Project description:Spermatogonial stem cells are the foundation of spermatogenesis and as such can serve as a tool for the treatment of infertility in prepubertal cancer survivors. Spermatogonial stem cells are unique as they develop from primordial germ cells (PGCs), which colonize the developing tubules as immature SSC precursors. It has been controversial, when SSCs are maturing to an adult-like stem cell and recent research has found that prepubertal SSCs are actually metabolically distinct from adult SSCs until puberty. Sertoli cells picture a major part of the SSC niche and undergo drastic changes with puberty and polarize to compartmentalize the seminiferous epithelium with formation of tight junctions to a tight basal part where SSCs reside and an apical part with more differentiated stages of spermatogenesis. In the study were mapping the progression of Sertoli cells maturation events to the metabolic changes SSCs undergo during prepubertal development.

Project description:MicroRNAs (miRs) play a key role in the control of gene expression in a wide array of tissue systems where their functions include the regulation of self-renewal, cellular differentiation, proliferation, and apoptosis. However, the functional importance of individual miRs in controlling spermatogonial stem cell (SSC) homeostasis has not been investigated. Using high-throughout sequencing, we profiled the expression of miRs in the Thy1+ testis cell population, which is highly enriched for SSCs, and the Thy1- cell population, composed primarily of testis somatic cells. In addition, we profiled the global expression of miRs in cultured germ cells, also enriched for SSCs. Our results demonstrate that miR-21, along with miR-34c, -182, -183, -146a, -465a-3p, -465b-3p, -465c-3p, and -465c-5p are preferentially expressed in the Thy1+ SSC-enriched population, as compared to Thy1- somatic cells, and we further observed that Thy1+ SSC-enriched testis cells and SSC-enriched cultured germ cells share remarkably similar miR expression profiles. Spermatogonial Stem Cell enriched cell populations (freshly isolated and short-term cultured) and somatic cell populations were isolated from C57B/L6 mouse donors and subjected to small RNA isolation and sequencing.

Project description:The testis is the organ with the most transcriptome diversity and alternative splicing (AS) is considered to be the most important source. However, the physiological role of AS in spermatogenesis is poorly understood. Here, we report that spliceosome component BUD31 is a prominent AS regulator in early stage of spermatogenesis in mice. Bud31 expression in the testis is initiated soon after birth. Conditional knock out of Bud31 in germ cells in Vasa-Cre mice led to loss of spermatogonial stem cells (SSCs) and to infertility. We further demonstrate that BUD31was required for both SSC pool maintenance and initiation of spermatogenesis. Mechanistically, BUD31 regulates the alternative splicing of multiple genes involved in cell cycle checkpoint and cell differentiation. In particular, we identified CDK2 as a direct splicing target of BUD31 through integrative analysis of SMART-seq and RIP-seq data. Knockout of BUD31 results in the intron retention as well as exon skipping of CDK2, which led to decrease in CDK2 expression. Our findings highlight the significance of BUD31 and its regulated AS in SSC self-renewal and differentiation.

Project description:The testis is the organ with the most transcriptome diversity and alternative splicing (AS) is considered to be the most important source. However, the physiological role of AS in spermatogenesis is poorly understood. Here, we report that spliceosome component BUD31 is a prominent AS regulator in early stage of spermatogenesis in mice. Bud31 expression in the testis is initiated soon after birth. Conditional knock out of Bud31 in germ cells in Vasa-Cre mice led to loss of spermatogonial stem cells (SSCs) and to infertility. We further demonstrate that BUD31was required for both SSC pool maintenance and initiation of spermatogenesis. Mechanistically, BUD31 regulates the alternative splicing of multiple genes involved in cell cycle checkpoint and cell differentiation. In particular, we identified CDK2 as a direct splicing target of BUD31 through integrative analysis of SMART-seq and RIP-seq data. Knockout of BUD31 results in the intron retention as well as exon skipping of CDK2, which led to decrease in CDK2 expression. Our findings highlight the significance of BUD31 and its regulated AS in SSC self-renewal and differentiation.

Project description:Maintenance and self-renewal of the spermatogonial stem cell (SSC) population is the cornerstone of male fertility. In this manuscript we have identified a key role for the nucleosome remodelling protein Chromodomain Helicase DNA binding protein 4 (CHD4) in regulating SSC function. Gene expression analyses revealed that CHD4 expression is largely restricted to spermatogonia in the mouse testis, and is particularly enriched in SSCs. Using spermatogonial transplantation techniques and RNAi mediated knockdown it was established that loss of Chd4 expression significantly impairs SSC regenerative capacity, resulting in a ~50% reduction in colonisation of recipient testes. A single cell RNA-seq comparison depicted reduced expression of ‘self-renewal’ genes such as Gfra1 and Pten following Chd4 knockdown, along with increased expression of signature progenitor genes, Neurog3 and Dazl. Co-immunoprecipitation analyses demonstrated that CHD4 regulates gene expression in spermatogonia not only though its traditional association with the remodelling complex NuRD, but also via interaction with the GDNF-responsive transcription factor SALL4. Cumulatively, the results of this study depict a previously unappreciated fundamental role for CHD4 in controlling fate decisions in the spermatogonial pool.

