Project description:The mammalian Y chromosome is essential for male fertility, but how individual Y genes regulate spermatogenesis is poorly understood. To resolve this question, we generate a deletion series of the mouse Y chromosome, creating thirteen Y-deletant mouse models and conducting exhaustive reproductive phenotyping. Eight Y genes, including several that are deeply conserved and exhibit testis-specific expression, are dispensable for spermatogenesis. For others, we uncover novel functions, including a role for Uty in establishment and differentiation of spermatogonia, and for Zfy2 in ensuring meiotic pairing and reciprocal recombination between the sex chromosomes. We also generate the first mouse equivalent of the human infertility AZFa deletion, revealing cumulative detrimental effects of Y-gene loss on spermatogenesis. We use single nuclei RNAseq to identify candidate mechanisms by which Y genes regulate the germ cell transcriptome and reveal an unexpected impact of Y genes on testis supporting cells. Our study represents a paradigm for the complete functional dissection of a mammalian Y chromosome and advances our knowledge of human infertility and Y-chromosome evolution.

Project description:The mammalian Y chromosome plays a critical role in spermatogenesis. However, the exact functions of each gene in the Y chromosome have not been completely elucidated, partly owing to difficulties in gene targeting analysis for the Y chromosome. Zfy was first proposed to be a sex determination factor, but its function in spermatogenesis has been recently elucidated. Nevertheless, Zfy gene targeting analysis has not been performed thus far. Here, we adopted the highly efficient CRISPR/Cas9 system to generate individual Zfy1 or Zfy2 knockout (KO) mice, and Zfy1 and Zfy2 double knockout (Zfy1/2-DKO) mice. While individual Zfy1 or Zfy2-KO mice did not show any significant phenotypic alterations in fertility, Zfy1/2-DKO mice were infertile and displayed abnormal sperm morphology, fertilization failure, and early embryonic development failure. Mass spectrometric screening, followed by confirmation with western blot analysis, showed that PLCZ1, PLCD4, PRSS21, and HTT protein expression was significantly deceased in spermatozoa from Zfy1/2-DKO mice compared with those from wild type mice. These results are consistent with the phenotypic changes seen in the double mutant mice. Collectively, our strategy and findings revealed that Zfy1 and Zfy2 have redundant functions in spermatogenesis, facilitating a better understanding of fertilization failure and early embryonic development failure.

Project description:The mammalian Y chromosome plays a critical role in spermatogenesis. However, the exact functions of each gene in the Y chromosome have not been completely elucidated, partly owing to difficulties in gene targeting analysis of the Y chromosome. Zfy was first proposed to be a sex determination factor, but its function in spermatogenesis has been recently elucidated. Nevertheless, Zfy gene targeting analysis has not been performed thus far. Here, we adopted the highly efficient CRISPR/Cas9 system to generate individual Zfy1 or Zfy2 knockout (KO) mice and Zfy1 and Zfy2 double knockout (Zfy1/2-DKO) mice. While individual Zfy1 or Zfy2-KO mice did not show any significant phenotypic alterations in fertility, Zfy1/2-DKO mice were infertile and displayed abnormal sperm morphology, fertilization failure, and early embryonic development failure. Mass spectrometric screening, followed by confirmation with western blot analysis, showed that PLCZ1, PLCD4, PRSS21, and HTT protein expression were significantly deceased in spermatozoa of Zfy1/2-DKO mice compared with those of wild-type mice. These results are consistent with the phenotypic changes seen in the double-mutant mice. Collectively, our strategy and findings revealed that Zfy1 and Zfy2 have redundant functions in spermatogenesis, facilitating a better understanding of fertilization failure and early embryonic development failure.

Project description:In the present study we carried out testicular gene expression profiling of patients with AZFc microdeletion, idiopathic infertility and normal spermatogenesis, in order to identify up- and downregulated genes in the different conditions, and to verify the presence of specific molecular pathways leading to the spermatogenic damage in patients with AZFc deletions. All samples of patients with AZFc deletion clustered together, showing downregulation of several genes related to spermatogenesis. In this study, we analyzed testis expression profiles of 16 patients with different phenotypes, including men with AZFc deletions and men with idiopathic infertility. All pathological human testis RNAs were hybridized against normal testis reference RNA samples (obstructive azoospermia), while the three samples with normal spermatogenesis were hybridized against a control represented by an home-made RNA universal reference consisting of a commercial human purified tissue RNA pool (brain, liver, muscle and lung) (Clontech, Terra Bella, CA, USA) . These latter hybridizations were carried out in order to generate a profile of genes specifically expressed in normal testis.

