Fact-checked by Grok 2 weeks ago

Synapsis

Synapsis is the process during which homologous chromosomes pair and align lengthwise in the of a diploid , occurring specifically during I of I. This pairing, also known as syndesis, forms a structure called a tetrad or bivalent, consisting of four chromatids, and is stabilized by the formation of the , a proteinaceous scaffold that holds the chromosomes in close proximity. The process of synapsis begins in the leptotene stage of prophase I with the formation of axial elements along each chromosome, followed by the initiation of double-strand breaks (DSBs) in DNA by the enzyme Spo11, which promotes homologous recombination and chromosome alignment. In the subsequent zygotene stage, homologous chromosomes search for and recognize each other through mechanisms involving proteins such as Rad51 and Dmc1, which form nucleoprotein filaments on single-stranded DNA at DSB sites to facilitate strand invasion and pairing. By the pachytene stage, the synaptonemal complex fully assembles, with transverse filaments (composed of proteins like SYCP1 in mammals) bridging the axial elements of homologous chromosomes, ensuring stable synapsis along their entire length. This complex not only maintains chromosome pairing but also creates a platform for genetic recombination, where non-sister chromatids exchange segments during crossing over. Synapsis is essential for the proper segregation of homologous chromosomes during I, as it ensures that each receives one copy of each chromosome, thereby maintaining genetic stability across generations. It also promotes by facilitating crossing over, which shuffles alleles between maternal and paternal chromosomes, contributing to variation in offspring. Defects in synapsis, such as failure to form the , can lead to meiotic arrest, , or , as observed in various model organisms like , worms, and mice. In evolutionary terms, the conservation of synapsis across eukaryotes underscores its fundamental role in .

Overview and Context

Definition

Synapsis is the process by which homologous chromosomes physically pair and align along their lengths during I of I, forming a structure known as a bivalent or tetrad that facilitates and ensures accurate segregation of chromosomes during subsequent meiotic divisions. This meiosis-specific event allows for the exchange of genetic material between maternal and paternal chromosomes, promoting in gametes. The phenomenon of chromosome pairing was first observed in 1900 by Hans von Winiwarter in studies of mammalian , where he described the side-by-side association of homologous s in rabbit oocytes. The term "synapsis," derived from the Greek for "connection," was first applied to chromosome pairing by John Edmund Sharrock Moore in 1892. Unlike chromosome condensation in , where sister chromatids align but homologous chromosomes remain unpaired, synapsis exclusively involves the intimate association of non-sister chromatids from homologous pairs, a feature unique to that supports crossover formation and homolog disjunction. This process is preceded by DNA replication during the premeiotic , which duplicates each into two sister chromatids, providing the four chromatids necessary for tetrad formation upon pairing. The stable alignment is temporarily stabilized by the .

Occurrence in Meiosis

Synapsis occurs specifically during the zygotene and pachytene substages of I in I, following the where telomeres cluster into a bouquet arrangement to facilitate initial alignment. In the zygotene stage, homologous chromosomes begin to align and pair along their lengths through initial formation, marking the onset of synapsis. This process advances to the pachytene stage, where full synapsis is achieved with the completion of the along the entire length of the homologs, stabilizing their close association. As I progresses into diplotene, partial desynapsis initiates, with the beginning to disassemble while chiasmata hold homologs together. Organismal variations in synapsis reflect adaptations to different chromosomal dynamics. In mammals, such as mice, synapsis initiates at telomeric regions and proceeds inward from the , promoting efficient homolog in large genomes. In the yeast , synapsis is preceded by the formation of double-strand breaks early in I, which trigger recombination intermediates that guide chromosome alignment. In plants like , synapsis is influenced by bouquet stage organization, with and initial stretches often starting near telomeres during early zygotene, though interstitial sites can also contribute. Synapsis is evolutionarily conserved across eukaryotes, from fungi like to humans, as a hallmark of meiotic I that ensures proper homolog segregation, and it is absent in or . During synapsis, the close pairing of homologous chromosomes results in tetrad formation, where each tetrad consists of two homologous chromosomes, each comprising two , held together by the to facilitate subsequent genetic exchange. This structure underpins the role of synapsis in promoting recombination between homologs.

