Project description:About 10% of couples of reproductive age worldwide suffer from infertility, with male factors accounting for about 50%, and testosterone is essential for male fertility, but the mechanisms behind the poor sperm quality and abnormally low blood testosterone levels in diabetic patients are unclear. In this study, we found that the peptide Apelin (APLN) significantly inhibited testosterone secretion from Leydig cells (LCs), which in turn led to decreased sperm quality. APLN was found to be localized to leydig cells in the testes of several diabetic mice, and its expression was significantly increased. The addition of APLN to mouse leydig cells decreased testosterone content and decreased the expression of genes related to testosterone synthesis, but the addition of ML221, an APLN receptor inhibitor, significantly increased the expression of testosterone synthesis genes. Injecting ML221 into diabetic mice significantly increased testosterone levels in the blood, increased sperm count as well as enhanced sperm motility and ultimately increased live birth rate of mice after in vitro fertilization. Proteomics revealed that ML221 significantly increased the expression of NR2F2 and further activated the transcription of testosterone synthesis genes. This study will further use mouse and cellular models to completely unravel the specific mechanisms by which APLN inhibits testosterone secretion and elucidate the causes of decreased sperm quality in diabetic patients. This study provides a new clinical target for the development of drugs to improve fertility in diabetic patients.

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:Type 2 diabetes mellitus is one of the most prevalent metabolic diseases affecting multiple organs, including reproductive disorders in male diabetic patients. However, the molecular mechanisms that contribute to spermatogenesis dysfunction in diabetic patients have not yet been fully elucidated. Here, we performed Smart-seq2 to examine the transcriptome of diabetic patients' testis cells at single cell resolution including all major cell types of the testis. Intriguingly, whereas spermatogenesis appears largely preserved, the gene expression profiles of Sertoli cells and the blood-testis barrier (BTB) structure were dramatically impaired. Among the deregulated pathways, the Apelin (APLN) peptide /Apelin-receptor (APJ) axis was hyper-activated in diabetic patients. Mechanistically, APLN is produced locally by Sertoli cells upon high glucose treatment, which subsequently suppressed the production of carnitine and repressed the expression of cell adhesion genes in Sertoli cells. Together, these effects culminated in BTB structural dysfunction. Finally, using the small molecule APLN receptor antagonist, ML221, we show that blocking APLN/APJ significantly ameliorated the BTB damage and, importantly, improved functional spermatogenesis in diabetic db/db mice. We also translated and validated these findings in cultured human testis. Our findings identify the APLN/APJ axis as a promising therapeutic target to improve reproduction capacity in male diabetic patients.

Project description:Evidence that persistent environmental pollutants may target the male reproductive system is increasing. The male reproductive system is regulated by secretion of testosterone by testicular Leydig cells, and perturbation of Leydig cells function may have ultimate consequences. 3-methylsulfonyl-DDE (3-MeSO2-DDE) is a potent adrenal toxicants formed from the persistent insecticide DDT. Although studies have revealed endocrine disruptive effect of 3-MeSO2-DDE, the underlying mechanisms at cellular level in steroidogenic Leydig cells remains to be established. The current study addresses the effect of 3-MeSO2-DDE viability, hormone production and proteome response of primary neonatal porcine Leydig cells. The AlamarBlue™ assay was used to evaluate cell viability. Solid phase radioimmunoassay was used to measure concentration of hormones produced by both unstimulated and luteinizing hormone (LH)-stimulated Leydig cells following 48 h exposure. Protein samples from Leydig cells exposed to a non-cytotoxic concentration of 3-MeSO2-DDE (10µM) were subjected to nano-LC-MS/MS and analyzed on a Q Exactive mass spectrometer and quantified using label-free quantitative algorithm. Gene Ontology (GO) and Ingenuity Pathway Analysis (IPA) were carried out for functional annotation and identification of protein interaction networks. 3-MeSO2-DDE regulated Leydig cell steroidogenesis differentially depending on cell culture condition. Whereas its effect on testosterone secretion at basal condition was stimulatory, the effect on LH-stimulated cells was inhibitory. From triplicate experiments, a total of 7540 proteins were identified in which the abundance of 87 proteins in unstimulated Leydig cells and 146 proteins in LH-stimulated Leydig cells were found to be significantly regulated in response to 3-MeSO2-DDE exposure. These proteins not only are the first reported in relation to 3-MeSO2-DDE exposure, but also display small number of proteins shared between culture conditions, suggesting the action of 3-MeSO2-DDE on several targeted pathways, including mitochondrial dysfunction, oxidative phosphorylation, EIF2-signaling, and glutathion-mediated detoxification. Further identification and characterization of these proteins and pathways may build our understanding to the molecular basis of 3-MeSO2-DDE induced endocrine disruption in Leydig cells.

