwise association between homologs, stabilized by the synaptonemal complex (SC). Here, we investigate factors contributing to pairwise synapsis by investigating meiosis in polyploid worms. We devised a strategy, based on transient inhibition of cohesin function, to generate polyploid derivatives of virtually any Caenorhabditis elegans strain. We exploited this strategy to investigate the contribution of recombination to pairwise synapsis in tetraploid and triploid worms. In otherwise wild-type polyploids, chromosomes first sort into homolog groups, then multipartner interactions mature into exclusive pairwise associations. Pairwise synapsis associations still form in recombination-deficient tetraploids, confirming a propensity for synapsis to occur in a strictly pairwise manner. However, the transition from multipartner to pairwise association was perturbed in recombination-deficient triploids, implying a role for recombination in promoting this transition when three partners compete for synapsis. To evaluate the basis of synapsis partner preference, we generated polyploid worms heterozygous for normal sequence and rearranged chromosomes sharing the same pairing center (PC). Tetraploid worms had no detectable preference for identical partners, indicating that PC-adjacent homology drives partner choice in this context. In contrast, triploid worms exhibited a clear preference for identical partners, indicating that homology outside the PC region can influence partner choice. Together, our findings, suggest a two-phase model for C. elegans synapsis: an early phase, in which initial synapsis interactions are driven primarily by recombination-independent assessment of homology near PCs and by a propensity for pairwise SC assembly, and a later phase in which mature synaptic interactions are promoted by recombination.

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Meiotic chromosome structures constrain and respond to designation of crossover sites

Cited by 163 publications

References 32 publications

Superresolution expansion microscopy reveals the three-dimensional organization of theDrosophilasynaptonemal complex

Superresolution expansion microscopy reveals the three-dimensional organization of theDrosophilasynaptonemal complex

Interference-mediated synaptonemal complex formation with embedded crossover designation

Manipulation of Karyotype inCaenorhabditis elegansReveals Multiple Inputs Driving Pairwise Chromosome Synapsis During Meiosis

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