Structural Components

Synaptonemal Complex

The synaptonemal complex (SC) is a highly conserved, tripartite proteinaceous structure that forms between paired homologous chromosomes during meiotic prophase I, serving as the physical scaffold for synapsis. It consists of two lateral elements aligned along each homologous chromosome, a central element positioned between the homologs, and transverse filaments that bridge the lateral elements to the central element. In mammals, the lateral elements are primarily composed of coiled-coil proteins SYCP2 and SYCP3, which form linear scaffolds along the chromosome axes; the central element includes proteins such as SYCE1, SYCE2, SYCE3, and TEX12, which organize into a periodic array; and the transverse filaments are formed by SYCP1, whose C-terminus anchors to the lateral elements and N-terminus extends to the central element. These components self-assemble through multivalent interactions, creating a stable zipper-like lattice that maintains close alignment of homologs. Assembly of the SC begins during the zygotene stage of meiotic I, when transverse filament proteins polymerize between partially aligned homologs, initiating zipper closure from sites of homologous contact. Polymerization proceeds continuously, completing the full tripartite structure by the pachytene stage, where it spans the entire length of paired . Disassembly initiates in diplotene, with progressive fragmentation and loss of central components as chromosomes desynapse. The overall width of the mature SC measures approximately 100 nm between chromosome axes, with the central being less than 100 nm thick, though these dimensions can vary slightly by and visualization method. Visualization of the SC has relied on electron microscopy, which first revealed its characteristic zipper-like ultrastructure in thin sections of meiotic cells, showing periodic transverse filaments spaced about 100 apart. More recently, fluorescence microscopy techniques, including super-resolution methods like 3D-STORM and structured illumination microscopy () tagged to SC proteins such as SYCP1 or SYP-1, have enabled observation of assembly dynamics in live cells and fixed preparations, resolving features down to 20-30 . Species-specific variations in SC structure and assembly reflect adaptations to meiotic strategies. In Caenorhabditis elegans, SC assembly is chromosome-specific, initiating at dedicated pairing centers on each chromosome and proceeding processively along the homolog pair via proteins like SYP-1 (transverse filament), SYP-2, and SYP-3 (lateral elements). In contrast, Drosophila melanogaster males lack full SC assembly and synapsis, undergoing achiasmate meiosis without the tripartite structure, while females form a complete SC dependent on proteins like C(3)G for transverse filaments.

Homologous Pairing Initiation

Homologous initiation during begins in the of I, where replicated chromosomes undergo a dynamic search-and-capture process to align homologous partners before the formation of stable synaptonemal complexes. This early alignment ensures accurate recombination and , relying on nuclear reorganization and molecular cues to bring homologs into proximity across the genome. A key feature in many species is the telomere bouquet, where chromosome ends cluster at the during leptotene, promoting efficient homolog search through telomere-led invasion and limited chromosomal territories. In budding yeast (), telomeres migrate to the spindle pole body, facilitating initial contacts that enhance pairing efficiency, though bouquet disruption reduces but does not eliminate pairing. Similarly, in fission yeast (), this clustering supports rapid homolog alignment via actin-dependent dynamics. The formation of double-strand breaks (DSBs) by the topoisomerase-like enzyme SPO11 plays a pivotal role in promoting homology search in yeast and mammals, where these breaks initiate recombination intermediates that stabilize transient contacts. In S. cerevisiae, SPO11 catalyzes DSBs essential for pairing, as mutants lacking DSB formation exhibit severe pairing defects despite normal chromosome condensation. In mice, SPO11-dependent DSBs are required for efficient homolog alignment, with knockouts leading to asynapsis and infertility due to failed pairing. However, this mechanism is not universal; in Caenorhabditis elegans, pairing initiates without SPO11-induced DSBs, relying instead on specialized pairing centers. Several mechanisms underlie the search process, including diffusion-based scanning of territories, loop extrusion mediated by complexes, and short-range homology checks through direct DNA-DNA interactions. Diffusion allows interchromosomal exploration, with homologs probing for matches via constrained by nuclear architecture, as observed in live imaging of meiotic nuclei. , particularly the meiotic variant Rec8, drives loop extrusion to organize linear chromosomes into searchable loops, facilitating detection along axes in and mammals. Short-range checks involve collision-based recognition, where DNA sequences invade and test for , often guided by recombination proteins like Rad51/Dmc1, ensuring specificity before stable pairing. Interspecies variations highlight evolutionary adaptations in pairing initiation. In mice, SUN-KASH proteins anchor telomeres to the and couple them to cytoplasmic for directed movements, with KASH5 mutants showing disrupted clustering and pairing failure despite intact attachments. In contrast, plants like , which form a , employ -dependent chromosome movements to bring homologs together, with disruptions in actin regulators impairing early alignment. Initial homolog contacts, once established, stabilize through reinforcement by recombination intermediates and , transitioning to full synapsis by triggering polymerization of the along paired axes during zygotene. This shift from dynamic search to stable alignment ensures progression only upon verified .

