Spermatogonial Stem Cells Research Articles

Epigenetic characterization of adult rhesus monkey spermatogonial stem cells identifies key regulators of stem cell homeostasis.

Spermatogonial stem cells (SSCs) play crucial roles in the preservation of male fertility. However, successful ex vivo expansion of authentic human SSCs remains elusive due to the inadequate understanding of SSC homeostasis regulation. Using rhesus monkeys (Macaca mulatta) as a representative model, we characterized SSCs and progenitor subsets through single-cell RNA sequencing using a cell-specific network approach. We also profiled chromatin status and major histone modifications (H3K4me1, H3K4me3, H3K27ac, H3K27me3 and H3K9me3), and subsequently mapped promoters and active enhancers in TSPAN33+ putative SSCs. Comparing the epigenetic changes between fresh TSPAN33+ cells and cultured TSPAN33+ cells (resembling progenitors), we identified the regulatory elements with higher activity in SSCs, and the potential transcription factors and signaling pathways implicated in SSC regulation. Specifically, TGF-β signaling is activated in monkey putative SSCs. We provided evidence supporting its role in promoting self-renewal of monkey SSCs in culture. Overall, this study outlines the epigenetic landscapes of monkey SSCs and provides clues for optimization of the culture condition for primate SSCs expansion.

Single-cell transcriptomic and cross-species comparison analyses reveal distinct molecular changes of porcine testes during puberty

The pig is an important model for studying human diseases and is also a significant livestock species, yet its testicular development remains underexplored. Here, we employ single-cell RNA sequencing to characterize the transcriptomic landscapes across multiple developmental stages of Bama pig testes from fetal stage through infancy, puberty to adulthood, and made comparisons with those of humans and mice. We reveal an exceptionally early onset of porcine meiosis shortly after birth, and identify a distinct subtype of porcine spermatogonia resembling transcriptome state 0 spermatogonial stem cells identified in humans, which were previously thought to be primate specific. We also discover the persistent presence of proliferating progenitors for myoid cells in postnatal testes. The regulatory roles of Leydig cell steroidogenesis and estrogen synthesis in supporting cell lineages are also explored, including the potential impact of estrogen on Sertoli cell maturation and spermatogenesis. Overall, this study offers valuable insights into porcine testicular development, paving the way for future research in reproductive biology, advancements in agricultural breeding, and potential applications in translational medicine.

In Vitro Spermatogenesis on Human Decellularized Testicular Matrix Plates Following Exosome Treatment in a Dynamic Culture System.

Testicular tissue engineering for in vitro spermatogenesis aims to restore fertility, focusing on challenges like efficiency, ethical concerns, and the need for a deeper biological understanding. The use of decellularized scaffolds led to better cell seeding and differentiation, and exosomes led to enhanced spermatogenesis. Also, the dynamic culture systems are being explored to replicate in vivo conditions more accurately. In this study, we aimed to utilize a perfusion mini-bioreactor for the dynamic culture of mouse spermatogonial stem cells on decellularized testicular matrix plates supplemented with exosomes. Our goal was to assess the progression of the spermatogenesis process through histological, immunohistochemical, and molecular analyses over four weeks. Human testicular tissues were decellularized using 1% sodium dodecyl sulfate and were then fabricated into thin plates using a cryostat. Sertoli and spermatogonial stem cells were isolated from neonate mouse testis and seeded onto the decellularized testicular matrix plates. A mini-perfusion bioreactor was employed to create dynamic culture conditions. Also, MSCs-derived exosomes were introduced to the culture medium, alone or in combination with a spermatogenic medium containing numerous chemical factors. The histological, IHC, and molecular analyses were performed at the end of the experiment. Our decellularization procedure successfully preserved the ECM components, while eliminating native cells. The isolated cells expressed PLZF and VIMENTIN markers, confirming the presence of SSCs and Sertoli cells. The seeded scaffolds exhibited proper homing, viability, proliferation, and differentiation of the cells towards in vitro spermatogenesis. Also, exosome treatment is capable of enhancing the spermatogenic potential of SSCs. Our findings indicate that the dynamic culture system significantly promoted the proliferation and differentiation of SSCs into mature spermatozoa. The use of exosomes further enhanced these effects, as evidenced by improved cellular viability, reduced apoptosis, and advanced spermatogenesis to the elongated spermatid stage. The combined treatment of exosomes and spermatogenic medium showed a synergistic effect, yielding superior outcomes in terms of sperm cell maturity and functionality. This study underscores the potential of combining decellularized testicular matrices with exosome therapy in a dynamic culture set up to advance the field of reproductive biology and fertility restoration.

