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Animal : An International Journal of... Jun 2018Spermatogenesis is a finely regulated process of germ cell multiplication and differentiation leading to the production of spermatozoa in the seminiferous tubules.... (Review)
Review
Spermatogenesis is a finely regulated process of germ cell multiplication and differentiation leading to the production of spermatozoa in the seminiferous tubules. Spermatogenesis can be divided into three parts: spermatocytogenesis, meiosis and spermiogenesis. During spermatocytogenesis, germ cells engage in a cycle of several mitotic divisions that increases the yield of spermatogenesis and to renew stem cells and produce spermatogonia and primary spermatocytes. Meiosis involves duplication and exchange of genetic material and two cell divisions that reduce the chromosome number and yield four haploid round spermatids. Spermiogenesis involves the differentiation of round spermatids into fully mature spermatozoa released into the lumin of seminiferous tubules. The seminiferous epithelium is composed of several generations of germ cells due to the fact that new generations of sperm cells engage in the spermatogenic process without waiting for the preceding generations to have completed their evolution and to have disappeared as spermatozoa into the lumen of the tubules. In bulls, the duration of the seminiferous epithelium cycle is 13.5 days. The total duration of spermatogenesis is 61 days, that is 4.5 times the duration of the cycle of the seminiferous epithelium. The spermatogenetic wave is used to describe the spatial arrangement of cell associations along the tubules. Several theories have been described to explain the renewal of spermatogonia. Depending on the model, there are five or six spermatogonial mitoses explaining the renewal of stem cells and the proliferation of spermatogonia. Daily sperm production and germ cell degeneration can be quantified from numbers of germ cells in various steps of development throughout spermatogenesis. Bulls have a lower efficiency of spermatogenesis than most species examined, but higher than that of humans.
Topics: Animals; Cattle; Male; Seminiferous Tubules; Spermatocytes; Spermatogenesis; Spermatogonia; Spermatozoa; Testis
PubMed: 29882505
DOI: 10.1017/S1751731118000435 -
Nature Communications Mar 2023N6-methyladenosine (m6A) and its reader proteins YTHDC1, YTHDC2, and YTHDF2 have been shown to exert essential functions during spermatogenesis. However, much remains...
N6-methyladenosine (m6A) and its reader proteins YTHDC1, YTHDC2, and YTHDF2 have been shown to exert essential functions during spermatogenesis. However, much remains unknown about m6A regulation mechanisms and the functions of specific readers during the meiotic cell cycle. Here, we show that the m6A reader Proline rich coiled-coil 2A (PRRC2A) is essential for male fertility. Germ cell-specific knockout of Prrc2a causes XY asynapsis and impaired meiotic sex chromosome inactivation in late-prophase spermatocytes. Moreover, PRRC2A-null spermatocytes exhibit delayed metaphase entry, chromosome misalignment, and spindle disorganization at metaphase I and are finally arrested at this stage. Sequencing data reveal that PRRC2A decreases the RNA abundance or improves the translation efficiency of targeting transcripts. Specifically, PRRC2A recognizes spermatogonia-specific transcripts and downregulates their RNA abundance to maintain the spermatocyte expression pattern during the meiosis prophase. For genes involved in meiotic cell division, PRRC2A improves the translation efficiency of their transcripts. Further, co-immunoprecipitation data show that PRRC2A interacts with several proteins regulating mRNA metabolism or translation (YBX1, YBX2, PABPC1, FXR1, and EIF4G3). Our study reveals post-transcriptional functions of PRRC2A and demonstrates its critical role in the completion of meiosis I in spermatogenesis.
Topics: Male; Humans; Spermatogenesis; Meiosis; Prophase; Spermatocytes; Sex Chromosomes; RNA
PubMed: 36964127
DOI: 10.1038/s41467-023-37252-y -
Cell Research Oct 2017Spermatogenesis is a differentiation process during which diploid spermatogonial stem cells (SSCs) produce haploid spermatozoa. This highly specialized process is...
