Project description:The DSB-machinery, which induces the programmed DNA double-strand breaks (DSBs) in leptotene and zygotene stages during meiosis, needs to be kept in silence after the initiation of pachytene stage to prevent the activation of DSB checkpoint that may lead to meiotic arrest or apoptosis of germ cells. However, the mechanisms underlying this repression remain largely unknown. Here, we report that ZFP541, a germ cell-specific zinc finger protein, is responsible for the suppression of DSBs formation at late pachytene. Lack of Zfp541 in mice leads to generation of DSBs in late pachytene spermatocytes by DSB formation related-proteins and causes male infertility due to meiotic failure. Plated-based scRNA-seq of Zfp541-/- spermatocytes revealed that ZFP541 negatively regulates many meiotic prophase genes, including genes for DSB formation and their upstream transcriptional regulators, in late pachytene spermatocytes. These results were confirmed by 10x single-cell RNA-seq data on spermatogenesis of Zfp541-/- testes, which suggested that Zfp541 is required for repressing the activation of pre-pachytene gene expression programs from early to late pachytene. ZFP541 ChIP-seq on pachytene and diplotene spermatocytes demonstrated that ZFP541 occupies the promoters of meiosis initiators (e.g., Meiosin and Rxra) and a subset of their downstream genes to repress their transcription, and thus prevent the reactivation of pre-pachytene gene expression programs in pachytene spermatocytes. Thus, our results not only revealed the role of ZFP541 in maintaining the repression of pre-pachytene transcriptional programs in pachytene spermatocytes but also provide new insight into the regulation of meiotic progression by timely turning off pre-pachytene genes.

Project description:The DSB-machinery, which induces the programmed DNA double-strand breaks (DSBs) in leptotene and zygotene stages during meiosis, needs to be kept in silence after the initiation of pachytene stage to prevent the activation of DSB checkpoint that may lead to meiotic arrest or apoptosis of germ cells. However, the mechanisms underlying this repression remain largely unknown. Here, we report that ZFP541, a germ cell-specific zinc finger protein, is responsible for the suppression of DSBs formation at late pachytene. Lack of Zfp541 in mice leads to generation of DSBs in late pachytene spermatocytes by DSB formation related-proteins and causes male infertility due to meiotic failure. Plated-based scRNA-seq of Zfp541-/- spermatocytes revealed that ZFP541 negatively regulates many meiotic prophase genes, including genes for DSB formation and their upstream transcriptional regulators, in late pachytene spermatocytes. These results were confirmed by 10x single-cell RNA-seq data on spermatogenesis of Zfp541-/- testes, which suggested that Zfp541 is required for repressing the activation of pre-pachytene gene expression programs from early to late pachytene. ZFP541 ChIP-seq on pachytene and diplotene spermatocytes demonstrated that ZFP541 occupies the promoters of meiosis initiators (e.g., Meiosin and Rxra) and a subset of their downstream genes to repress their transcription, and thus prevent the reactivation of pre-pachytene gene expression programs in pachytene spermatocytes. Thus, our results not only revealed the role of ZFP541 in maintaining the repression of pre-pachytene transcriptional programs in pachytene spermatocytes but also provide new insight into the regulation of meiotic progression by timely turning off pre-pachytene genes.

Project description:The DSB-machinery, which induces the programmed DNA double-strand breaks (DSBs) in leptotene and zygotene stages during meiosis, needs to be kept in silence after the initiation of pachytene stage to prevent the activation of DSB checkpoint that may lead to meiotic arrest or apoptosis of germ cells. However, the mechanisms underlying this repression remain largely unknown. Here, we report that ZFP541, a germ cell-specific zinc finger protein, is responsible for the suppression of DSBs formation at late pachytene. Lack of Zfp541 in mice leads to generation of DSBs in late pachytene spermatocytes by DSB formation related-proteins and causes male infertility due to meiotic failure. Plated-based scRNA-seq of Zfp541-/- spermatocytes revealed that ZFP541 negatively regulates many meiotic prophase genes, including genes for DSB formation and their upstream transcriptional regulators, in late pachytene spermatocytes. These results were confirmed by 10x single-cell RNA-seq data on spermatogenesis of Zfp541-/- testes, which suggested that Zfp541 is required for repressing the activation of pre-pachytene gene expression programs from early to late pachytene. ZFP541 ChIP-seq on pachytene and diplotene spermatocytes demonstrated that ZFP541 occupies the promoters of meiosis initiators (e.g., Meiosin and Rxra) and a subset of their downstream genes to repress their transcription, and thus prevent the reactivation of pre-pachytene gene expression programs in pachytene spermatocytes. Thus, our results not only revealed the role of ZFP541 in maintaining the repression of pre-pachytene transcriptional programs in pachytene spermatocytes but also provide new insight into the regulation of meiotic progression by timely turning off pre-pachytene genes.