Integrating Microarray Data and Single-Cell RNA-Seq Reveals Key Gene Involved in Spermatogonia Stem Cell Aging.

The in vitro generation of spermatogonial stem cells (SSCs) from embryonic stem cells (ESCs) offers a viable approach for addressing male infertility. A multitude of molecules participate in this intricate process, which requires additional elucidation. Despite the decline in SSCs in aged testes, SSCs are deemed immortal since they can multiply for three years with repeated transplantation. Nonetheless, the examination of aging is challenging due to the limited quantity and absence of precise indicators. Using a microarray, we assessed genome-wide transcripts (about 55,000 transcripts) of fibroblasts and SSCs. The WGCNA approach was then used to look for SSC-specific transcription factors (TFs) and hub SSC-specific genes based on ATAC-seq, DNase-seq, RNA-seq, and microarray data from the GEO databases as well as gene expression data (RNA-seq and microarray data). The microarray analysis of three human cases with different SSCs revealed that 6 genes were upregulated, and the expression of 23 genes was downregulated compared to the normal case in relation to aging genes. To reach these results, online assessments of Enrich Shiny GO, STRING, and Cytoscape were used to forecast the molecular and functional connections of proteins before identifying the master routes. The biological process and molecular function keywords of cell-matrix adhesion, telomerase activity, and telomere cap complex were shown to be significantly altered in upregulated differentially expressed genes (DEGs) by the functional enrichment analysis. According to our preliminary research, cell-specific TFs and TF-mediated GRNs are involved in the creation of SSCs. In order to maximize the induction efficiency of ESC differentiation into SSCs in vitro, hub SSC-specific genes and important SSC-specific TFs were identified, and sophisticated network regulation was proposed. According to our research, these genes and the hub proteins that they interact with may be able to shine a light on the pathophysiologies of infertility and aberrant germ cells.

Germ cell progression through zebrafish spermatogenesis declines with age.

Vertebrate spermatogonial stem cells maintain sperm production over the lifetime of an animal but fertility declines with age. While morphological studies have informed our understanding of typical spermatogenesis, the molecular and cellular mechanisms underlying the maintenance and decline of spermatogenesis are not yet understood. We used single-cell RNA sequencing to generate a developmental atlas of the aging zebrafish testis. All testes contained spermatogonia, but we observed a progressive decline in spermatogenesis that correlates with age. Testes from some older males only contained spermatogonia and a reduced population of spermatocytes. Spermatogonia in older males are transcriptionally distinct from spermatogonia in testes capable of robust spermatogenesis. Immune cells including macrophages and lymphocytes drastically increase in abundance in testes that cannot complete spermatogenesis. Our developmental atlas reveals the cellular changes as the testis ages and defines a molecular roadmap for the regulation of spermatogenesis.

