Project description:Testicular fetal Leydig cells are specialized for androgen production during embryogenesis. Testosterone is essential for regulating sex differentiation, spermatogenesis, and fertility. Deficiencies in Leydig cell differentiation can lead to various disorders of sex development and male reproductive conditions, such as ambiguous genitalia, hypospadias, cryptorchidism, and infertility. Understanding the differentiation of fetal Leydig cells is essential for comprehending male sexual differentiation, reproductive health, and fertility. Fetal Leydig cells originate from proliferating progenitor cells in the gonadal interstitium, marked by genes like Arx, Pdgfra, Tcf21, Wnt5a, and Nr2f2. However, the precise mechanisms governing the transition from interstitial cells to Leydig cells remain elusive. Through integrated approaches involving animal models and multiomics, we have demonstrated that fetal Leydig cells originate from a Nr2f2 positive non-steroidogenic interstitial cell population. NR2F2 promotes progenitor cell fate while suppressing Leydig cell differentiation. Moreover, embryonic deletion of Nr2f2 in mouse testes resulted in disorders of sex development, including reduced testicular size, Leydig cell hypoplasia, cryptorchidism, and hypospadias. Collectively, our findings highlight the critical role of Nr2f2 in orchestrating the transition from interstitial cells to Leydig cells during testicular development.

Project description:Testicular fetal Leydig cells are specialized for androgen production during embryogenesis. Testosterone is essential for regulating sex differentiation, spermatogenesis, and fertility. Deficiencies in Leydig cell differentiation can lead to various disorders of sex development and male reproductive conditions, such as ambiguous genitalia, hypospadias, cryptorchidism, and infertility. Understanding the differentiation of fetal Leydig cells is essential for comprehending male sexual differentiation, reproductive health, and fertility.

Project description:Testicular fetal Leydig cells are specialized for androgen production during embryogenesis. Testosterone is essential for regulating sex differentiation, spermatogenesis, and fertility. Deficiencies in Leydig cell differentiation can lead to various disorders of sex development and male reproductive conditions, such as ambiguous genitalia, hypospadias, cryptorchidism, and infertility. Understanding the differentiation of fetal Leydig cells is essential for comprehending male sexual differentiation, reproductive health, and fertility. Fetal Leydig cells originate from proliferating progenitor cells in the gonadal interstitium, marked by genes like Arx, Pdgfra, Tcf21, Wnt5a, and Nr2f2 (COUP-TFII). However, the precise mechanisms governing the transition from interstitial cells to Leydig cells remain elusive. Through integrated approaches involving animal models and multiomics, we have demonstrated that fetal Leydig cells originate from a COUP-TFII positive non-steroidogenic interstitial cell population. COUP-TFII promotes progenitor cell fate while suppressing Leydig cell differentiation. Moreover, embryonic deletion of COUP-TFII in mouse testes resulted in disorders of sex development, including reduced testicular size, Leydig cell hypoplasia, cryptorchidism, and hypospadias. Collectively, our findings highlight the critical role of COUP-TFII in orchestrating the transition from interstitial cells to Leydig cells during testicular development.

Project description:Decreasing fertility rates has emerged as a significant social and medical concern, with male infertility accounting for at least half of the cases. Conventional semen analysis offers restricted prognostic utility for male fertility, largely because a considerable number of male infertility incidents are attributed to dysfunctions in the testicular interstitium. Here we have not only characterized transcriptome data and reveals Cd34+/Sox4+ mesenchymal cells as potential Leydig cell progenitor, but also examined super enhancers information in both young, adult and aged mice Leydig cell progenitors. Our findings reveal A comprehensive atlas of testicular interstitium during aging in both H3K27ac modifications and gene expression alterations. Specifically, the transcriptional activities of key genes involved in progenitor stemness appear to be regulated by super-enhancers. These discoveries offer pivotal insights for developing novel cell-based therapies to ameliorate testicular dysfunction in older individuals.