Project description:Prophase I of male meiosis involves dynamic chromosome segregation processes during early spermatogenesis, including synapsis, meiotic recombination, and cohesion. Genetic defects in genes participating in these processes consistently cause reproduction failure in mice. To identify candidate genes responsible for infertility in humans, we performed expression profiling of mouse spermatogenic cells undergoing meiotic prophase I. Cell fractions enriched in spermatogonia, leptotene/zygotene spermatocytes, or pachytene spermatocytes were separately isolated from mouse testes for RNA extraction. To minimize the contamination of other cell types, we fractionated the testicular cells undergoing the first round of spermatogenesis using Percoll gradient procedure. The cell fractions were characterized by morphological analysis by phase contrast microscopy and Nomarski interference microscopy, and then expression of cell lineage- and spermatogenesis stage-specific genes were examined by RT-PCR. The most enriched fractions for spermatogonia (fraction2 from day8), leptotene/zygotene spermatocytes (fraction5 from day12), and pachytene spermatocytes (fraction8 from day15) were subjected to hybridization on Affymetrix microarrays.

Project description:The four mammalian Argonaute family members are thought to share redundant functions in the microRNA pathway, yet only AGO2 possesses the catalytic "slicer" function required for RNA interference. Whether AGO1, AGO3, or AGO4 possess specialized functions remains unclear. Here, we Series_summary = show that AGO4 localizes to spermatocyte nuclei during meiotic prophase I, specifically at sites of asynapsis and in the transcriptionally silenced XY sub-domain, the sex body. We generated Ago4 knockout mice and show that Ago4-/- spermatogonia initiate meiosis early, resulting from premature induction of retinoic acid-response genes. During prophase I, the sex body assembles incorrectly in Ago4-/- mice, leading to disrupted meiotic sex chromosome inactivation (MSCI). This is associated with a dramatic loss of microRNAs, >20% of which arise from the X chromosome. Loss of AGO4 results in increased AGO3 in spermatocytes, indicating some degree of redundancy. Thus, AGO4 regulates meiotic entry and MSCI in mammalian germ cells, implicating small RNA pathways in these processes. mRNA transcripts were isolated and prepared using pachytene spermatocytes, pre-meiotic testes and other tissues from Ago4+/+ and Ago4-/- littermates and sequenced using Illumina HiSeq2000. small RNA transcripts were isolated and prepared using pachytene spermatocytes from adult Ago4+/+ and Ago4-/- littermates and sequenced using Illumina GAII.

Project description:As a serine/threonine phosphatase, protein phosphatase 2A (PP2A) is essential in numerous physiological processes. Our previously study confirmed PP2A dysfunction can cause azoospermia by generating catalytic subunit of PP2A (Ppp2ca) conditional knockout (CKO) in C57BL/6J mice. Here, we further explored the possible mechanisms by focusing on meiosis initiation and spermatogenesis. The deficiency of Ppp2ca in germ cells conspicuously disturbed spermatogonial differentiation and lead to pachytene arrest, accompanied by defects in programmed double-strand break (DSB) repair and meiotic sex chromosome inactivation (MSCI). Furthermore, Ppp2ca-deficient spermatocytes exhibited abnormal agglutination and cohesion complex degradation of chromosome, probably contributing to pachytene arrest. Our study demonstrates the irreplaceable role of PP2A in spermatogenesis and provide more evidences on azoospermia etiology.