Molecular Mechanisms

Chromosome Cohesion

Chromosome cohesion during synapsis is primarily mediated by complexes, which are ring-shaped structures composed of structural maintenance of chromosomes (SMC) proteins that encircle and tether DNA strands. In meiosis, these complexes incorporate the meiosis-specific subunit Rec8 instead of the mitotic Rad21 (also known as Scc1), enabling the establishment of cohesion between sister chromatids during premeiotic DNA replication. Rec8-containing cohesins load onto axes and line the during pachytene, providing the physical linkage necessary for homologous chromosome alignment and pairing. This contrasts with mitotic cohesins, where Rad21 supports sister chromatid cohesion for equitable segregation in , whereas Rec8 facilitates the unique meiotic requirement for homolog disjunction in I while maintaining sister cohesion at centromeres until II. Cohesin-mediated cohesion is differentially regulated along chromosome arms and at centromeres to support synapsis and subsequent . Inter-arm cohesion, established by Rec8 complexes, promotes homologous and synapsis by stabilizing axes and resisting premature separation, allowing double-strand breaks and recombination to resolve into chiasmata. In contrast, centromeric sister-chromatid is preserved to ensure bipolar attachment and proper of sisters in II. The acetyltransferase Esco2 modifies cohesin subunits, such as Smc3, during I to stabilize these complexes, with partial Esco2 depletion in spermatocytes delaying autosomal synapsis and weakening . Centromeric protection is further ensured by shugoshin-2 (Sgo2), which recruits protein phosphatase 2A (PP2A) to dephosphorylate and shield Rec8 from separase cleavage, maintaining through I and until II. Cohesion dynamics during synapsis involve both reinforcement and partial release to balance and progression through I. While initial is loaded in , it is reinforced during zygotene and pachytene stages via additional loading mediated by loader proteins like Nipbl/Scc2, enhancing axis rigidity for assembly. In diplotene, following desynapsis, arm distal to chiasmata is gradually released through mechanisms involving Wapl and Pds5, yet sufficient inter-sister linkages persist to hold homologs together via chiasmata until I. This dynamic turnover ensures alignment during synapsis without rigid locking. Recent studies as of 2025 have further shown that meiosis-specific subunits like RAD21L contribute to 3D organization during synapsis, while SCC3 is essential for maintaining . Experimental evidence underscores the critical role of in synapsis. In Rec8 knockout mice, the absence of this subunit leads to failure of homologous synapsis, with synaptonemal complex-like structures forming instead between , resulting in meiotic arrest at I and complete in both males and females due to germ cell loss. Similarly, mutations in associated subunits like Stag3 destabilize Rec8 complexes, disrupting axis formation and synapsis progression, further confirming that intact cohesin architecture is indispensable for meiotic pairing.

Silencing of Unsynapsed Regions

Meiotic silencing of unsynapsed (MSUC) is a conserved process during the first meiotic that transcriptionally represses unpaired chromosomal regions to maintain genomic integrity and promote proper homologous . This mechanism prevents the expression of potentially harmful genes from unsynapsed segments, which could otherwise lead to DNA damage or improper recombination, thereby enforcing the completion of synapsis as a step in . MSUC is particularly active during the pachytene stage of prophase I, where it initiates upon detection of asynapsis and resolves once full synapsis is achieved, though some repressive marks may persist into later stages. In mammals, MSUC begins with the retention of HORMAD1 and HORMAD2 proteins along the axial elements of unsynapsed chromosomes, which serve as sensors for pairing failure and recruit the ATR kinase to these regions. HORMAD2, in particular, is essential for ATR localization specifically to unsynapsed axes, independent of DNA double-strand breaks, thereby initiating downstream silencing events on associated loops. This ATR-dependent pathway ensures chromosome-wide transcriptional inactivation, distinguishing it from localized responses at recombination sites. Key markers of MSUC include histone modifications such as the of H2AX at serine 139 to form γH2AX, which spreads across unsynapsed and correlates directly with repression. ATR-catalyzed γH2AX formation recruits MDC1 ( of DNA damage checkpoint protein 1), which further stabilizes the silenced state by facilitating compaction and exclusion of . In some species, including mammals, RNA-level silencing complements these changes through piRNA-mediated pathways; for instance, the piRNA effector protein localizes to unsynapsed regions and interacts with proteins like and MIWI to degrade aberrant transcripts. Recent research as of 2025 has identified additional regulators, such as ARID1A in directing histone variant H3.3 for silencing and SHOC1 in to avert MSUC on autosomes. A prominent example of MSUC is meiotic sex chromosome inactivation () in male mice, where the largely unsynapsed X and Y chromosomes form the XY body and are silenced via γH2AX foci that appear at the zygotene-pachytene transition. relies on ATR and associated DNA damage response factors to enforce near-complete transcriptional shutdown of the pair, preventing expression of X- and Y-linked genes during pachytene and averting meiotic arrest. Defects in this process, such as in HORMAD2 mutants, lead to incomplete γH2AX coverage and failed silencing, highlighting its role in synapsis surveillance. Related silencing pathways exist in other organisms; for example, in the fungus , meiotic silencing by unpaired DNA (MSUD) transcriptionally represses unpaired regions through RNA-directed RNA polymerases like SAD-1, which amplify aberrant transcripts for degradation, analogous to MSUC's enforcement of pairing fidelity.

