Search Results (1,503)

Benign prostatic hyperplasia (BPH) is a significant health issue among ageing men, with ongoing research focused on elucidating its underlying mechanisms and improving experimental models. Testosterone Propionate (TP) is the first line of choice for the induction of BPH in experimental rodent models. However, TP’s controlled status as a Schedule III drug in the United States and a Class C drug in the UK presents challenges in obtaining TP for experimental use, giving preference to the sulpiride model since it is easily obtained as an alternative for the induction and study of BPH. A comprehensive literature search was conducted across multiple electronic databases, including PubMed/MEDLINE, Embase, and Web of Science. The primary PubMed search strategy included combinations of Medical Subject Headings (MeSH) and free-text terms: (“Benign prostatic hyperplasia induction” OR “and rodent models’’) AND (“Testosterone Propionate model”) AND (“sulpiride model”). Studies were included if they induced BPH (using testosterone or sulpiride models). Titles and abstracts were screened for relevance; eligible articles underwent full-text review, with data extracted thematically. No formal risk-of-bias scoring was used due to the narrative approach; instead, studies were appraised by design, rigor, plausibility, and evidence. This study reviewed published and publicly available data, so no ethical approval was required. Although both TP and sulpiride induce BPH via various mechanisms, this review provides a comparative analysis of these two commonly utilised models for studying BPH. In the TP approach, castrated rodents receive daily subcutaneous injections for 4 weeks, resulting in dihydrotestosterone (DHT)-mediated epithelial hyperplasia predominantly affecting the ventral prostate lobes. Conversely, the sulpiride model is non-invasive, employs intact animals treated with sulpiride, and induces hyperprolactinemia-mediated BPH via interactions with androgen and oestrogen receptor pathways that stimulate prostatic stromal and epithelial proliferation, particularly in the lateral and dorsal lobes, representing an alternative method. We also highlight the strengths and limitations of TP and sulpiride in replicating clinical symptoms and examine the toxicological effects of sulpiride on the kidney, testis, liver, and brain. We recommend the sulpiride model for the induction and studying of BPH, as it is readily accessible and closely mimics the pathogenesis of BPH in humans, unlike the TP model, which requires castration. Full article

Stem cells maintain tissue homeostasis through precisely regulated self-renewal and differentiation, processes largely dependent on metabolic control. The Drosophila testis provides an ideal model system to study metabolism regulation of stem cell homeostasis due to many advantages, including its well-defined stem cell niche architecture and genetic tractability. Recent studies have revealed that germline stem cells (GSCs) and somatic cyst stem cells (CySCs) exhibit distinct metabolic profiles. In particular, GSCs exhibit a metabolic feature closely associated with mitochondrial dynamics, lipid metabolism, and redox homeostasis, all of which are essential for maintaining their stem identity through the regulation of TOR (Target of Rapamycin) signaling. Nutrient sensing through the insulin/TOR, BMP, and JAK-STAT pathways integrates nutritional cues with developmental programs. Lipid metabolism and membrane homeostasis further contribute to the maintenance of stem cells. Metabolic intermediates function as signaling molecules, modulating niche-stem cell interactions and epigenetic modifications in stem cells. Hence, dysregulation of metabolic homeostasis can lead to stem cell depletion and age-related reproductive decline. This review synthesizes the current understanding of metabolic regulation in Drosophila testis stem cell maintenance, identifies critical knowledge gaps, and explores future research directions such as spatial/temporal metabolomics approaches. Lastly, we highlight how these insights may help understand mammalian stem cell biology and regenerative medicine. Full article