Project description:Spermatogenesis in mammals is a complex and highly orchestrated process, which involves the differentiation of diploid (2n-DNA content) spermatogonia into haploid (n) sperm. This process begins with spermatogonia, a niche of stem cells, which drive this process. Spermatogonial stem cells (SSCs) undergo mitotic self-renewal to maintain this niche, while sub-populations of spermatogonia progressively undergo differentiation and later gain competence to initiate meiosis and form sperm. SSCs undergo extensive chromatin remodelling and major morphological changes, while maintaining genome integrity and parental imprints. To study this in greater detail we performed single-cell RNA sequencing of spermatogenic cells derived from the testis of the non-human primate Macaca fascicularis.

Project description:Autotransplantation of in vitro proliferated spermatogonial stem cells (SSCs) has been advocated as a way to restore fertility in childhood cancer survivors. In this study we determined the effects of cell culture on DNA methylation patterning in human SSCs, to evaluate the safety of future clinical application of SSC autotransplantation. Bisulfite converted DNA of 34 human spermatogonial stem cell samples, 4 sperm samples and 3 seminoma samples were hybridized to Illumina Infinium 450k Human Methylation Beadchips

Project description:MicroRNAs (miRs) play a key role in the control of gene expression in a wide array of tissue systems where their functions include the regulation of self-renewal, cellular differentiation, proliferation, and apoptosis. However, the functional importance of individual miRs in controlling spermatogonial stem cell (SSC) homeostasis has not been investigated. Using high-throughout sequencing, we profiled the expression of miRs in the Thy1+ testis cell population, which is highly enriched for SSCs, and the Thy1- cell population, composed primarily of testis somatic cells. In addition, we profiled the global expression of miRs in cultured germ cells, also enriched for SSCs. Our results demonstrate that miR-21, along with miR-34c, -182, -183, -146a, -465a-3p, -465b-3p, -465c-3p, and -465c-5p are preferentially expressed in the Thy1+ SSC-enriched population, as compared to Thy1- somatic cells, and we further observed that Thy1+ SSC-enriched testis cells and SSC-enriched cultured germ cells share remarkably similar miR expression profiles.

Project description:Background: Spermatogonial stem cells (SSCs) sustain the process of steady-state spermatogenesis in the mammalian testis, which is critical to the ongoing production of sperm and male fertility. SSCs can both self-renew to perpetuate the SSC population, and give rise to progenitors to propel the spermatogenic differentiation pathway. SSCs are detectable as a small subpopulation of undifferentiated spermatogonia that demonstrate regenerative capacity in a transplantation assay, and can be selectively recovered on the basis of expression of an Id4-eGfp sortable marker transgene. Enriched populations of SSCs and progenitors display consistent differences in gene expression patterns suggesting they represent discrete spermatogonial subtypes. Results: Here we describe distinct spermatogonial subtype-specific epigenetic programming profiles associated with subtype-specific differential gene expression on the basis of genome-wide patterns of six different histone modifications, chromatin accessibility, and DNA methylation. We find that similarly expressed genes show no differences in epigenetic programming, whereas differentially expressed genes show distinct histone modification patterns as well as subtype-specific differences in patterns of distal intergenic low-methylated regions. Motif-enrichment analysis of differentially programmed elements predicts a set of transcription factors that may regulate this spermatogonial subtype-specific epigenetic programming, and gene-specific chromatin immunoprecipitation analyses confirm subtype-specific differences in binding of a subset of these factors to target genes. Conclusions: Taken together, these results indicate that SSCs and progenitors are discrete spermatogonial subtypes that appear to be differentially programmed to carry out mutually exclusive functions including self-renewal and maintenance of regenerative capacity in SSCs and lineage commitment and loss of regenerative capacity in progenitors.

Project description:Background: Spermatogonial stem cells (SSCs) sustain the process of steady-state spermatogenesis in the mammalian testis, which is critical to the ongoing production of sperm and male fertility. SSCs can both self-renew to perpetuate the SSC population, and give rise to progenitors to propel the spermatogenic differentiation pathway. SSCs are detectable as a small subpopulation of undifferentiated spermatogonia that demonstrate regenerative capacity in a transplantation assay, and can be selectively recovered on the basis of expression of an Id4-eGfp sortable marker transgene. Enriched populations of SSCs and progenitors display consistent differences in gene expression patterns suggesting they represent discrete spermatogonial subtypes. Results: Here we describe distinct spermatogonial subtype-specific epigenetic programming profiles associated with subtype-specific differential gene expression on the basis of genome-wide patterns of six different histone modifications, chromatin accessibility, and DNA methylation. We find that similarly expressed genes show no differences in epigenetic programming, whereas differentially expressed genes show distinct histone modification patterns as well as subtype-specific differences in patterns of distal intergenic low-methylated regions. Motif-enrichment analysis of differentially programmed elements predicts a set of transcription factors that may regulate this spermatogonial subtype-specific epigenetic programming, and gene-specific chromatin immunoprecipitation analyses confirm subtype-specific differences in binding of a subset of these factors to target genes. Conclusions: Taken together, these results indicate that SSCs and progenitors are discrete spermatogonial subtypes that appear to be differentially programmed to carry out mutually exclusive functions including self-renewal and maintenance of regenerative capacity in SSCs and lineage commitment and loss of regenerative capacity in progenitors.