Biological Functions

Facilitation of Recombination

Synapsis, mediated by the (SC), aligns homologous chromosomes in close proximity, typically at a distance of approximately 100-200 nm, enabling the repair of meiotic double-strand breaks (DSBs) through . This alignment ensures that DSBs, induced by SPO11 early in I, are preferentially repaired using the as a template rather than the sister , promoting genetic exchange. In most eukaryotes, this process results in the formation of 1-2 crossovers per chromosome arm, which is critical for generating chiasmata that facilitate proper during I. Recombination nodules are proteinaceous structures associated with the SC that mark sites of active recombination. Type I nodules appear early in zygotene, are numerous (often 100-200 per ), and correspond to non-crossover recombination events or early DSB processing intermediates. In contrast, Type II nodules emerge later in pachytene, are fewer in number (typically 1-3 per bivalent), and are specifically linked to crossover-designated sites, where they facilitate the of recombination intermediates into crossovers. These nodules localize to the central region of the SC, integrating recombination machinery with the structural framework of synapsis. Crossover interference, enforced by synapsis, ensures that crossovers are evenly spaced along chromosomes, preventing adjacent events and promoting at least one crossover per bivalent. This phenomenon reduces the probability of a second crossover within a defined physical (often 10-100 in genetic terms, corresponding to SC lengths of several micrometers). The beam-film models this as a process: chromosomes act as elastic beams under from SC polymerization, where initial crossover designation relieves local , propagating an inhibitory signal that redistributes and spaces subsequent events. In , this results in interference distances of about 0.3-1 µm along the SC, scaling with chromosome size in higher organisms. Following synapsis completion in pachytene, DSB processing involves the formation of nucleoprotein filaments by the recombinases RAD51 and DMC1 on resected single-stranded DNA ends. These filaments mediate strand invasion into the homologous duplex DNA, initiating double Holliday junction formation for crossover resolution. The SC stabilizes these invasion structures through direct interactions between RAD51/DMC1 complexes and SC proteins like SYCP1 and SYCP3, anchoring them in the central region and biasing repair toward the homolog. In mouse meiosis, mixed RAD51-DMC1 foci appear on chromosome cores during leptotene/zygotene and persist into pachytene, with approximately 100 such sites per nucleus. The culmination of synapsis-facilitated recombination is the formation of chiasmata during diplotene, when the SC begins to disassemble but crossovers remain as physical ties between homologs. These chiasmata, visible as X-shaped connections under , lock homologs together until anaphase I, ensuring bipolar attachment to the and accurate segregation. In organisms like and mice, this results in robust bivalent formation, with failure to generate chiasmata leading to .

Surveillance and Checkpoint Control

The pachytene checkpoint serves as a critical quality control mechanism during meiotic I in mammals, monitoring the proper assembly of the () and the progression of to ensure genomic integrity. This surveillance system detects defects in chromosome synapsis or recombination initiation, triggering cell cycle arrest at the pachytene stage to prevent the transmission of chromosomal abnormalities to gametes. In response to such failures, affected meiocytes undergo , thereby eliminating potentially deleterious cells and maintaining reproductive fidelity. Key components of this checkpoint include the ATR and ATM kinases, which localize to unsynapsed chromosomal regions and sense exposed DNA through integration of meiotic silencing of unsynapsed chromatin (MSUC) signals. ATR, in particular, accumulates on asynaptic axes during zygotene and pachytene stages, promoting the activation of downstream responses that enforce checkpoint signaling and facilitate the elimination of defective cells. In budding yeast, the orthologous Pch2 ATPase functions analogously by forming a hexameric ring structure that remodels SC components, such as the axial element protein Hop1, to enforce checkpoint activation in response to synapsis defects. The stringency of the pachytene checkpoint varies across species and sexes, reflecting evolutionary adaptations to reproductive strategies. In female meiosis, the checkpoint is particularly stringent, arresting oocytes with incomplete synapsis to avert , whereas male spermatocytes exhibit a more lenient response, allowing progression despite some defects. In fungi like budding yeast, the checkpoint is even less rigorous, permitting cells with asynapsis to complete without arrest. This interspecies variation underscores the checkpoint's role in balancing quality against reproductive output. Recent advances have further elucidated the roles of HORMAD1 and HORMAD2 in synapsis surveillance; for instance, a 2025 study demonstrated that their retention on synapsed axes, as observed in Trip13−/− , recruits in a DSB-independent manner, activating the asynapsis checkpoint and leading to DNA damage response and oocyte elimination. In male meiosis, pairing within the XY (PAR) is specifically monitored to ensure proper segregation, as failures here trigger checkpoint-mediated to prevent . Checkpoint bypass in mutants, such as those lacking key surveillance components, results in the production of aneuploid gametes, increasing the risk of embryonic lethality or genetic disorders.