Chinese tongue sole (Cynoglossus semilaevis) is an important mariculture product in northern China, exhibiting significant sexual dimorphism: females grow 2–4 times faster than males and ultimately attain much greater body weights. As a well-known transcription factor crucial for regulating sex differentiation, foxl2 has been characterized in various mammals. Herein, we identified and characterized three foxl genes, foxl1, foxl2a and foxl2l. Three foxl genes exhibited a gonad-biased expression pattern, where foxl2a showed higher expression in ovary than in testis, while foxl1 and foxl2l exhibited higher expression in testis. All foxl genes were detected in testes and ovaries by ISH; foxl1/foxl2l were expressed in oocytes and sperm, and foxl2a in granulosa cells and sperm. Overexpression of foxl in testicular cells led to KEGG enrichment in DNA repair, MAPK, FOXO and progesterone-mediated oocyte maturation pathways. In tongue sole testicular cell line, knockdown of foxl1 and foxl2l resulted in upregulation of multiple male-related genes. In contrast, knockdown of foxl2a led to decreased expression of aromatase genes and increased expression of ctnnb1, indicating that foxl2a is more closely associated with female differentiation and maintenance. Our study investigated the functions of the foxl gene family in teleosts and offers valuable insights into their role in sex differentiation and gonadal maintenance in teleost fish. Full article

Objective: Although Hu sheep are renowned for their high fecundity, the multi-tissue regulatory networks governing spermatogenesis, particularly within the hypothalamic–pituitary–testicular (HPT) axis, remain poorly understood. This study aimed to elucidate these mechanisms by performing a comparative proteomic analysis of the HPT axis in Hu sheep and three other breeds. Methods: We utilized data-independent acquisition (DIA) proteomics to analyze hypothalamic, pituitary, and testis tissues from 36 samples across four breeds. The experimental workflow included protein extraction, enzymatic digestion, LC-MS/MS, and subsequent bioinformatic analyses, complemented by histological examination. Results: Hu sheep exhibited accelerated testicular development and an earlier onset of spermatogenesis. Comprehensive proteomic profiling identified a total of 10,528 proteins, with 771 differentially expressed proteins (DEPs) detected in the testis. These testicular DEPs were significantly enriched in pathways related to spermatogenesis, the blood–testis barrier, and steroid hormone biosynthesis. Notably, the cAMP signaling pathway was consistently enriched across all three tissues, underscoring its pivotal role in regulating spermatogenesis. Protein–protein interaction (PPI) network analysis further highlighted hub proteins, such as MET, suggesting their potential involvement in somatic cell functions and the spermatogenic microenvironment. Key findings were validated by Western blot analysis. Conclusion: This study is the first multi-tissue proteomic investigation proposing a model in which the high reproductive performance of Hu sheep is potentially linked to the efficient, coordinated regulation of spermatogenesis-related proteins and signaling pathways—particularly in the testis. These findings offer novel insights into the molecular mechanisms of male reproduction in sheep and identify potential targets for future research and breeding applications. Full article

The blood–testis barrier (BTB) is a highly specialized and dynamic junctional structure formed by adjacent Sertoli cells that is essential for maintaining testicular immune privilege and supporting spermatogenesis. While the BTB undergoes tightly regulated, stage-dependent remodeling under physiological conditions, inflammatory stimuli can profoundly disturb this process. Accumulating evidence indicates that inflammatory conditions disrupt BTB integrity by altering junctional protein organization, cytoskeletal dynamics, and barrier permeability. We aimed to integrate current evidence to elucidate the key pathways by which inflammation impairs BTB integrity, drawing on studies using intratesticular administration of pro-inflammatory cytokines and experimental rodent models of reproductive dysfunction characterized by pathological inflammation, including chemotherapy-induced inflammation and orchitis. Collectively, findings from these models demonstrate that inflammatory signaling compromises BTB integrity, destabilizes the spermatogenic niche, and may contribute to impaired spermatogenesis. Our narrative review frames the BTB as a dynamic and inflammation-sensitive structure whose regulation emerges from the coordinated action of inflammatory pathways, cytoskeletal remodeling, and junction-associated signaling modules, rather than from isolated molecular events. Full article

