Project description:Although testosterone deficiency (TD) may be present in 1 out of 5 men 40 years or older, the factors responsible for TD remain largely unknown. Leydig stem cells (LSCs) differentiate into adult Leydig cells (ALC) and produce testosterone in the testes under the pulsatile control of luteinizing hormone (LH) from the pituitary gland. However, recent studies have suggested that the testicular microenvironment (TME), which is comprised of Sertoli and peritubular myoid cells (PMC), plays an instrumental role in LSC differentiation and testosterone production under the regulation of the desert hedgehog signaling pathway (DHH). It was hypothesized that TME releases paracrine factors to modulate LSC differentiation. For this purpose, cells (Sertoli, PMCs, LSCs and ALCs) were extracted from men undergoing testis biopsies for sperm retrieval and were evaluated for the paracrine factors in the presence or absence of TME (Sertoli and PMC). The results demonstrated that TME secretes leptin which induces LSC differentiation and increases T production. Leptin’s effects on LSC differentiation and T production, however, are inversely concentration-dependent: positive at low doses and negative at higher doses. Mechanistically, leptin acts on LSCs upstream of DHH; leptin-DHH regulation functions unidirectionally insofar as DHH gain or loss of function has no effects on leptin levels. Taken together, these findings identify leptin as a key paracrine factor released by cells within the TME that modulates LSC differentiation and testosterone release from mature Leydig cells, a finding with important clinical implications for TD.

Project description:In addition to germ cell population, testes contain several types of somatic cells, including Sertoli cells, Leydig cells, and peritubular myoid (PTM) cells. PTM cells are a type of smooth muscle-like cells and have contraction ability. To identify a marker of PTM cells, we isolated primary cells and subsequently performed RNA-Seq of testicular peritubular myoid cells (PTM_1, PTM_2, PTM_3), testicular Sertoli cells (Sertoli_1, Sertoli_2, Sertoli_3), testicular Leydig cells (Leydig_1, Leydig_2, Leydig_3), testicular germ cells (Germ_1, Germ_2, Germ_3), vascular smooth muscle cells (VSMC_1, VSMC_2, VSMC_3), intestinal smooth muscle cells (ISMC_1, ISMC_2, ISMC_3), and tracheal smooth muscle cells (TSMC_1, TSMC_2, TSMC_3) using BGISEQ-500 platform (BGI, China).

Project description:In addition to germ cell population, testes contain several types of somatic cells, including Sertoli cells, Leydig cells, and peritubular myoid (PTM) cells. PTM cells are a type of smooth muscle-like cells and have contraction ability. To identify a marker of PTM cells, we isolated primary cells and subsequently performed miRNA-Seq of testicular peritubular myoid cells (PTM_1, PTM_2, PTM_3), testicular Sertoli cells (Sertoli_1, Sertoli_2, Sertoli_3), testicular Leydig cells (Leydig_1, Leydig_2, Leydig_3), testicular germ cells (Germ_1, Germ_2, Germ_3), vascular smooth muscle cells (VSMC_1, VSMC_2, VSMC_3), intestinal smooth muscle cells (ISMC_1, ISMC_2, ISMC_3), and tracheal smooth muscle cells (TSMC_1, TSMC_2, TSMC_3) using BGISEQ-500 platform (BGI, China).

Project description:Human testis development in prenatal life involves complex changes in germline and somatic cell identity. To better understand, we profiled and analyzed ~32,500 single-cell transcriptomes of testicular cells from embryonic, fetal and infant stages. Our data shows that at 6-7 weeks post-fertilization as the testicular cords are established, the Sertoli and interstitial cells originate from a common heterogeneous progenitor pool, which then resolves into fetal Sertoli cells (expressing tube-forming genes) or interstitial cells (including Leydig-lineage cells expressing steroidogenesis genes). Almost ten weeks later, beginning at 15-16 weeks post-fertilization, the male primordial germ cells exit mitosis, downregulate pluripotent transcription factors and transition into cells that strongly resemble the ‘State 0’ spermatogonia originally defined in the infant and adult testes. Therefore, we termed these fetal spermatogonia ‘State f0’. Taken together, we reveal multiple insights into the coordinated and temporal development of the embryonic, fetal and postnatal male germline together with the somatic niche.