Regulation and Implications

Key Proteins and Genetic Factors

The synaptonemal complex (SC) is primarily assembled from a set of core proteins that form its structural elements. SYCP1 constitutes the transverse filaments, bridging the lateral elements of homologous chromosomes and stabilizing their alignment during synapsis. SYCP2 and SYCP3 form the lateral elements, providing a scaffold along each chromosome axis that supports the attachment of transverse filaments and facilitates chromosome pairing. The central element, which runs along the interface between paired chromosomes, is composed of SYCE1, SYCE2, and SYCE3, along with TEX12; these proteins interact to create a rigid structure essential for maintaining synapsis. Several pairing factors contribute to the initiation and stabilization of pairing independent of or alongside double-strand break (DSB) formation. In mammals, TEX11 and TEX12 promote DSB-independent pairing by facilitating early interactions between homologous axes and integrating into the SC central element to support its polymerization. In budding yeast, the orthologous ZIP1 protein drives SC polymerization along paired chromosomes, enabling stable synapsis and influencing crossover formation. Cohesin regulators play critical roles in maintaining chromosome structure during synapsis. Rec8 serves as the meiosis-specific kleisin subunit of cohesin, forming complexes with STAG3 (also known as SA3) to organize axial elements and ensure proper homolog juxtaposition. SPO11 initiates DSBs, which are necessary for promoting synapsis in many organisms by facilitating strand invasion and recombination intermediates. Genetic models have elucidated the functions of these proteins through targeted disruptions. In mice, Sycp3 (Sycp3-/-) results in defective lateral element formation, leading to complete asynapsis and meiotic arrest, causing in males and in females. Similar phenotypes occur in knockouts of other components, such as Sycp2-/-, underscoring their essential roles. In humans, variants in SYCP3, including missense mutations like c.666A>G, are associated with and recurrent loss due to impaired synapsis. Variants in SYCE1 and related genes also disrupt SC assembly, linking them to non-obstructive and oocyte defects. Recent studies, including a 2024 review, have highlighted PAR-specific roles for proteins such as SPO11 isoforms and RAD51AP2 in promoting crossovers and synapsis in the (PAR) of chromosomes, mitigating asynapsis in males. In 2025, research demonstrated that synapsis maintenance via chromosome response complexes (CRCs) is crucial for protecting double Holliday junctions and ensuring crossover formation during pachytene. CRISPR-based editing of homologs, including ASY3 and ZIP4, has revealed dosage-dependent effects on synapsis and crossover control, enabling targeted improvements in recombination for hybrid crop breeding.

Defects and Associated Disorders

Defects in synapsis can manifest as asynapsis, characterized by the complete failure of homologous chromosomes to pair or synapse during the first meiotic division, often resulting in univalents at diakinesis and I. Desynapsis, in contrast, involves initial homologous pairing at but premature separation in later stages due to failure in maintaining the , leading to variable bivalents and univalents at I. Non-homologous pairing occurs when defects in homologous recognition cause formation between non-homologous chromosomes or self-foldbacks, uncoupling pairing from synapsis as observed in various meiotic mutants. In humans, mutations in proteins, such as heterozygous variants in SYCP3 (e.g., c.643delA), disrupt protein fiber formation and are associated with non-obstructive due to meiotic arrest. Genetic factors, including mutations in proteins, contribute to approximately 10-15% of severe cases, with non-obstructive accounting for 10-15% of infertile men overall. Other SYCP3 variants, like c.657T>C, have been linked to recurrent loss in females, highlighting sex-specific reproductive impacts. Failed synapsis heightens the risk of during , particularly in maternal I, by impairing and leading to aneuploid gametes. This mechanism contributes to 21 (), where about 90% of cases arise from meiotic errors, with synapsis disruptions from chromosomal abnormalities like translocations exacerbating in oocytes. Animal models illustrate these defects' consequences. In mice, synapsis-deficient mutants like Spo11^{-/-} accumulate unrepaired double-strand breaks on asynaptic chromosomes, triggering a CHK2-dependent checkpoint that depletes the reserve by early adulthood. Similarly, Trip13 mutants exhibit persistent recombination defects post-synapsis, leading to oocyte elimination unless mitigated by factors like HORMAD2 deficiency. In C. elegans, him-3 mutants fail to activate the synapsis checkpoint despite unsynapsed chromosomes, allowing progression and revealing the protein's role in monitoring assembly. Recent research (2022-2023) on (47,XXY) has emphasized (PAR) overdosage, where three active copies of PAR1 genes like SHOX contribute to phenotypic traits and meiotic instability in germ cells, often resulting in . Therapeutic approaches currently rely on testicular sperm extraction combined with , achieving pregnancy rates of about 43% per cycle.