Project description:Post-transcriptional regulation of gene expression by RNA-binding proteins helps facilitate fast, clean transitions from one cell state to the next during germ cell differentiation. Previously we showed that the RNA helicase YTHDC2 is required for germ cells to properly switch from mitosis to meiosis (Bailey et al., 2017). While YTHDC2 protein is first expressed as male germ cells enter meiosis, when it is needed to shut down the mitotic program, YTHDC2 expression continues to increase and reaches its highest levels later in meiotic prophase, in pachytene spermatocytes. Here we show that YTHDC2 has an additional essential role regulating meiotic progression in late spermatocytes during mouse germ cell differentiation. Inducing conditional knockout of Ythdc2 during the first wave of spermatogenesis, after the germ cells have already initiated meiotic prophase, allowed Ythdc2-deficient germ cells to successfully reach the pachytene stage and properly express many meiotic markers. However, instead of continuing through meiotic prophase and initiating the meiotic divisions, late pachytene spermatocytes failed to transition to the diplotene stage and quickly died. Loss of function of Ythdc2 in spermatocytes resulted in changes in transcript levels for a number of genes by RNA-sequencing compared to control spermatocytes. Our findings suggest that YTHDC2 facilitates proper progression of germ cells through multiple steps of meiosis, potentially via several mechanisms of post-transcriptional RNA regulation.

Project description:Regulation of the transcriptome to promote meiosis is important for sperm development and fertility. However, how chromatin remodeling directs the transcriptome during meiosis in male germ cells is largely unknown. Here, we demonstrate that the ISWI family ATP-dependent chromatin remodeling factor SMARCA5 (SNF2H) plays a critical role in regulating meiotic prophase progression during spermatogenesis. Males with germ cell-specific depletion of SMARCA5 are infertile and unable to form sperm. Loss of Smarca5 results in failure of meiotic progression with abnormal spermatocytes beginning at the pachytene stage and an aberrant global increase in chromatin accessibility, especially at genes important for meiotic prophase.

Project description:TAR DNA binding protein of 43 kDa (TDP-43; gene name: Tardbp), a ubiquitously expressed evolutionarily conserved protein, is highly expressed in the preleptotene and pachytene spermatocytes. TDP-43 is linked to several human neurodegenerative disorders. Exploring its functional requirement for spermatogenesis for the first time, we show here that conditional knockout (cKO) of Tardbp in male germ cells of mice leads to failure of meiosis and arrest of spermatogenesis. Fertility trials indicated severe subfertility. Spermatocytes of cKO mice showed failure to complete prophase I of meiosis with arrest at mid-pachytene stage. Our work reveals a crucial role for TDP-43 in male meiosis and suggests that some forms of meiotic arrest seen in infertile men may result from loss of function of TDP-43. In order to identify putative direct genes of TDP-43, we performed RNA-seq using testes from postnatal day 12 (PND12) wild type (control) and cKO (experimental) mice.

Project description:H3K9 tri-methylation (H3K9me3) plays emerging roles in gene regulation, beyond its accumulation on pericentric constitutive heterochromatin. It remains a mystery why and how H3K9me3 undergoes dynamic regulation in male meiosis. Here, we identify a novel, critical regulator of H3K9 methylation and spermatogenic heterochromatin organization: the germline-specific protein ATF7IP2 (MCAF2). We show that, in male meiosis, ATF7IP2 amasses on autosomal and X pericentric heterochromatin, spreads through the entirety of the sex chromosomes, and accumulates on thousands of autosomal promoters and retrotransposon loci. On the sex chromosomes, which undergo meiotic sex chromosome inactivation (MSCI), the DNA damage response pathway recruits ATF7IP2 to X pericentric heterochromatin, where it facilitates the recruitment of SETDB1, a histone methyltransferase that catalyzes H3K9me3. In the absence of ATF7IP2, male germ cells are arrested in meiotic prophase. Analyses of ATF7IP2-deficient meiosis reveal the protein’s essential roles in the maintenance of MSCI, suppression of retrotransposons, and global activation of autosomal genes. We propose that ATF7IP2 is a downstream effector of the DDR pathway in meiosis that coordinates the organization of heterochromatin and gene regulation through the spatial regulation of SETDB1-mediated H3K9me3 deposition. CUT&RUN of H3K9me3 in Atf7ip2+/+ and Atf7ip2-/- pachytene spermatocytes and CUT&Tag of ATF7IP2 in C57/B6 WT pachytene spermatocytes.