Heat stress (HS) severely impairs boar reproductive function by inducing oxidative stress and inflammatory responses, while lycopene (LYC), as a potent antioxidant, exerts a potential protective effect on the male reproductive system. This study aimed to clarify the mechanism underlying LYC-mediated alleviation of HS-induced decline in semen quality in Rongchang boars, identify the most affected tissues, and explore its regulatory role in the Nrf2 (Nuclear factor E2-related factor 2) pathway. A total of 18 Rongchang boars with an initial body weight of 15.81 ± 1.07 kg were randomly assigned to three groups (6 boars per group): the control group (CON, 26 ± 1 °C), the heat stress group (HS, exposed to 35 ± 1 °C for 8 h daily), and the heat stress + 100 mg/kg lycopene group (HS + LYC). After 28 days of adaptive feeding and 14 days of HS treatment, samples were collected for semen quality analysis, testicular histological analysis, antioxidant index detection, transcriptome analysis, Nrf2 pathway detection, and inflammatory index detection. The results showed that HS significantly increased the sperm abnormality rate (p < 0.05), damaged the testicular structure, and induced oxidative stress in serum, lung, liver, left ventricle, testis, and epididymis (caput epididymis, corpus epididymis, cauda epididymis), with varying degrees of oxidative stress observed in these samples. Among these tissues, the testis and cauda epididymis exhibited the most significant responses to HS and LYC, with the comprehensive impact magnitudes of 317% and 514%, respectively. Enrichment analysis of differentially expressed genes (DEGs) in these two tissues revealed that the pathways mediating oxidative stress response displayed distinct tissue specificity, and all of them were closely associated with the Nrf2 antioxidant signaling pathway. HS significantly downregulated the mRNA expressions of Nrf2, Quinone Oxidoreductase (NQO1), Heme Oxygenase 1 (HMOX1) and Glutamate-Cysteine Ligase Catalytic Subunit (GCLC) genes as well as the protein level of Nrf2 in the testis and cauda epididymis, increased the protein level of Keap1, and significantly elevated the levels of interleukin-6 (IL-6), interleukin-1β (IL-1β) and tumor necrosis factor-α (TNF-α) in these two tissues (p < 0.05). Compared with the HS group, dietary supplementation of LYC significantly improved sperm motility and the proportion of rapidly progressive sperm, reduced the proportion of immotile sperm and sperm abnormality rate (p < 0.05), alleviated testicular damage and oxidative stress in various tissues, upregulated the mRNA expressions of Nrf2 and HMOX1 genes in the testis as well as the mRNA expressions of Nrf2, NQO1, HMOX1 and GCLC genes in cauda epididymis (p < 0.05), significantly increased the Nrf2 protein level and decreased the Keap1 protein level in these two tissues, and simultaneously decreased the levels of the aforementioned inflammatory factors (p < 0.05). In conclusion, dietary supplementation with 100 mg/kg LYC can alleviate HS-induced decline in semen quality and testicular damage by regulating the oxidative status and inflammatory level of relevant tissues (e.g., testis and cauda epididymis) in boars, and this protective effect may be associated with the regulation of the Nrf2 signaling pathway. Full article

In Italy, the breeding of alpacas (Vicugna pacos) is on the rise, driven by the value of their precious wool and their docile temperament. This growth is, however, severely limited by the species’ reproductive inefficiency. This study aimed to investigate the specific role of the neuropeptide orexin A (OxA) and its receptor OX1R in modulating testicular steroidogenesis in the alpaca, testing the hypothesis that the OxA/OX1R pathway stimulates testosterone production. Using testicular tissue from two groups of adult male alpacas (five- and seven-year-olds, n = 6 per group), we combined immunohistochemistry with ex vivo functional assays. Immunohistochemical analysis confirmed the expression of both OxA and OX1R in Leydig cells. Functional studies on testicular fragments demonstrated that OxA enhanced testosterone synthesis via OX1R activation. Furthermore, OxA reduced estradiol levels by suppressing aromatase activity and counteracted the inhibitory effect of Müllerian inhibiting substance (MIS) on testosterone secretion. These results provide the first evidence that the peripheral OX1R pathway is functionally involved in promoting a testosterone-dominant steroidogenic milieu in alpaca testes. This preliminary study identifies the orexin system as a potential target for developing strategies to improve reproductive management in this species. Full article