References

  1. [1]
    11.2: The Process of Meiosis - Biology LibreTexts
    Nov 22, 2024 · In synapsis, the genes on the chromatids of the homologous chromosomes are aligned with each other. The synaptonemal complex also supports the ...Meiosis I · Prophase I · Prometaphase I · Metaphase I
  2. [2]
    Recombination, Pairing, and Synapsis of Homologs during Meiosis
    Interplay between homologous chromosomes during meiosis is, by its nature, a dynamic process. The nature of the forces behind these dynamics, which are ...
  3. [3]
    Synapsis - an overview | ScienceDirect Topics
    Synapsis defines newly 'coming together' and 'maintenance' of a communication platform that generates information exchange by close membrane approximation.
  4. [4]
    Meiosis - Molecular Biology of the Cell - NCBI Bookshelf - NIH
    At anaphase of the first meiotic cell division, the arms of the sister chromatids suddenly become unglued, causing one member of each chromosome pair, still ...
  5. [5]
    Meiosis through three centuries - PMC - PubMed Central
    May 10, 2024 · Initiation of synapsis and interlocking of chromosomes during zygotene in Bombyx spermatocytes. Carlsberg Res Commun. 1986;51:401–432. doi ...
  6. [6]
    Telomeres Cluster De Novo before the Initiation of Synapsis - NIH
    The extent to which synapsis has occurred delineates the first three stages of meiotic prophase: leptotene, zygotene, and pachytene; these stages are ...Results · A Telomere Cluster Forms De... · Discussion
  7. [7]
    Recombinational DNA double-strand breaks in mice precede synapsis
    In Saccharomyces cerevisiae, meiotic recombination is initiated by Spo11-dependent double-strand breaks (DSBs), a process that precedes homologous synapsis.
  8. [8]
    Pairing and synapsis in wild type Arabidopsis thaliana - PubMed
    Pairing and synapsis start in regions close to the telomeres at early zygotene. Interstitial synaptonemal complex (SC) stretches were found to occur at several ...
  9. [9]
    Pathways to meiotic recombination in Arabidopsis thaliana - 2011
    Mar 2, 2011 · This article summarizes current progress in the understanding of meiotic recombination and its control in Arabidopsis.
  10. [10]
    Conservation and Variability of Meiosis Across the Eukaryotes
    Nov 23, 2016 · Comparisons among a variety of eukaryotes have revealed considerable variability in the structures and processes involved in their meiosis.
  11. [11]
    https://doi.org/10.1038/s41467-020-17017-7
  12. [12]
    https://doi.org/10.1126/sciadv.adq9374
  13. [13]
    https://doi.org/10.1073/pnas.1414814112
  14. [14]
    https://doi.org/10.1016/j.cell.2005.09.034
  15. [15]
    https://doi.org/10.1101/gad.935001
  16. [16]
    Meiotic telomere clustering requires actin for its formation and ...
    In meiosis, homologous chromosomes (homologues) undergo pairing and crossing over, which are prerequisites for the reductional segregation that compensates for ...Meiotic Telomere Mobility Is... · Rec8 Deletion Induces... · Actin Is Required For...
  17. [17]
    Reconstitution of SPO11-dependent double-strand break formation
    Feb 19, 2025 · DSBs generated by SPO11 activity are a nearly universal feature of meiosis because they initiate the homologous recombination that supports ...
  18. [18]
    Diffusion and distal linkages govern interchromosomal dynamics ...
    Mar 18, 2022 · During meiosis prophase I, homologous chromosomes undergo pairing, synapsis, and crossing over to ensure their proper segregation at meiosis I.
  19. [19]
    Rec8 Cohesin-mediated Axis-loop chromatin architecture is ...
    The lateral element is formed along the axis joining a pair of sister chromatids and is essential for meiotic recombination between homologs. Formation of ...Rec8 Cohesin-Mediated... · Rec8 Mutant Screening · Results
  20. [20]
    All who wander are not lost: the search for homology during ...
    Feb 7, 2024 · Homologous recombination (HR) is a template-based DNA double-strand break repair pathway that functions to maintain genomic integrity.
  21. [21]
    A mammalian KASH domain protein coupling meiotic chromosomes ...
    Sep 23, 2013 · A complex of KASH5 and Sun1 is required for meiotic homologous chromosome pairing through the coupling of telomere attachment sites to ...
  22. [22]
    https://rupress.org/jcb/article/202/7/1023/37394/A-mammalian-KASH-domain-protein-coupling-meiotic
  23. [23]
    Complex elaboration: making sense of meiotic cohesin dynamics
    Apr 20, 2015 · The staining pattern for Esco2 during meiotic prophase is diffuse and not localized to particular structures.
  24. [24]
    Meiotic sex chromosome cohesion and autosomal synapsis are ...
    Feb 12, 2020 · This study provides the first evidence for a specific role of ESCO2 in mammalian meiosis, identifies a particular ESCO2 dependence of sex chromosome cohesion.
  25. [25]
    Absence of Mouse REC8 Cohesin Promotes Synapsis of Sister ...