Project description:Mammalian gonadal sex determination is dependent on proper expression of sex determining genes in fetal gonadal somatic support cells (i.e., pre-granulosa and pre-Sertoli cells in XX and XY gonads, resp.). We used a unique transgenic mouse strain combined with microarray profiling to identify all the differentially expressed transcripts in XX and XY isolated somatic support cells during critical stages of gonadal development and differentiation.

Project description:To examine the transcriptome of early testicular somatic cells during gonadogenesis at 12.5dpc RNA sequencing (RNA-Seq) was performed on murine primary testicular cell lineages isolated from the Sf1-eGFP line by FACS. The three main somatic cell lineages of the testis were isolated: the Sertoli cells which direct male development; the fetal Leydig cells (FLCs) that produce steroid hormones and virilise the XY individual and a heterogenous population of interstitial cells, some of which give rise to the adult Leydig cells (ALCs). This dataset provides a platform for exploring the biology of FLCs and understanding the role of these cells in testicular development and masculinization of the embryo, and a basis for targeted studies designed to identify causes of idiopathic XY DSD. RNA-Seq of 3 enriched cell populations from 12.5dpc mouse gonad (Sertoli cells, Leydig cells and Interstitial cells isolated by FACS-sorting) on an Illumina HiSeq 1500, in triplicate.

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:Mammalian gonadal sex determination is dependent on proper expression of sex determining genes in fetal gonadal somatic support cells (i.e., pre-granulosa and pre-Sertoli cells in XX and XY gonads, resp.). We used a unique transgenic mouse strain combined with microarray profiling to identify all the differentially expressed transcripts in XX and XY isolated somatic support cells during critical stages of gonadal development and differentiation. Experiment Overall Design: XX and XY somatic support cells (SSC) were isolated by flow cytometry from embryonic day (E) 11.5 and E12.5 mouse gonads. Total RNA was isolated from pools of isolated cells; 3 pools per sex and each timepoint.

Project description:Germ cell aplasia represents the most severe form of male infertility, and is associated with increased risk of early onset age-related chronic diseases and higher risk of death. Here we investigated the transcriptional landscape of 3880 somatic cells clustered in Sertoli, peritubular Myoid, Leydig, endothelial, stromal, T cells and macrophages from 3 human testis with idiopathic germ cell aplasia. Deregulated somatic pathways were associated with over-expression of paternally imprinted genes in immature Leydig cells, extracellular matrix composition and organization, hormonal milieu, chronic pro-inflammatory environments and early ageing, which were validated with an external cohort of 44 men with idiopathic germ cell aplasia compared to 102 age-matched fertile men. These 7 transcriptomic datasets unveil new insights into the germ cell aplasia, and prompts new thinking to better understand the pathogenesis of the idiopathic disease and the associated clinical manifestations of early ageing process.

Project description:The ability of male reproduction is seriously dependent on Sertoli cells. However, the mechanisms governing the functional integrity of Sertoli cells remained largely unexplored. Tyrosine phosphatase protein Shp2 is expressed in germ, Leydig and Sertoli cells of mice testes. But the physiological role of Shp2 in the spermatogenesis was not fully understood. Thus, we conditionally deleted Shp2 gene in Sertoli cells using two transgenic models, and demonstrated that Shp2 deficiency caused infertility, excessive differentiation of SSCs and abnormal BTB in mice. To further discover the underlying mechanism of Shp2 regulation, we collected the mRNA of testes from wild type or knockout mice at 16.5 fetal day, Postnatal 3 days, 1 weeks, 2 weeks, and then screened the gene expression. Testis tissues from Shp2f/f and SCSKO mice were for RNA extraction and hybridization on Affymetrix microarrays.