Spermatogenesis is a differentiation process during which diploid spermatogonial stem cells (SSCs) produce haploid spermatozoa. This highly specialized process is precisely controlled at the transcriptional, posttranscriptional, and translational levels. Here we report that N-methyladenosine (mA), an epitranscriptomic mark regulating gene expression, plays essential roles during spermatogenesis. We present comprehensive mA mRNA methylomes of mouse spermatogenic cells from five developmental stages: undifferentiated spermatogonia, type A spermatogonia, preleptotene spermatocytes, pachytene/diplotene spermatocytes, and round spermatids. Germ cell-specific inactivation of the mA RNA methyltransferase Mettl3 or Mettl14 with Vasa-Cre causes loss of mA and depletion of SSCs. mA depletion dysregulates translation of transcripts that are required for SSC proliferation/differentiation. Combined deletion of Mettl3 and Mettl14 in advanced germ cells with Stra8-GFPCre disrupts spermiogenesis, whereas mice with single deletion of either Mettl3 or Mettl14 in advanced germ cells show normal spermatogenesis. The spermatids from double-mutant mice exhibit impaired translation of haploid-specific genes that are essential for spermiogenesis. This study highlights crucial roles of mRNA mA modification in germline development, potentially ensuring coordinated translation at different stages of spermatogenesis.
Topics: Adaptor Proteins, Signal Transducing; Adenosine; Animals; Cell Differentiation; Cell Proliferation; Gene Expression Regulation, Developmental; Male; Methyltransferases; Mice; RNA, Messenger; Spermatids; Spermatocytes; Spermatogenesis; Spermatozoa; Stem Cells; Testis
PubMed: 28914256
DOI: 10.1038/cr.2017.117 -
Cell Reports Mar 2022The DSB machinery, which induces the programmed DNA double-strand breaks (DSBs) in the leptotene and zygotene stages during meiosis, is suppressed before the onset of...
The DSB machinery, which induces the programmed DNA double-strand breaks (DSBs) in the leptotene and zygotene stages during meiosis, is suppressed before the onset of the pachytene stage. However, the biological significance and underlying mechanisms remain largely unclear. Here, we report that ZFP541 is indispensable for the suppression of DSB formation after mid-pachytene. The deletion of Zfp541 in mice causes the aberrant recruitment of DSB machinery to chromosome axes and generation of massive DSBs in late pachytene and diplotene spermatocytes, leading to meiotic arrest at the diplotene stage. Integrated analysis of single-cell RNA sequencing (scRNA-seq) and chromatin immunoprecipitation (ChIP) sequencing data indicate that ZFP541 predominantly binds to promoters of pre-pachytene genes, including meiotic DSB formation-related genes (e.g., Prdm9 and Mei1) and their upstream activators (e.g., Meiosin and Rxra), and maintains their repression in pachytene spermatocytes. Our results reveal that ZFP541 functions as a transcriptional regulator in pachytene spermatocytes, orchestrating the transcriptome to ensure meiosis progression.
Topics: Animals; Chromosomal Proteins, Non-Histone; DNA Breaks, Double-Stranded; Histone-Lysine N-Methyltransferase; Male; Meiosis; Meiotic Prophase I; Mice; Pachytene Stage; Spermatocytes; Transcription Factors
PubMed: 35320728
DOI: 10.1016/j.celrep.2022.110540 -
Nature Communications Nov 2022Meiosis requires the formation of programmed DNA double strand breaks (DSBs), essential for fertility and for generating genetic diversity. DSBs are induced by the...
Meiosis requires the formation of programmed DNA double strand breaks (DSBs), essential for fertility and for generating genetic diversity. DSBs are induced by the catalytic activity of the TOPOVIL complex formed by SPO11 and TOPOVIBL. To ensure genomic integrity, DNA cleavage activity is tightly regulated, and several accessory factors (REC114, MEI4, IHO1, and MEI1) are needed for DSB formation in mice. How and when these proteins act is not understood. Here, we show that REC114 is a direct partner of TOPOVIBL, and identify their conserved interacting domains by structural analysis. We then analyse the role of this interaction by monitoring meiotic DSBs in female and male mice carrying point mutations in TOPOVIBL that decrease or disrupt its binding to REC114. In these mutants, DSB activity is strongly reduced genome-wide in oocytes, and only in sub-telomeric regions in spermatocytes. In addition, in mutant spermatocytes, DSB activity is delayed in autosomes. These results suggest that REC114 is a key member of the TOPOVIL catalytic complex, and that the REC114/TOPOVIBL interaction ensures the efficiency and timing of DSB activity.
Topics: Male; Female; Mice; Animals; DNA Breaks, Double-Stranded; Meiosis; Chromosomes; Spermatocytes; DNA
PubMed: 36396648
DOI: 10.1038/s41467-022-34799-0 -
Fertility and Sterility Apr 2023To obtain de novo male gametes capable of inducing full preimplantation blastocyst development using a novel three-dimensional (3D) culture system.
OBJECTIVE
To obtain de novo male gametes capable of inducing full preimplantation blastocyst development using a novel three-dimensional (3D) culture system.