    We show that REC8 has an essential role in mammalian meiosis, in that Rec8 null mice of both sexes have germ cell failure and are sterile.
  26. [26]
    STAG3‐mediated stabilization of REC8 cohesin complexes ...
    May 5, 2014 · We find that homozygous Stag3 mutant mice fail to complete meiosis and that both males and females are infertile. We have used these homozygous ...
  27. [27]
    Meiotic Silencing in Mammals - Annual Reviews
    Nov 23, 2015 · This process, meiotic silencing, is conserved in all mammals studied to date, but its purpose is not yet defined. Here, I review the molecular ...Missing: MSY2 | Show results with:MSY2
  28. [28]
    Meiotic sex chromosome inactivation - Company of Biologists journals
    May 15, 2007 · Meiotic sex chromosome inactivation (MSCI) is the process of transcriptional silencing of the X and Y chromosomes that occurs during the meiotic phase of ...An introduction to sex... · The epigenetics of MSCI · Post-meiotic transcriptional...
  29. [29]
    Meiotic DNA double-strand breaks and chromosome asynapsis in ...
    We show that HORMAD2 is required for the accumulation of the checkpoint kinase ATR along unsynapsed axes, but not at DNA DSBs or on DNA DSB-associated chromatin ...
  30. [30]
    the link between meiotic silencing of unsynapsed chromatin and ...
    Abstract. Meiotic silencing of unsynapsed chromatin (MSUC) is a key mechanism in spermatogenesis and a model system to study the dynamics of gene silencing.
  31. [31]
    Chromosome architecture and homologous recombination in meiosis
    In this review, we summarize insights into the importance of chromosome architecture in the regulation of meiotic recombination.<|control11|><|separator|>
  32. [32]
    Changes in protein composition of meiotic nodules during ... - PubMed
    Homologous chromosome synapsis and meiotic recombination are facilitated by several meiosis-specific structures: the synaptonemal complex (SC), and two types ...
  33. [33]
    Crossover Patterning by the Beam-Film Model - Research journals
    The beam-film model predicts the existence of mutants that are defective in interference but do not exhibit an increase in the frequency of zero-CO chromosomes.
  34. [34]
    Rad51 and Dmc1 Form Mixed Complexes Associated with Mouse ...
    The eukaryotic RecA homologues RAD51 and DMC1 function in homology recognition and formation of joint-molecule recombination intermediates during yeast meiosis.
  35. [35]
    The meiotic checkpoint monitoring synapsis eliminates ... - PubMed
    The meiotic checkpoint monitoring synapsis eliminates spermatocytes via p53-independent apoptosis.
  36. [36]
    The pachytene checkpoint prevents accumulation and ... - PNAS
    In both yeast and mammals, a checkpoint prevents cells from exiting the pachytene stage of meiotic prophase until meiotic recombination and synaptonemal complex ...
  37. [37]
    ATR Acts Stage Specifically to Regulate Multiple Aspects ... - PubMed
    Jul 1, 2013 · The checkpoint protein ATM and Rad3-related (ATR) localizes to unsynapsed chromosomes, but its role in the initiation and maintenance of meiotic ...
  38. [38]
    ATR acts stage specifically to regulate multiple aspects of ...
    The checkpoint protein ATM and Rad3-related (ATR) localizes to unsynapsed chromosomes, but its role in the initiation and maintenance of meiotic silencing is ...
  39. [39]
    Pch2 is a hexameric ring ATPase that remodels the chromosome ...
    In the presence of ATP, Pch2 binds to and remodels Hop1, an important component of the synaptonemal complex, and displaces it from DNA. Based on these and ...
  40. [40]
    Does the Pachytene Checkpoint, a Feature of Meiosis, Filter Out ...
    Apr 8, 2022 · The pachytene checkpoint detects, selectively arrests, and in many organisms actively destroys gamete-producing cells with chromosomes that cannot adequately ...
  41. [41]
    The DNA damage checkpoint eliminates mouse oocytes with ...
    Genetic and developmental analyses of mouse mutants have suggested there are at least two distinct checkpoints during meiotic prophase I in oocytes, one that ...Missing: strict lenient fungi
  42. [42]
    Numerical constraints and feedback control of double-strand breaks ...
    Apr 18, 2013 · Unlike mouse spermatocytes, yeast cells experiencing even complete asynapsis progress efficiently through meiosis (Henderson and Keeney 2004); ...
  43. [43]
    The N-terminal modification of HORMAD2 causes its ectopic ...
    Mammalian HORMAD1 and HORMAD2 localize to unsynapsed chromosome axes but are removed upon synapsis by the TRIP13 AAA+ ATPase. TRIP13 engages the N-terminal ...
  44. [44]
    Distinct properties of the XY pseudoautosomal region crucial ... - NIH
    X-Y chromosome segregation hinges on efficient crossing-over in a very small region of homology, the pseudoautosomal region (PAR). We find that mouse PAR DNA ...
  45. [45]
    Structural Insight into the Central Element Assembly of the ... - Nature