Correction to: Melatonin attenuates detrimental effects of diabetes on the niche of mouse spermatogonial stem cells by maintaining Leydig cells

Correction to: Melatonin attenuates detrimental effects of diabetes on the niche of mouse spermatogonial stem cells by maintaining Leydig cells

Cryopreservation of human spermatozoa or testicular tissue for fertility preservation

Loss of reproductive capacity due to treatments for malignant or non-malignant diseases or even as aresult of diseases themselves significantly impacts patients' quality of life. Cryopreservation of sperm from ejaculate is awell-established procedure for preserving the fertility of these patients and thus improving their quality of life in the long term. If cryopreservation of sperm from ejaculate is not possible, either because ejaculation cannot occur or no sperm can be found in the ejaculate, the preferred treatment option is (microsurgical) testicular sperm extraction (mTESE). Testicular sperm and ejaculated spermatozoa can be cryopreserved and later used for intracytoplasmic sperm injection (ICSI) treatment. The use of cryopreserved sperm for fertility treatment does not carry an increased risk of malformations in the offspring. If gonadotoxic therapy is necessary in pre- or early pubertal boys, the only option to preserve fertility in the long term is to cryopreserve spermatogonial stem cells from testicular tissue as part of the Androprotect© network. This is an experimental approach which has been available since 2012 acrossGermany and which is accompanied by intensive scientific work ( www.androprotect.de ).

A Study of JUN’s Promoter Region and Its Regulators in Chickens

Background: The Jun proto-oncogene (JUN), also referred to as C-JUN, is an integral component of the JNK signaling pathway, which is crucial for the formation and differentiation of spermatogonial stem cells (SSCs). Investigations into the transcriptional regulation of chicken JUN can offer a molecular foundation for elucidating its mechanistic role in SSCs. Methods: In this study, we successfully cloned a 2000 bp upstream sequence of the JUN transcription start site and constructed a series of pGL3 recombinant vectors containing JUN promoters of varying lengths. Results: We verified the promoter activity of the 2000 bp upstream sequence by assessing the fluorescence intensity of DF-1 and identified the promoter activities of different regions via dual-luciferase assays. The transcription of JUN and its promoter region spanning −700 to 0 bp was modulated by an activator of the JNK signaling pathway. Bioinformatics analysis revealed that this −700 to 0 bp region was highly conserved among avian species and predicted the presence of binding sites for Wilms tumor 1 (WT1) and CCAAT/enhancer binding protein alpha (CEBPA). The JNK signaling pathway activator was found to upregulate the expression of these transcription factors in DF-1 cells. Through the deletion of binding sites and the overexpression of WT1 and CEBPA, we demonstrated that WT1 inhibited the transcription of JUN, while CEBPA promoted it. Conclusions: In conclusion, the −700 to 0 bp region is the key region of the JUN promoter, with WT1 inhibiting JUN transcription. The results of the study not only provide ideas for exploring the regulatory mechanism of JUN in chicken SSCs, but also lay an important foundation for the study of avian SSCs.

Identification and Manipulation of Spermatogonial Stem Cells with the Aim of Inducing Spermatogenesis in Vitro.

Assisted reproduction techniques for infertile men with non-obstructive azoospermia require a sufficient number of functional germ cells produced in vitro. Understanding the mechanisms that allow the resumption of spermatogenesis outside the testicular environment is crucial for fertility preservation in these patients. A review of the literature was conducted using databases such as PubMed, Scopus and Web of Science, with keywords including "spermatogonial stem cell," "germ cells," "male factor infertility," and "enrichment and propagation of SSCs in vitro." Currently, two models-"in vivo" and "in vitro"-have been developed for producing haploid germ cells. The "in vivo" models include spermatogonial stem cell transplantation and testicular xenograft techniques. In contrast, the "in vitro" models consist of conventional culture systems, organ culture, and three-dimensional culture systems, all designed to induce spermatogenesis in vitro. These culture systems enable the simulation of the seminiferous epithelium in vitro, which facilitates better regulation of cell-signaling pathways that control the self-renewal and differentiation of SSCs. This review provides up-to-date information on the organization of SSCs, focusing on the identification, proliferation, and differentiation of spermatogonia in vitro.