DESIGN
Mouse embryonic stem cells (mESCs) were spherified by plunging in sodium alginate followed by calcium chloride, delineating a 3D environment that simulates the seminiferous tubule. As a control, mESCs cultured on two-dimensional plates were used. Plates and spheres containing mESCs from both methods were exposed to Activin-A, bFGF, and KSR followed by exposure to BMP4, LIF, SCF, and EGF to promote differentiation into male germ-like cells.
MAIN OUTCOME MEASURES
Cells were assessed for VASA, DAZL, and BOULE on days 3 and 10. Cells were later injected into activated oocytes and monitored using time-lapse imaging on days 15, 22, 29, and 36. Control conceptuses generated using mature epididymal spermatozoa were also monitored via time-lapse imaging.
RESULTS
On day 3, cells differentiated on plates expressed VASA at 1% and DAZL at 29%. In spheres, VASA was expressed at a rate of 15% and DAZL at a rate of 45% (P<.001). On day 10, cells differentiated on plates had VASA expression of 7%, DAZL of 23%, and BOULE of only 0.5%. Cells differentiated into spheres expressed VASA at a rate of 20%, DAZL at 43%, and BOULE at 10% (P<.001). Subsequent differentiation in spheres on day 3 exhibited a DAZL (expressed in spermatogonia) expression of 43% and a VASA (further spermatogenesis progression) expression of 15%. On day 10, DAZL and VASA expressions were reassessed and increased to 45% and 18%, respectively. BOULE, a marker expressed solely in postmeiotic spermatocytes, was expressed at 8%, whereas acrosin was expressed in spermatids at 2%. On day 15, VASA expression plateaued at 17%, BOULE peaked at 10%, and acrosin reached 5%. On day 22, expression of VASA increased to 19%, BOULE decreased to 8%, and acrosin peaked at 7%. On day 29, VASA expression peaked at 20%, BOULE dropped to 2%, and acrosin remained stable at 7%. On day 36, VASA expression remained at 13%, whereas BOULE and acrosin expression decreased to 0% and 1%, respectively. The control cohort attained 88.4% fertilization and 76.9% blastocyst rates. De novo gametes achieved fertilization rates of 35.0%, 61.1%, 81.8%, and 50.0% on days 15, 22, 29, and 36, respectively. Neogametes-generated blastocyst rates were 5.0%, 16.7%, 36.4%, and 8.3% for days 15, 22, 29, and 36, respectively.
CONCLUSION
Our novel 3D differentiation model can generate functional gametes and is aimed at obviating the need for allogeneic/xenogeneic transplantation. The decreased overall marker expression and the reduced blastocyst development indicated that intrasphere germ cell differentiation correlated with the length of mouse spermatogenesis at approximately 30 days. Future experiments will be conducted to confirm the reproducibility of our findings and the eventual generation of offspring.
Topics: Male; Animals; Mice; Acrosin; Haploidy; Reproducibility of Results; Spermatozoa; Spermatogenesis; Spermatocytes
PubMed: 36706828
DOI: 10.1016/j.fertnstert.2023.01.021 -
Nucleic Acids Research Aug 2023DNA-RNA hybrids play various roles in many physiological progresses, but how this chromatin structure is dynamically regulated during spermatogenesis remains largely...
DNA-RNA hybrids play various roles in many physiological progresses, but how this chromatin structure is dynamically regulated during spermatogenesis remains largely unknown. Here, we show that germ cell-specific knockout of Rnaseh1, a specialized enzyme that degrades the RNA within DNA-RNA hybrids, impairs spermatogenesis and causes male infertility. Notably, Rnaseh1 knockout results in incomplete DNA repair and meiotic prophase I arrest. These defects arise from the altered RAD51 and DMC1 recruitment in zygotene spermatocytes. Furthermore, single-molecule experiments show that RNase H1 promotes recombinase recruitment to DNA by degrading RNA within DNA-RNA hybrids and allows nucleoprotein filaments formation. Overall, we uncover a function of RNase H1 in meiotic recombination, during which it processes DNA-RNA hybrids and facilitates recombinase recruitment.