    Nov 14, 2014 · False pairing between homologous chromosomes produces infertility. Here, we present a crystal structure of the mouse meiosis-specific protein ...
  46. [46]
    Synaptonemal complex protein 2 (SYCP2) mediates the association ...
    Feb 1, 2017 · The N-terminal region of the SYCP1 molecule binds to the central element consisting of SYCE1, SYCE2, SYCE3 and TEX12 proteins. The lateral ...
  47. [47]
    Synaptonemal complex proteins modulate the level of genome ...
    SYCP2 and SYCP3 directly interact with each other. The CE is composed of SYCE1, SYCE2, SYCE3, TEX12, and SIX6OS1. With the exception of TEX12, all of the CE ...
  48. [48]
    The Zip4 protein directly couples meiotic crossover formation to ...
    Dec 30, 2021 · A unique defining feature of meiosis is the pairing/synapsis ... (B) Yeast two-hybrid interaction analysis between mouse TEX11 and TEX12.
  49. [49]
    A ZIP1 separation-of-function allele reveals that centromere pairing ...
    Aug 9, 2018 · The protein Zip1 in budding yeast localizes to paired centromeres in meiotic prophase and is necessary for centromere pairing (Fig 1A) [7–10], ...Missing: factors TEX11 TEX12
  50. [50]
    Mechanism and Regulation of Meiotic Recombination Initiation - PMC
    Meiotic recombination initiates with the formation of DNA double-strand breaks (DSBs) catalyzed by the Spo11 protein.Missing: SA3 | Show results with:SA3
  51. [51]
    A molecular model for the role of SYCP3 in meiotic chromosome ...
    Jun 20, 2014 · According to this initial map of the SC, the SYCE1, SYCE2, SYCE3 and TEX12 proteins form the central element, whilst SYCP2 and SYCP3 are the ...
  52. [52]
    Mutation of the Mouse Syce1 Gene Disrupts Synapsis and Suggests ...
    Mutations in axial element components Sycp2 and Sycp3 result in failure of SC formation and infertility in the male. Milder meiotic defects in female ...
  53. [53]
    A rare synaptonemal complex protein 3 gene variant in unexplained ...
    Our current findings therefore suggest that the c.666A>G variant in the SYCP3 gene might possibly contribute to female infertility in humans.Missing: knockouts synapsis asynapsis
  54. [54]
    Alterations in synaptonemal complex coding genes and human ...
    Feb 21, 2022 · SYCP2 and SYCP3 are the core axis proteins in mammals and have a direct interaction [26, 67]. SYCP2 has 47 exons and encodes a 1350 amino acid ...<|separator|>
  55. [55]
    Recent advances in mechanisms ensuring the pairing, synapsis and ...
    Apr 23, 2024 · Research has made great strides in identifying genes and mechanisms that facilitate CO formation in the PAR. Here, we outline the most recent and relevant ...
  56. [56]
    ASY3 has dosage-dependent diverse effects on meiotic crossover ...
    Jan 9, 2024 · The simultaneous mutation of all four ASY3 alleles results in defective synapsis and drastic reduction of crossovers, which is largely rescued ...
  57. [57]
    An overview of recent advances on wheat homologous and ...
    Recent advances in understanding homologous and homoeologous meiotic recombination in allopolyploid plant species have led us to propose a model for wheat.
  58. [58]
    (PDF) Asynapsis and Desynapsis in Plants - ResearchGate
    Asynapsis is the complete failure of homologous chromosomes to pair or synapse during the first meiotic division, whereas, desynapsis is a condition where ...Missing: non- | Show results with:non-
  59. [59]
    Maize meiotic mutants with improper or non-homologous synapsis ...
    Oct 6, 2010 · The large number of non-homologous synapsis mutants defective in pairing illustrates that synapsis and pairing can be uncoupled.Missing: desynapsis | Show results with:desynapsis
  60. [60]
    Azoospermia in patients heterozygous for a mutation in SYCP3
    We tested the hypothesis that mutation of the human testis-specific SYCP3 is associated with human non-obstructive azoospermia.
  61. [61]
    Failure of homologous synapsis and sex-specific reproduction ...
    A subset of chromosomal abnormalities, including translocation and inversion, disturbs these processes, resulting in the failure to complete synapsis. This ...
  62. [62]
    Article The DNA Damage Checkpoint Eliminates Mouse Oocytes ...
    Jun 2, 2017 · Oocytes defective for either synapsis or DSB repair are eliminated with different dynamics and severity. Females with mutations causing ...
  63. [63]
    Synaptonemal Complex Components Are Required for Meiotic ...
    HTP-3, HIM-3, and HTP-1 are required for the synapsis checkpoint. (A) htp-3 and him-3 mutants have wild-type levels of germline apoptosis and reduce germline ...
  64. [64]
    a summary of the 2022 3rd International Workshop on Klinefelter ...
    Currently, the picture emerging focuses more on X chromosomal escape genes, including genes from the pseudo-autosomal region (PAR) and other genes with Y ...Missing: defects | Show results with:defects