Androgen blockage impairs proliferation and function of Sertoli cells via Wee1 and Lfng

BackgroundAndrogens are essential hormones for testicular development and the maintenance of male fertility. Environmental factors, stress, aging, and psychological conditions can disrupt androgen production, impacting the androgen signaling pathway and consequently spermatogenesis. Within the testes, testosterone is produced by Leydig cells and acts on Sertoli cells by activating the androgen receptor (AR), which then translocates to the nucleus to function as a transcription factor. Despite clinical correlations between low testosterone levels and diminished sperm quality, the precise mechanism remains unclear.MethodsThis study explores the hypothesis that reduced androgen levels impair Sertoli cell function by disrupting AR transcriptional regulation. Using an androgen blockade model with enzalutamide, we investigated the impact of low androgen levels on AR target genes in Sertoli cells through ChIP-seq and RNA-seq assays.ResultsOur results reveal that androgen blockage increases AR enrichment on the promoter region of Wee1, promoting Wee1 expression, while decreasing binding to the promoter region of Lfng, inhibiting its expression. Increased WEE1 protein inhibits Sertoli cell proliferation, whereas reduced LFNG affects Notch modification, leading to decreased production of glial cell line-derived neurotrophic factor (GDNF), a key growth factor for spermatogonial stem cell self-renewal.ConclusionsThese findings provide new insights into the molecular mechanisms by which low androgen levels interfere with Sertoli cell functions, offering novel perspectives for the clinical treatment of male reproductive disorders.

A novel investigation of NANOG and POU5F1 associations in the pluripotent characterization of ES-like and epiblast cells

The transcription factors NANOG and POU5F1 (OCT4) play crucial roles in maintaining pluripotency in embryonic stem (ES) cells. While their functions have been well-studied, the specific interactions between NANOG and POU5F1 and their combined effects on pluripotency in ES-like and Epiblast cells remain less understood. Understanding these associations is vital for refining pluripotent stem cell characterization and advancing regenerative medicine. In this matter, we investigated the associations between NANOG and POU5F1 in maintaining pluripotency in ES-like and Epiblast cells and how these interactions contribute to the distinct pluripotent states of these cells. In the present paper, we examined the pattern of NANOG expression by the immunocytochemical method in embryonic stem-like (ES-like) cells and compared it with its expression pattern in embryonic stem cells (ESCs). Similarly, we examined the expression pattern of POU5F1 in ES-like cells, ESCs, and epiblast cells and compared the expression pattern of these two genes with each other. On the other hand, using Fluidigm Biomark system analysis, we compared the amount of NANOG mRNA in these three cell lines and differentiated and undifferentiated Spermatogonial stem cells in several passages. Microscopic observations indicated the cytoplasmic expression of NANOG in the considered cells; moreover, they showed a similar expression pattern of NANOG with POU5F1 in the experimented cells. It has also been suggested that the more limited the cell’s pluripotency, the lower the expression of these two genes. However, the decrease in NANOG expression is less than that of POU5F1. Fluidigm real-time RT-PCR analysis also confirmed these results. During the experimental process, protein-protein (PPI) network analysis shows a significant association of NANOG with other stem cell proteins, such as POU5F1. Our findings reveal distinct yet overlapping roles of NANOG and POU5F1 in maintaining pluripotency in ES-like and Epiblast cells. The differential binding patterns and functional interactions between these factors underscore the complexity of pluripotency regulation in different stem cell states. This study provides new insights into the molecular mechanisms governing pluripotency and highlights potential targets for enhancing stem cell-based therapies.

The role of p53 in male infertility.

The tumor suppressor p53 is a transcription factor involved in a variety of crucial cellular functions, including cell cycle arrest, DNA repair and apoptosis. Still, a growing number of studies indicate that p53 plays multiple roles in spermatogenesis, as well as in the occurrence and development of male infertility. The representative functions of p53 in spermatogenesis include the proliferation of spermatogonial stem cells (SSCs), spermatogonial differentiation, spontaneous apoptosis, and DNA damage repair. p53 is involved in various male infertility-related diseases. Innovative therapeutic strategies targeting p53 have emerged in recent years. This review focuses on the role of p53 in spermatogenesis and male infertility and analyses the possible underlying mechanism involved. All these conclusions may provide a new perspective on drug intervention targeting p53 for male infertility treatment.