Topics: Humans; Male; Cell Cycle Proteins; DNA; Meiosis; Rad51 Recombinase; Recombinases; Spermatocytes; Ribonuclease H
PubMed: 37378420
DOI: 10.1093/nar/gkad524 -
Genes Apr 2021Nuclear architecture undergoes an extensive remodeling during spermatogenesis, especially at levels of spermatocytes (SPC) and spermatids (SPT). Interestingly, typical... (Review)
Review
Nuclear architecture undergoes an extensive remodeling during spermatogenesis, especially at levels of spermatocytes (SPC) and spermatids (SPT). Interestingly, typical events of spermiogenesis, such as nuclear elongation, acrosome biogenesis, and flagellum formation, need a functional cooperation between proteins of the nuclear envelope and acroplaxome/manchette structures. In addition, nuclear envelope plays a key role in chromosome distribution. In this scenario, special attention has been focused on the LINC (linker of nucleoskeleton and cytoskeleton) complex, a nuclear envelope-bridge structure involved in the connection of the nucleoskeleton to the cytoskeleton, governing mechanotransduction. It includes two integral proteins: KASH- and SUN-domain proteins, on the outer (ONM) and inner (INM) nuclear membrane, respectively. The LINC complex is involved in several functions fundamental to the correct development of sperm cells such as head formation and head to tail connection, and, therefore, it seems to be important in determining male fertility. This review provides a global overview of the main LINC complex components, with a special attention to their subcellular localization in sperm cells, their roles in the regulation of sperm morphological maturation, and, lastly, LINC complex alterations associated to male infertility.
Topics: Animals; Cell Nucleus; Cytoskeleton; Humans; Infertility, Male; Male; Mechanotransduction, Cellular; Nuclear Envelope; Nuclear Matrix; Spermatids; Spermatocytes; Spermatozoa
PubMed: 33925685
DOI: 10.3390/genes12050658 -
Development (Cambridge, England) Jul 2023Valosin-containing protein (VCP) binds and extracts ubiquitylated cargo to regulate protein homeostasis. VCP has been studied primarily in aging and disease contexts,...
Valosin-containing protein (VCP) binds and extracts ubiquitylated cargo to regulate protein homeostasis. VCP has been studied primarily in aging and disease contexts, but it also affects germline development. However, the precise molecular functions of VCP in the germline, particularly in males, are poorly understood. Using the Drosophila male germline as a model system, we find that VCP translocates from the cytosol to the nucleus as germ cells transition into the meiotic spermatocyte stage. Importantly, nuclear translocation of VCP appears to be one crucial event stimulated by testis-specific TBP-associated factors (tTAFs) to drive spermatocyte differentiation. VCP promotes the expression of several tTAF-target genes, and VCP knockdown, like tTAF loss of function, causes cells to arrest in early meiotic stages. At a molecular level, VCP activity supports spermatocyte gene expression by downregulating a repressive histone modification, mono-ubiquitylated H2A (H2Aub), during meiosis. Remarkably, experimentally blocking H2Aub in VCP-RNAi testes is sufficient to overcome the meiotic-arrest phenotype and to promote development through the spermatocyte stage. Collectively, our data highlight VCP as a downstream effector of tTAFs that downregulates H2Aub to facilitate meiotic progression.
Topics: Animals; Male; Spermatocytes; Valosin Containing Protein; Cell Differentiation; Drosophila; Testis; Gene Expression; Spermatogenesis; Meiosis
PubMed: 37401420
DOI: 10.1242/dev.201557 -
PLoS Genetics Aug 2018During meiosis, maternal and paternal chromosomes undergo exchanges by homologous recombination. This is essential for fertility and contributes to genome evolution. In... (Review)
Review
During meiosis, maternal and paternal chromosomes undergo exchanges by homologous recombination. This is essential for fertility and contributes to genome evolution. In many eukaryotes, sites of meiotic recombination, also called hotspots, are regions of accessible chromatin, but in many vertebrates, their location follows a distinct pattern and is specified by PR domain-containing protein 9 (PRDM9). The specification of meiotic recombination hotspots is achieved by the different activities of PRDM9: DNA binding, histone methyltransferase, and interaction with other proteins. Remarkably, PRDM9 activity leads to the erosion of its own binding sites and the rapid evolution of its DNA-binding domain. PRDM9 may also contribute to reproductive isolation, as it is involved in hybrid sterility potentially due to a reduction of its activity in specific heterozygous contexts.
Topics: Amino Acid Sequence; Animals; Binding Sites; Chromosome Mapping; DNA-Binding Proteins; Evolution, Molecular; Fertility; Heterozygote; Histone-Lysine N-Methyltransferase; Homologous Recombination; Humans; Infertility; Male; Meiosis; Mice; Protein Conformation; Reproductive Isolation; Spermatocytes
PubMed: 30161134
DOI: 10.1371/journal.pgen.1007479