Project description:In vitro and in vivo aging of mouse spermatogonial stem cells alters stem cell function based on quantitative spermatogonial stem cell transplantation analyses. We used microarrays to identify differential gene expression in vitro and in vivo aged spermatogonial stem cells to identify potential causes of observed phenotypic differences in aged spermatogonial stem cell function. Spermatogonial stem cells were isolated from young and serial-transplanted aged mouse donors and cultured for short and long periods. Spermatogonial stem cells were isolated from cultures and subjected to microarray analysis to identify differential gene expression.

Project description:Background: Production of functional sperms from spermatogonial stem cells in vitro is important for understanding of biological mechanisms underlying physiological spermatogenesis and for treatment of male infertility. However, comparing with the in vivo testes, in vitro spermatogenesis is severely lower efficiency. Here we describe abnormalities occurring in early stage of in vitro spermatogenesis at single cell resolution. Results: While spermatogenesis was similarly progressed between in vivo and in vitro-cultured testes, noticeable acute inflammatory response occurred right after in vitro culture of neonatal testes not only in immune cells but also non-immune testicular somatic cells. Inhibitor treatment revealed NLRP3 inflammasome signaling is key to the inflammation occurring in in vitro cultured testes We also found accumulation of damaged/dead germ cells in in vitro cultured testes, which may be due to dysfunction of sertoli cell phagocytosis. Conclusion: Our data revealed tissue-wide sterile inflammation occurring in in vitro cultured testes, in which DAMPs - NLRP3 inflammasome axis may key element. Thus, these abnormal testicular microenvironments may be a cause of low spermatogenesis efficiency of in vitro spermatogenesis.

Project description:Spermatogonial stem cells undergo both self-renewal to maintain the stem cell population and differentiation to produce mature sperm. These processes are controlled by both stem cell-intrinsic and external niche factors. DOT1L, the sole H3K79 methyltransferase, is dispensable for mouse embryonic stem cell self-renewal but instead functions as a barrier to somatic cell reprogramming. Here we show that DOT1L is required for spermatogonial stem cell self-renewal. Mice lacking DOT1L in the germ cells show a failure in the maintenance of spermatogonial stem cells without a block in spermatogenic cell differentiation and thus a progressive loss of germ cells, leading to a Sertoli-cell-only syndrome. Chemical inhibition of DOT1L in cultured stem cells reduces the spermatogonial stem cell activity after transplantation. RNA-seq analysis reveals downregulation of Hoxc cluster genes in DOT1L-inhibited spermatogonia stem cells. Single cell RNA-seq analysis demonstrates that inhibition of DOT1L sequesters spermatogonial stem cells in a primitive state and prevents them from transitioning to a progenitor state. These results identify a new function for DOT1L in adult stem cells and provides a paradigm for regulation of spermatogonial stem cell self-renewal. Self-renewal of spermatogonial stem cells is vital to life-long production of male gametes and thus fertility. However, the underlying mechanisms remain enigmatic. Here, we show that DOT1L, the sole H3K79 methyltransferase, is required for spermatogonial stem cell self-renewal. Mice lacking DOT1L fail to maintain spermatogonial stem cells, characterized by a sequential loss of germ cells from spermatogonia to spermatids and ultimately a Sertoli-cell-only syndrome. Inhibition of DOT1L reduces the stem cell activity after transplantation, prevents spermatogonial stem cells from transitioning to a progenitor state, and sequesters them in a primitive state. Furthermore, DOT1L promotes expression of the fate-determining HoxC transcription factors in spermatogonial stem cells. Our findings identify an essential function for DOT1L in adult stem cells and provide an epigenetic paradigm for regulation of spermatogonial stem cells.

Project description:ITGA6+ human testicular cell populations acquire a mesenchymal rather than germ cell transcriptional signature during long-term culture

Project description:In vitro and in vivo aging of mouse spermatogonial stem cells alters stem cell function based on quantitative spermatogonial stem cell transplantation analyses. We used microarrays to identify differential gene expression in vitro and in vivo aged spermatogonial stem cells to identify potential causes of observed phenotypic differences in aged spermatogonial stem cell function.