A translation regulator that drives spermatogonial stem cell formation.

Spermatogonial stem cells (SSCs) are essential for adult spermatogenesis. Themolecular mechanisms driving SSC generation are poorly understood. Zou et al. reported that the precursor cells that give rise to SSCs-prospermatogonia (ProSG) require the RNA-binding protein, DDX20, in orderto undergo the obligatory proliferative re-activation step that proceeds SSC formation. Literature search. We summarize the authors' discovery that the RNA-binding protein, DDX20, iscritical for driving the proliferative re-activation of ProSG, a key step that proceeds SSC generation in vivo. They provide evidence that DDX20 performs this role through its ability to promote the translation of mRNAs encoding proteins known to be essential for cell-cycle and spermatogonial homeostasis. It remains to be determined whether this role is conserved inhumans. It will also be interesting to elucidate whether other post-transcriptional regulators also have roles in early germ cell development. More broadly, it will be fascinating to determine whether post-transcriptional regulators workin concert with transcriptional regulators to drive germ-cell development.

Evaluation of Female Recipient Infertility and Donor Spermatogonial Purification for Germ Cell Transplantation in Paralichthys olivaceus.

Since the advent of germ cell transplantation (GCT), it has been widely used in shortening the fish breeding cycle, sex-controlled breeding and the protection of rare and endangered fish. In this study, the effectiveness of female sterile recipient preparation and donor stem cell isolation and purification were comprehensively evaluated for spermatogonial stem cell transplantation (SSCT) in Paralichthys olivaceus. The best way to prepare sterile recipients was found to be giving three-year-old fish four intraovarian injections of busulfan (20 mg/kg body weight) combined with exposure to a high temperature (28 °C) after the spawning season compared with the two other ways, which induced apoptosis of most of the endogenous germ cells, resulting in shrinkage of the spawning plate and enlargement of the ovarian lumen. Further analysis showed that both the gonadosomatic index and germ-cell-specific vasa expression were significantly lower than those of the natural-temperature group before treatment (p < 0.05). A high percentage (>60.00%) of spermatogonial stem cells (SSCs) were obtained after isolation and purification and were transplanted into the prepared recipients. After three weeks of SSCT, the numbers of PKH26-labeled SSCs were increased in the ovaries of the recipients. These findings provide a basis for the establishment of an ideal SSCT technique using P. olivaceus females as the recipients, ultimately contributing to the efficient conservation of male germplasm resources and effective breeding.

Ultrastructural Characterization of Testis in Non-descript Goat (Capra hircus)

Background: The proposed experiment was aimed at locating the spermatogonial stem cell niches inside the testis and to characterise the development of germ cells of testis in the non- descript goats at the different stages of pre and post natal life, which could be useful in selecting the goats for breeding at appropriate time and for other interventions related to reproductive developments in the goats. Methods: The present study was conducted on the testes of non-descript goats divided into three groups, viz. neonatal (within 1 month), prepubertal (from 1-18 months) and pubertal (above 18 months) with 10 healthy animals in each group. The collected samples of testis were processed for scanning electron microscopic study and subsequently, the samples were viewed and the photographs were taken in the facility available at Central Instrumentation Facility (CIF), OUAT, Bhubaneswar. Result: The present study revealed that the testis was surrounded by the tunica albuginea, a thin capsule of connective tissue, from which thin septum originated and extended into the inside of the organ. Among these septa, the seminiferous tubules were found. The seminiferous epithelium consisted of spermatogonial cells at different stages of development separated from each other by interstitial connective tissue. The interstitium was made up of randomly arranged collagen bundles. The intertubular vascular connective tissue contained Leydig cells mainly at wider locations where they were bounded by more than two seminiferous tubules. The mediastinal rete testis area contained many cavities of many intercommunicating channels supported by connective tissue pillars. The present study helped in developing a baseline data on the ultrastructural characteristics of seminiferous epithelium, rete restis, peritubular cells, Lyedig cells and other components of testis in non-descript goat at different post natal stages under study. The appearance of seprmatogonial cell lineage at the various post natal stages in non-descript goat would help in accessing the reproductive status of the animal.