This study aimed to determine the sexual maturation pattern of Shenxian pigs by combining observation, teaser boar testing, and back-pressure methods, and to apply this pattern for early breeding to shorten the generation interval and increase production efficiency. Subsequently, high-throughput transcriptome technology was used to compare gene expression levels in testicular tissues of Shenxian pigs before and after sexual maturity, as well as between sexually mature Shenxian pigs and Shenxian × Large White crossbred pigs. Functional analysis of differentially expressed genes (DEGs) was conducted to screen candidate genes related to sexual maturation and precocity in Shenxian pigs. The results showed that boars reached sexual maturity at an average age of 116 days in winter and 129 days in summer. For sows, the first estrus occurred at 114 days, the second at 134 days, and the third at 154 days in winter; corresponding ages in summer were 125, 144, and 164 days, respectively. The duration of estrus was around 3 days, and the estrus interval was approximately 20 days for both seasons. Comparative trials revealed no significant change in production performance when selection and first mating were conducted at 5 months of age compared to previous practices. Transcriptome sequencing of testicular tissues before and after sexual maturity in Shenxian pigs identified 6016 upregulated genes, primarily associated with reproduction and sperm function, influencing sexual maturation. The comparison between sexually mature Shenxian pigs and crossbred pigs identified 582 upregulated genes, mainly involved in hormone synthesis, affecting the onset of puberty in Shenxian pigs. After intersecting and functionally analyzing the upregulated genes from both sets, SRD5A1 and CYP11B2 were selected as the most likely candidate genes to affect precocious puberty in Shenxian pigs. Full article

The yak (Bos grunniens) thrives under chronic hypoxia and cold on the Qinghai–Tibet Plateau, yet a cross-tissue view of post-transcriptional regulation in this species remains limited. Here, we integrated multi-tissue RNA-seq and miRNA-seq data (tissues pooled from three Maiwa yaks) to construct and compare tissue-specific competing endogenous RNA (ceRNA) networks, while explicitly addressing a major source of false positives in ceRNA inference—misclassified lncRNA candidates with translational signatures. We cataloged 10,037 high-confidence lncRNAs (9360 non-redundant), 234 circRNAs, and 1030 miRNAs across six tissues. We then used Ribo-seq as an orthogonal quality-control layer to remove lncRNA candidates showing clear ribosome-association signals prior to network construction. Using a shared-target strategy (7mer-m8 seed matches; a ceRNA edge required ≥5 shared miRNAs), we assembled ceRNA networks for liver, lung, spleen, testis, and small intestine; skeletal muscle was excluded owing to insufficient Ribo-seq support for consistent filtering. Network topology varied substantially across tissues, with the testis network exhibiting the highest connectivity. ceRNA edges showed minimal overlap between tissues, indicating strong tissue dependence, whereas miRNA load/use profiles were moderately concordant, supporting a hierarchical conserved core—variable periphery organization. Importantly, the Ribo-seq–filtered lncRNA set provides a separate pool of ribosome-associated candidates for targeted follow-up, although ribosome association alone does not establish stable micropeptide production. Together, our results deliver a multi-tissue ceRNA resource and a reproducible, evidence-aware workflow for prioritizing candidate regulators while reducing annotation-driven false positives in yak. Full article