Project description:Spermatogenesis is a complex multi-step process involving intricate interactions between different cell types in the male testis. Disruption of these interactions results in infertility. Combination of shotgun tissue proteomics with MALDI imaging mass spectrometry is markedly potent in revealing topological maps of molecular processes within tissues. Here, we use a combinatorial approach on a characterized mouse model of hormone induced male infertility to uncover misregulated pathways. Comparative testicular proteome of wildtype and mice overexpressing human P450 aromatase (AROM+) with pathologically increased estrogen levels unravels gross dysregulation of spermatogenesis and emergence of pro-inflammatory pathways in AROM+ testis. In situ MS allowed us to localize misregulated proteins/peptides to defined regions within the testis. Results suggest that infertility is associated with substantial loss of proteomic heterogeneity, which define distinct stages of seminiferous tubuli in healthy animals. Importantly, considerable loss of mitochondrial factors, proteins associated with late stages of spermatogenesis and steroidogenic factors characterise AROM+ mice. Thus, the novel proteomic approach pinpoints in unprecedented ways the disruption of normal processes in testis and provides a signature for male infertility.

Project description:Expression profiling of mouse ing2 -/- testis vs WT reveals gene expression differences consistent with spermatogenic arrest and infertility. Ing2 is indispensable for male germ cell development in mice. While mice deficient for Ing2 were born and grew without apparent abnormalities, male, but not female, were infertile, consistent with the highest expression of Ing2 in testes in wild-type mice and in humans. Histological and DNA content analyses in Ing2-/- testes revealed a spermatogenesis arrest at meiotic phase and enhanced apoptosis associated with increased p53, resulting in a decline in mature spermatozoa, which became more severe in older age. HDAC1 accumulation and core histone deacetylation at pachytene stage were impaired in Ing2-/- testes, suggesting that the recruitment of HDAC1 by Ing2 plays a critical role in spermatogenesis. This study establishes Ing2 as a novel mammalian regulator of spermatocyte differentiation, which coordinates spermatogenesis stage-specific histone modifications. This study has implications in understanding human male infertility. Testis from WT and Ing2 KO mice at 2-3 months of age where analyzed for differences in gene expression.

Project description:Spermatogenesis is an essential process to generate male gametes in vertebrates, and it has become an important social health problem caused by spermatogenesis disorder. However, the molecular mechanism underlying spermatogenesis, particularly epigenetic modification in Sertoli cells of testis, remain elusive. In this study we generated Rnf20 conditional knockout mice by recombinant mothed, and only to find that Rnf20 knockout in Sertoli cells led to male infertility.

Project description:Spermatogenesis plays an important role in the mammalian testis, involving in the complex processes of mitosis, meiosis, and spermiogenesis. Spermatogenesis may also be disrupted in the absence of the immunological and ‘fence’ functions of the BTB, resulting in male subfertility or infertility. Mice lacking wild-type p53-induced phosphatase 1 (Wip1) display male reproductive organ defects, but the molecular mechanisms underlying these abnormalities remain unclear. We explored the function of Wip1 in spermatogenesis and fertility by examining differences in the expressed testis proteome and phosphoproteome between Wip1-deficient and wild-type mice using a proteomics approach. 90 proteins and 178 phosphoproteins were differentially regulated between these two groups of mice. These results suggested that proinflammatory cytokines may impair the blood–testis barrier dynamics by decreasing the expression of junction-associated proteins, which effect could be partially responsible for the subfertility and spermatogenesis defects in Wip1-knockout mice.

Project description:Male spermatogenesis is an essential and complex developmental process with the purpose to gain totipotency and allow a whole new organism to develop upon fertilization. While single-gene based studies have provided insights into the mechanisms at work, global profiling is clearly required to deconvolute these processes. Here, by isolating highly enriched mouse meiotic cell populations, we report a comprehensive gene expression map of mammalian meiosis. Our data reveal in unique details the dynamic of fundamental expression patterns such as the global chromosome X inactivation and reactivation allowing to precisely dissect this unique process. It also reveals a rapid global expression switch at the initiation of the long pachytene stage reminiscent and coincident with the commitment to meiosis observed in budding yeast. Overall, this meiotic atlas provides an exhaustive blueprint and resource for deconvoluting mammalian gametogenesis and meiosis. 10- to 16-week-old male C57BL/6 x DBA/2J F1 testis were used for sorting multiple meiotic fractions. These samples were used for subsequent RNA purification, labeling and hybridization to Affymetrix arrays. 1-4 biological replicates per fraction.

Project description:Ikbkap/Elp1 regulates genes involved in spermatogenesis. Ikbkap deficiency causes male infertility by disrupting meiotic progression. In this dataset, we include the expression data for control and Ikbkap-knockout mouse testis.