6432 Enriching Testicular Organoid Aggregates to Promote Germ Cell Homing

Abstract Disclosure: A. Patel: None. O.O. Printy: None. C. Joswiak: None. M.M. Laronda: None. The long-term effects of life-saving chemotherapy treatments, such as an increased risk of infertility, are of concern to the growing number of childhood cancer survivors. De novo testicular morphogenesis seeks to generate testicular organoids that are structurally and functionally similar to the native testis. These organoids serve as a tool for investigating patient-specific models for restoring spermatogenesis for prepubertal cancer patients. Our lab has previously developed testicular organoids containing tubule-like structures (TLS) resembling the native seminiferous tubules as assessed by immunohistochemistry of testicular cell-type markers for Leydig cells (HSD3B2), peritubular myoid cells (ACTA1), Sertoli cells (SOX9), germ cells (DDX4), and spermatogonial stem cells (SSCs) (SALL4). Internal architecture demonstrated semi-continuous ring-like structures composed of ACTA1-positive cells encapsulating a population of SOX9-positive cells with HSD3B2-positive cells clustering near the periphery of the organoids. However, organoids lacked native germ cell populations. We hypothesized that murine testicular organoids would merge to form elongated TLS, within which exogenous SSCs would home to existing Sertoli cell niches, when cultured within structures designed from the appropriate dimensions and materials. Organoids were generated from testicular tissue isolated from 5 days-post-partum (dpp) CD1 mice using cell-seeding densities and microenvironmental conditions previously established by our lab. To promote aggregate formation, 48-hour-old organoids were transferred to trough-shaped structures formed from 2% agarose using 3D printed silicone molds. Separately, SSCs were isolated from 5 dpp tdTomato+ mice via magnetic-activated cell sorting of THY1+ cells. Organoids and aggregates were enriched with SSCs by three methods: (1) enrichment of cell suspension during organoid formation, (2) enrichment of culture during aggregate formation, and (3) injection of SSCs into aggregate using 20 µm glass pipette. Organoids transferred to agarose troughs on day 2 of culture merged to form aggregates by day 5 and continued to display dynamic architecture, shortening in length and increasing in width over time. Aggregates were more elongated in shape when cultured in narrow troughs less than 700µm in width. Observations thus far indicate that attempts to inject aggregates resulted in penetrance and inclusion of the SSC suspension; additionally, tdTomato+ cells were visualized within injected aggregates on day 17 of culture. Research is ongoing to define where exogenous SSCs take up residence, how long they survive, and if they proliferate over time within the testicular aggregates. This research expands upon foundational work establishing testicular organoids as an approach to in vitro spermatogenesis with clinical applications in fertility restoration. Presentation: 6/2/2024