Male infertility contributes substantially to couple infertility, and a large proportion of cases remain idiopathic. Dysbiosis within the gut, seminal, and urinary microbiomes has been associated with impaired semen parameters, reproductive tract inflammation, and oxidative stress. This narrative review, informed by a structured literature search, summarizes current evidence for the gut–testis axis and the androbactome in male infertility and discusses mechanistic pathways linking microbial imbalance to sperm dysfunction. Proposed mechanisms include immune activation, increased oxidative stress, endocrine and metabolic perturbations, and disruption of epithelial barriers, including the blood–testis barrier. Early clinical trials report that selected probiotic or synbiotic formulations may be associated with improvements in one or more World Health Organization (WHO) semen parameters and with reductions in oxidative or inflammatory biomarkers (surrogate laboratory endpoints; pregnancy and live-birth outcomes are rarely reported and remain unproven) in selected populations, such as idiopathic infertility and the post-varicocelectomy setting. Given patient heterogeneity, a personalized approach requires prespecified clinical phenotypes and measurable monitoring targets, rather than indiscriminate supplementation. At present, probiotics should be considered an adjunct rather than a stand-alone therapy. Well-designed, contamination-aware microbiome studies and adequately powered randomized trials with clinically meaningful endpoints, including pregnancy and live birth, are required before routine clinical implementation. This synthesis is intended to support personalized counseling and trial design by clarifying candidate phenotypes, appropriate monitoring endpoints, and realistic limitations of current evidence. Full article

Studies of adult depressed patients report that selective serotonin (5-HT) reuptake inhibitors (SSRIs) like clomipramine (CMI) have secondary effects on sperm quality. The epididymis possesses an autonomous serotonergic system critical for sperm maturation, whose establishment during neonatal development remains unexplored as a target for SSRI programming. We hypothesized that neonatal CMI exposure would disrupt the developing epididymal 5-HT system, leading to permanent sperm dysfunction. CMI (30 mg/kg s.c.) was administered to male rats between postnatal days 8–21. At 3 months, sperm from the epididymal cauda was evaluated, and 5-HT levels were measured in the testis, caput, and cauda epididymis. Our novel findings demonstrate that neonatal CMI exposure induces region-specific, long-term alterations in epididymal 5-HT levels (decreased in caput, increased in cauda) without affecting testicular 5-HT. This reprogramming of the local serotonergic milieu was associated with reduced sperm concentration, viability, normal morphology, and motility, alongside increased mitochondrial activity and reactive oxygen species. This study reveals, for the first time, that the epididymal serotonergic system is a key target for neonatal SSRI programming, providing a mechanistic link (altered 5-HT homeostasis) between early-life exposure and persistent sperm defects in adulthood. Full article

Background: Cyclophosphamide (CYC) is an effective chemotherapeutic agent and immunosuppressant drug. Former research showed that CYC induces testicular toxicity through oxidative stress, inflammation and apoptosis. Saroglitazar (SAR) is a dual PPARα/γ agonist, used for treatment of diabetic dyslipidemia. Purpose: This study aimed to elucidate the protective impact of SAR against CYC-linked testicular toxicity. Methods: Randomly, thirty adult male rats were alienated into control group, SAR (4 mg/kg) group, CYC (200 mg/kg) group, CYC+SAR (2 mg/kg) group and CYC+SAR (4 mg/kg) group. SAR was orally administered at two doses (2 and 4 mg/kg) for 7 days. CYC was injected intraperitoneally at dose (200 mg/kg) at day 7. Results: In comparison to the CYC group, SAR at the dose of 2 and 4 mg/kg significantly increased testis weight, testicular index, sperm count, serum testosterone and serum luteinizing hormone. Additionally, SAR at both doses induced a significant reduction in testicular MDA content in addition to increased testicular levels of GSH and TAC. Furthermore, SAR markedly upregulated testicular levels of PPARγ, Nrf2 and HO-1 in addition to decreased testicular expression of NF-κB, IL-6 and TNF-α, illustrating its antioxidant and anti-inflammatory effect. SAR also significantly decreased testicular expression of caspase-3 and Bax and increased Bcl2 expression, indicating its anti-apoptotic effect. Conclusions: SAR at doses (2 and 4 mg/kg) could ameliorate CYC-induced testicular injury in rats, possibly through antioxidant, anti-inflammatory and anti-apoptotic effect. Full article