Project description:Bisphenol A (BPA), a prevalent endocrine disruptor, has been implicated in male reproductive dysfunction, particularly affecting Leydig cells (LCs), which are critical for testosterone production. Here, we explore the impact of BPA on m6A RNA methylation and its regulatory effects on autophagy and LC function. Utilizing both in vivo and in vitro models, we demonstrate that BPA exposure significantly reduces testosterone biosynthesis and upregulates m6A modification in LCs. The m6A 'writer' METTL3 and 'eraser' ALKBH5 were found to play a central role in regulating the m6A levels in Leydig cells upon BPA exposure, and manipulating m6A methylation level mitigates BPA-induced Leydig cell injury.

Project description:Arsenic is a widespread metalloid in environment, whose exposure has been associated with a broad spectrum of toxic effects. However, a global view of arsenic-induced male reproductive toxicity is still lack, and the underlying mechanisms remain largely unclear. Our results revealed that arsenic exposure decreased testosterone level and reduced sperm quality in rats. By conducting an integrated proteomics and metabolomics analysis, the present study aims to investigate the global influence of arsenic exposure on the proteome and metabolome in rat testis. The abundance of 70 proteins (36 up-regulated and 34 down-regulated) and 13 metabolites (8 increased and 5 decreased) were found to be significantly altered by arsenic treatment. Among these, 19 proteins and 2 metabolites were specifically related to male reproductive system development and function, including spermatogenesis, sperm function and fertilization, fertility, internal genitalia development, and mating behavior. It is further proposed that arsenic mainly impaired spermatogenesis and fertilization via aberrant modulation of these male reproduction-related proteins and metabolites, which may be mediated by the ERK/AKT/NF-κB-dependent signaling pathway. Overall, these findings will aid our understanding of the mechanisms responsible for arsenic-induced male reproductive toxicity, and from such studies useful biomarkers indicative of arsenic exposure could be discovered.

Project description:ZIKV infection is associated with testicular damage and abnormal spermatogenesis. However, the molecular mechanisms underlying these pathogenic processes remain unclear. Here, we demonstrate that ZIKV disrupts Leydig cells' ability to produce testosterone, leading to decreased sperm counts and motility. Specifically, the non-structural protein NS2A of ZIKV downregulates testosterone production by directly binding to mRNA of CYP17A1, a key enzyme in testosterone synthesis, thereby inhibiting its translation. Notably, the sole membrane-traversing segment and its flanking loops of NS2A are crucial for this interaction with CYP17A1 mRNA. Scanning mutagenesis studies within this sequence identified amino acid residues critical for NS2A binding and the suppression of CYP17A1 mRNA translation. Testicular inoculation of adeno-associated virus (AAV) delivering ZIKV-NS2A or its mutant showed that ZIKV-NS2A alone is sufficient to affect steroidogenesis and spermatogenesis in vivo. Moreover, a mutant virus generated by reverse genetics, containing a single amino acid mutation that abolishes NS2A’s binding to CYP17A1 mRNA, exhibited significantly lower inhibition of steroidogenesis and spermatogenesis compared to the wild-type virus in mouse models. These findings enhance our understanding of how ZIKV impacts male reproductive health and provide crucial insights for future preventive and therapeutic strategies.

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:Steroid hormones regulate essential physiological processes and inadequate levels are associated with various pathological conditions. In testosterone-producing Leydig cells, steroidogenesis is strongly stimulated by LH via its receptor leading to increased cAMP production and expression of the steroidogenic acute regulatory (STAR) protein, which is essential for the initiation of steroidogenesis. Leydig cell steroidogenesis then passively decreases following the rapid degradation of cAMP into AMP by phosphodiesterases. In this study, we show that AMP-activated protein kinase (AMPK) is activated following cAMP breakdown in MA-10 and MLTC-1 Leydig cells. Activated AMPK then actively inhibits cAMP-induced steroidogenesis by repressing the expression of key regulators of steroidogenesis including Star and Nr4a1. Similar results were obtained in Y-1 adrenal cells and in the constitutive steroidogenic cell line R2C. Our data identify AMPK as an active repressor of steroid hormone biosynthesis in steroidogenic cells that is essential to preserve cellular energy and prevent excess steroid production. Steroid hormones regulate essential physiological processes and inadequate levels are associated with various pathological conditions. In testosterone-producing Leydig cells, steroidogenesis is strongly stimulated by LH via its receptor leading to increased cAMP production and expression of the steroidogenic acute regulatory (STAR) protein, which is essential for the initiation of steroidogenesis. Leydig cell steroidogenesis then passively decreases following the rapid degradation of cAMP into AMP by phosphodiesterases. In this study, we show that AMP-activated protein kinase (AMPK) is activated following cAMP breakdown in MA-10 and MLTC-1 Leydig cells. Activated AMPK then actively inhibits cAMP-induced steroidogenesis by repressing the expression of key regulators of steroidogenesis including Star and Nr4a1. Similar results were obtained in Y-1 adrenal cells and in the constitutive steroidogenic cell line R2C. Our data identify AMPK as an active repressor of steroid hormone biosynthesis in steroidogenic cells that is essential to preserve cellular energy and prevent excess steroid production. MA-10 Leydig cells were treated with either DMSO (control), 10 uM forskolin or forskolin+Aicar (1 mM) for 1.5 h before total RNA extraction