Project description:Decreasing fertility rates has emerged as a significant social and medical concern, with male infertility accounting for at least half of the cases. Conventional semen analysis offers restricted prognostic utility for male fertility, largely because a considerable number of male infertility incidents are attributed to dysfunctions in the testicular interstitium. Here we have not only characterized transcriptome data and reveals Cd34+/Sox4+ mesenchymal cells as potential Leydig cell progenitor, but also examined super enhancers information in both young, adult and aged mice Leydig cell progenitors. Our findings reveal A comprehensive atlas of testicular interstitium during aging in both H3K27ac modifications and gene expression alterations. Specifically, the transcriptional activities of key genes involved in progenitor stemness appear to be regulated by super-enhancers. These discoveries offer pivotal insights for developing novel cell-based therapies to ameliorate testicular dysfunction in older individuals.

Project description:We investigated somatic cell dynamics in testicular tissue lacking spermatogenesis using model mice with testis-specific deletion of the histone H3 variant gene H3t. Leydig cells in testes lacking spermatogenesis led to increased testosterone synthesis that occurred alongside a high inflammatory response and oxidative stress.

Project description:We investigated somatic cell dynamics in testicular tissue lacking spermatogenesis using model mice with testis-specific deletion of the histone H3 variant gene H3t. Leydig cells in testes lacking spermatogenesis led to increased testosterone synthesis that occurred alongside a high inflammatory response and oxidative stress.

Project description:Prkar1a encodes the regulatory subunit R1a of the proteine kinase A. Prkar1a ablation in the testis results in profound alterations of tissue homeostasis leading to tumor development and infertility. We used microarrays to analyze gene expression in response to Prkar1a gene ablation in testicular somatic cells (derived from SF1+ cells) (prKO model), in Sertoli cells (sKO model) or in Leydig cells (lrKO model) in 2-week and 2-month-old mouse testes.

Project description:The global infertility rate has been increasing annually, and male infertility becoming severe. The proportion of idiopathic infertility is high, with most patients with ambiguous clinical symptoms. These symptoms manifested as declining semen quality, and the effects of autoimmune factors on this measure of fertility cannot be ignored. Aside from anti-sperm antibody for autoimmune infertility, detection indexes for male infertility are lacking. We successfully collected seminal fluid via electric stimulation from an experimental model of autoimmune orchitis in rats. We used the most advanced isobaric tags for relative and absolute quantitative proteomics analysis to analyze the seminal plasma of autoimmune infertility.

Project description:Leydig cells (LCs) are the primary androgen producing cells in males throughout development and appear in chronologically distinct populations; fetal Leydig cells (FLCs), neonatal LCs and adult Leydig cells (ALCs). ALCs are responsible for progression through puberty and for maintenance of reproductive functions in adulthood. In patients with reproductive problems, such as infertility or testicular cancer, and especially in men with high gonadotrophin levels, LC function is often impaired, and LCs may cluster abnormally into hyperplastic micronodules. The purpose of this study was to investigate whether ALCs within hyperplastic micronodules display characteristics of FLCs. Transcriptome profiling was performed on LCs microdissected from 12 frozen human tissue samples, including morphologically normal foetal (gestational week 10-11) and adult testis samples, and adult specimens with LC micronodules or LC micronodules adjacent to chorionic gonadotrophin (hCG)-producing testicular germ cell tumours. Fifteen additional foetal and adult testis tissue specimens were used for validation of the expression data at the protein level. The study revealed the the gene expression profiles of FLCs and all ALC subgroups were clearly different, but there were no significant differences in expressed genes between the normally clustered and hyperplastic ALCs. Close similarity between transcriptome profiles of the normally clustered and hyperplastic ALCs suggest that the changes in LC function and morphology observed in patients with reproductive disorders possibly reflect subtle changes in the expression of many genes rather than regulatory changes of single genes or pathways. The transcriptome of FLCs revealed several genes not known previously to be expressed in this cell type during early development, including SULT2A1, WISP2, HPGD, and IGF2BP1, and their expression changes were validated at the protein level.