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A hallmark of meiosis is pairing of homologous chromosomes, an event that ensures proper segregation into the gametes. Homology pairing is crucial to the formation of normal gametes, the maintenance of genomic integrity, and avoidance of aneuploidy. However, chromosomes are not completely homologous. Here we discuss two notable exceptions to homology: the mammalian sex chromosomes and centromeres. In themselves, these exceptions illustrate meiotic adaptations that both ensure correct chromosome segregation and present evolutionary opportunities. More broadly, such examples of non-homology provide a window for viewing normal mechanisms of meiotic pairing and chromosome modifications. Current analyses of mammalian meiotic chromosome dynamics suggest that the basis for the initial recognition of homology early in meiosis may be based in epigenetic chromatin modifications. Chromatin units may both form pairing sites and provide the modifications that allow non-homologous sequences to be tolerated. Despite recent research progress, we have yet to understand why some non-homologies are tolerated, while others lead to aneuploidy. Understanding how genomes evolve strategies to subvert the usual rules of meiosis will benefit from studies focused on the identification and characterization of meiosis in species with recently acquired non-homology. Looking forward, we are now armed with technologies and tools suited to precisely measure the extent of nonhomology across mammalian chromosomes and to probe the molecular and biophysical steps required for the initiation of homologous chromosome recognition and pairing. These goals are important for elucidating an essential mechanism of meiosis and ultimately for advancing the clinical diagnosis of gametic and embryo aneuploidy.
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Meiotic chromosome dynamics and double strand break formation in reptiles
During meiotic prophase I, tightly regulated processes take place, from pairing and synapsis of homologous chromosomes to recombination, which are essential for the generation of genetically variable haploid gametes. These processes have canonical meiotic features conserved across different phylogenetic groups. However, the dynamics of meiotic prophase I in non-mammalian vertebrates are poorly known. Here, we compare four species from Sauropsida to understand the regulation of meiotic prophase I in reptiles: the Australian central bearded dragon ( Pogona vitticeps ), two geckos ( Paroedura picta and Coleonyx variegatus ) and the painted turtle ( Chrysemys picta ). We first performed a histological characterization of the spermatogenesis process in both the bearded dragon and the painted turtle. We then analyzed prophase I dynamics, including chromosome pairing, synapsis and the formation of double strand breaks (DSBs). We show that meiosis progression is highly conserved in reptiles with telomeres clustering forming the bouquet , which we propose promotes homologous pairing and synapsis, along with facilitating the early pairing of micro-chromosomes during prophase I (i.e., early zygotene). Moreover, we detected low levels of meiotic DSB formation in all taxa. Our results provide new insights into reptile meiosis.
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- Award ID(s):
- 2127995
- PAR ID:
- 10412168
- Date Published:
- Journal Name:
- Frontiers in Cell and Developmental Biology
- Volume:
- 10
- ISSN:
- 2296-634X
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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The pairing of homologous chromosomes (homologs) in meiosis is essential for distributing the correct numbers of chromosomes into haploid gametes. In budding yeast, pairing depends on the formation of 150 to 200 Spo11-mediated double-strand breaks (DSBs) that are distributed among 16 homolog pairs, but it is not known if all, or only a subset, of these DSBs contribute to the close juxtaposition of homologs. Having established a system to measure the position of fluorescently tagged chromosomal loci in three-dimensional space over time, we analyzed locus trajectories to determine how frequently and how long loci spend colocalized or apart. Continuous imaging revealed highly heterogeneous cell-to-cell behavior of foci, with the majority of cells exhibiting a “mixed” phenotype where foci move into and out of proximity, even at late stages of prophase, suggesting that the axial structures of the synaptonemal complex may be more dynamic than anticipated. The observed plateaus of the mean-square change in distance (MSCD) between foci informed the development of a biophysical model of two diffusing polymers that captures the loss of centromere linkages as cells enter meiosis, nuclear confinement, and the formation of Spo11-dependent linkages. The predicted number of linkages per chromosome in our theoretical model closely approximates the small number (approximately two to four) of estimated synapsis-initiation sites, suggesting that excess DSBs have negligible effects on the overall juxtaposition of homologs. These insights into the dynamic interchromosomal behavior displayed during homolog pairing demonstrate the power of combining time-resolved in vivo analysis with modeling at the granular level.more » « less
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Salz, H (Ed.)Abstract Meiosis is usually described as 4 essential and sequential processes: (1) homolog pairing; (2) synapsis, mediated by the synaptonemal complex; (3) crossing over; and (4) segregation. In this canonical model, the maturation of crossovers into chiasmata plays a vital role in holding homologs together and ensuring their segregation at the first meiotic division. However, Lepidoptera (moths and butterflies) undergo 3 distinct meiotic processes, only one of which is canonical. Lepidoptera males utilize 2 meiotic processes: canonical meiosis that produces nucleated fertile sperm, and a noncanonical meiosis that produces anucleated nonfertile sperm which are nonetheless essential for reproduction. Lepidoptera females, which carry heteromorphic sex chromosomes, undergo a completely achiasmate (lacking crossovers) meiosis, thereby requiring an alternative mechanism to ensure proper homolog segregation. Here, we report that the development of a molecular cell biology toolkit designed to properly analyze features of meiosis, including the synaptonemal complex structure and function, in the silkworm Bombyx mori. In addition to standard homology searches to identify Bombyx orthologs of known synaptonemal complex encoding genes, we developed an ortholog discovery app (Shinyapp) to identify Bombyx orthologs of proteins involved in several meiotic processes. We used this information to clone genes expressed in the testes and then created antibodies against their protein products. We used the antibodies to confirm the localization of these proteins in normal male spermatocytes, as well as using in vitro assays to confirm orthologous interactions. The development of this toolkit will facilitate further study of the unique meiotic processes that characterize meiosis in Lepidoptera.more » « less
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- Free Publicly Accessible Full Text
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Accepted Manuscript1.0
- Journal Article:
- https://doi.org/10.3389/fcell.2022.1009776