Nonsense-mediated mRNA decay (NMD) is a highly conserved RNA quality and quantity surveillance machinery in eukaryotic cells, serving as an important node in the post-transcriptional gene expression. Previous studies using the complete knockout of individual NMD factors in cells or animals reveal that NMD deficiency causes developmental defects and compromises tissue homeostasis. However, because most NMD factors participate in multiple molecular functions, a direct link between NMD and cell fate determination is missing. SMG6 is a core NMD effector and the only endoribonuclease among all NMD factors. The NMD function of SMG6 is exclusively mediated by its PIN (PilT N-terminus) domain. In this study, we engineered a mouse model with the capability of specifically deactivating the SMG6’s PIN domain/endoribonuclease activity (Smg6-PIN^F/F), but not knocking out the complete SMG6 protein. We found that SMG6’s PIN domain is essential for NMD activity in embryonic stem cells (ESCs) and various tissues of adult mice. Furthermore, loss of SMG6’s PIN domain is dispensable for the mouse ESC self-renewal, but severely compromises the differentiation, which consequently causes the mutant mice to die during the process of organogenesis. Through the induced deletion of SMG6’s PIN domain in adult mice, we found that loss of SMG6’s NMD function affects the homeostasis of several mouse tissues, including the testis and the intestine. In sum, our study establishes a mechanistic link between NMD per se and cell fate determination of mouse ESCs, as well as in the tissues of adult mice, where cell fate transitions are actively ongoing. The Smg6-PIN^F/F mouse line could be a valuable strain for elucidating the biology of NMD per se. Full article

Male infertility is increasingly recognized as a complex, multifactorial disorder that extends beyond abnormalities in conventional semen parameters. A growing body of evidence highlights oxidative stress, sperm DNA fragmentation (SDF), and epigenetic alterations as tightly interconnected mechanisms contributing to sperm dysfunction and impaired fertility. Reactive oxygen species, though vital for sperm maturation and signaling, can inflict extensive genomic and chromatin damage when their levels exceed the antioxidant capacity of the testis and seminal plasma. These redox-driven lesions not only compromise fertilization potential but may also influence embryonic development and offspring health. Clinical studies and meta-analyses consistently report that elevated SDF and redox imbalance are associated with reduced pregnancy and live birth rates, particularly in assisted reproductive technologies (ARTs). The use of testicular sperm in men with high ejaculated SDF appears to improve ART outcomes, although long-term safety data remain limited. Advances in redox and genomic diagnostics, including assays for oxidation–reduction potential, SDF, and sperm epigenetic profiling, have opened new avenues for precision-based andrology, enabling targeted antioxidant, metabolic, and surgical interventions. Nonetheless, methodological variability, lack of assay standardization, and insufficient longitudinal follow-up constrain the full clinical translation of these findings. This review synthesizes evidence linking OS, SDF, and epigenetic alterations, highlighting their mechanistic crosstalk and translational relevance in the personalized management of male infertility. Full article

Molecular sex determination in Syrian hamsters (Mesocricetus auratus) has been limited by the incomplete annotation of Y-linked loci in currently available genome assemblies. Here, we evaluate the Y-linked gene PRSSLY, which encodes a testis-specific serine protease-like protein, as a molecular marker for genetic sexing of Syrian hamster embryonic and placental tissues. Primers flanking a conserved PRSSLY coding region produced a male-specific amplicon showing 100% concordance with results from the established KDM5C/KDM5D PCR assay in E15.5 tail biopsies. SYBR Green–based qPCR enables the accurate detection of PRSSLY, characterized by a unique melt-curve profile, exclusively in male samples, allowing for efficient and sensitive mid-throughput analysis. Application of the PRSSLY assay to 417 placental samples from 39 dams demonstrated its suitability for large-scale sex genotyping, enabling sex assignment in the majority of samples despite the intrinsic complexity of placental tissue containing both maternal and embryonic genetic material. This assay provides a robust and reproducible approach for accurate sex genotyping in developmental and reproductive studies using Syrian hamsters. Full article