Project description:The aim of the study was to identify in vivo spermatogonial gene expression within the context of their biological niche. Identification of spermatogonial genes was done by t-testing on the replicates of Score 3 (Spermatogonia) and Score 2 (SCO) testicular biopsies. 3 biological replicates with spermatogonial presence in the tubuli seminiferi, 5 biological replicates with Sertoli-cell-only syndrome.

Project description:Peritubular cells of the human testis form a small compartment surrounding the seminiferous tubules. It contrast to rodents, it is composed of several cell layers and extracellular matrix. Peritubular cells are crucial for sperm transport and emerge as contributors to the spermatogonial stem cell niche, yet testicular peritubular cells are among the least known cell types of the human body. We employed single-cell RNA sequencing of cultured human testicular peritubular cells (HTPCs) isolated from testicular samples of donors with normal spermatogenesis and compared our data with recently published ex vivo data and, if available, with immunohistochemical data of the Human Protein Atlas. We observed a significant overlap between our results and genes expressed in vivo. Based on expression of a set of smooth muscle markers, HTPCs can be classified as smooth muscle cells. Small differences between in vivo/in vitro expressed genes may be due to plasticity/phenotypic switching. Plasticity was also shown upon addition of FCS to the culture medium. Based on transcriptome similarities four cellular states were observed. Characteristics of mesenchymal stromal cells and Leydig stem cells were noted, yet differentiation attempts into fat cells, bone cells or mature Leydig cells were not successful. Further analyses confirmed known stem cell niche-relevant factors (e.g. GDNF) and identified unknown functions e.g. the ability to produce retinoic acid. The results reveal that HTPCs upon isolation and culture are a highly adequate cellular model as they retain major characteristics. They therefore allow us to define the signature and functions of human testicular peritubular cells. The data may serve as a resource for future studies to better understand male (in)fertility.

Project description:The somatic microenvironment supports spermatogonial stem cell differentiation into sperm. Extracellular matrix (ECM) plays multiple roles in the stem cell niche, including self-renewal, proliferation, differentiation and survival of spermatogonial cells. The pathophysiology of male infertility might be representative of a progressive degenerative process of the testicular tissue, including ECM, rather than a defective genetic background, thus outlining the existence of chronic etiological agents/pathways. In this context, we sought to identify potential causative factors responsible for a number of modifications of the testicular somatic microenvironment associated with idiopathic germ cell aplasia in human beings. Proteomic analysis of the decellularized ECM was performed to study testis parenchyma from 10 idiopathic non-obstructive azoospermic (iNOA) men, dichotomized according to positive sperm retrieval versus germ cell aplasia. Germ cell aplasia was characterized by an increased nuclear distribution of the retinoic acid receptor in Sertoli cells which was associated with decreased expression of the ECM markers, Nidogen-2 and Heparan sulfate proteoglycan-2. Decreased levels of the interstitial matrisome associated Factor IX and its regulator VKORC1 were instead coupled with decreased signaling of vitamin K in Leydig cells. This study identified pathogenetic signature of the somatic testicular microenvironment and provide mechanistic insights into the molecular determinants of human idiopathic germ cell aplasia.

Project description:Smooth-muscle-like peritubular cells make up the wall of semniferous tubules of men. These human testicular peritubular cells (HTPC) have been shown to fulfill different roles. They transport sperm, secrete various factors like GDNF (glial cell line derived neurotrophic factor) and are immunologically active. They might contribute to spermatogonial stem cell niche altering and testicular ageing. Previous studies were limited regarding heterogeneity (due to lifestyle, age, medical history etc.) and accessibility of HTPCs. To circumvent this problem a cellular primate model should be established. The proteome of 6 MKTPCs of individual healthy and young (2 or 3 years) donors was assessed to investigate the suitability as a model.

Project description:In regenerative medicine, histocompatibility of pluripotent stem cells is required to solve the problem of immunorejection after therapeutic transplantation. In this study, we show that autologous germline stem cells (GSCs), often called spermatogonial stem cells, could be derived by testis biopsy from individual mice and that GSCs subsequently could be dedifferentiated into autologous germline-derived pluripotent stem (gPS) cells. The establishment of GSCs by testicular biopsy in the mouse model can prove the principle of human clinical application to derive autologous GSCs to generate patient-specific pluripotent cells for regenerative medicine.