6432 Enriching Testicular Organoid Aggregates to Promote Germ Cell Homing

Abstract Disclosure: A. Patel: None. O.O. Printy: None. C. Joswiak: None. M.M. Laronda: None. The long-term effects of life-saving chemotherapy treatments, such as an increased risk of infertility, are of concern to the growing number of childhood cancer survivors. De novo testicular morphogenesis seeks to generate testicular organoids that are structurally and functionally similar to the native testis. These organoids serve as a tool for investigating patient-specific models for restoring spermatogenesis for prepubertal cancer patients. Our lab has previously developed testicular organoids containing tubule-like structures (TLS) resembling the native seminiferous tubules as assessed by immunohistochemistry of testicular cell-type markers for Leydig cells (HSD3B2), peritubular myoid cells (ACTA1), Sertoli cells (SOX9), germ cells (DDX4), and spermatogonial stem cells (SSCs) (SALL4). Internal architecture demonstrated semi-continuous ring-like structures composed of ACTA1-positive cells encapsulating a population of SOX9-positive cells with HSD3B2-positive cells clustering near the periphery of the organoids. However, organoids lacked native germ cell populations. We hypothesized that murine testicular organoids would merge to form elongated TLS, within which exogenous SSCs would home to existing Sertoli cell niches, when cultured within structures designed from the appropriate dimensions and materials. Organoids were generated from testicular tissue isolated from 5 days-post-partum (dpp) CD1 mice using cell-seeding densities and microenvironmental conditions previously established by our lab. To promote aggregate formation, 48-hour-old organoids were transferred to trough-shaped structures formed from 2% agarose using 3D printed silicone molds. Separately, SSCs were isolated from 5 dpp tdTomato+ mice via magnetic-activated cell sorting of THY1+ cells. Organoids and aggregates were enriched with SSCs by three methods: (1) enrichment of cell suspension during organoid formation, (2) enrichment of culture during aggregate formation, and (3) injection of SSCs into aggregate using 20 µm glass pipette. Organoids transferred to agarose troughs on day 2 of culture merged to form aggregates by day 5 and continued to display dynamic architecture, shortening in length and increasing in width over time. Aggregates were more elongated in shape when cultured in narrow troughs less than 700µm in width. Observations thus far indicate that attempts to inject aggregates resulted in penetrance and inclusion of the SSC suspension; additionally, tdTomato+ cells were visualized within injected aggregates on day 17 of culture. Research is ongoing to define where exogenous SSCs take up residence, how long they survive, and if they proliferate over time within the testicular aggregates. This research expands upon foundational work establishing testicular organoids as an approach to in vitro spermatogenesis with clinical applications in fertility restoration. Presentation: 6/2/2024

Establishment and Characterization of Testis Organoids with Proliferation and Differentiation of Spermatogonial Stem Cells into Spermatocytes and Spermatids.

Organoids play pivotal roles in uncovering the molecular mechanisms underlying organogenesis, intercellular communication, and high-throughput drug screening. Testicular organoids are essential for exploring the genetic and epigenetic regulation of spermatogenesis in vivo and the treatment of male infertility. However, the formation of testicular organoids with full spermatogenesis has not yet been achieved. In this study, neonatal mouse testicular cells were isolated by two-step enzymatic digestion, and they were combined with Matrigel and transplanted subcutaneously into nude mice. Histological examination (H&E) staining and immunohistochemistry revealed that cell grafts assembled to form seminiferous tubules that contained spermatogonial stem cells (SSCs) and Sertoli cells, as illustrated by the co-expression of PLZF (a hallmark for SSCs) and SOX9 (a marker for Sertoli cells) as well as the co-expression of UCHL1 (a hallmark for SSCs) and SOX9, after 8 weeks of transplantation. At 10 weeks of transplantation, SSCs could proliferate and differentiate into spermatocytes as evidenced by the expression of PCNA, Ki67, c-Kit, SYCP3, γ-HA2X, and MLH1. Notably, testicular organoids were seen, and spermatids were observed within the lumen of testicular organoids after 16 weeks of transplantation, as shown by the presence of TNP1 and ACROSIN (hallmarks for spermatids). Collectively, these results implicate that we successfully established testicular organoids with spermatogenesis in vivo. This study thus provides an excellent platform for unveiling the mechanisms underlying mammalian spermatogenesis, and it might offer valuable male gametes for treating male infertility.

Low Testosterone Concentration Improves Colonisation and Viability in the Co-Cultured Goat Spermatogonial Stem Cell With Sertoli Cells.

Spermatogonial stem cells (SSCs) maintain spermatogenesis through self-renewal and differentiation. The proliferation of SSCs in culture systems can provide a valuable source of germ cells. Several studies have investigated new reproductive technologies, including the production of transgenic animals and recombinant proteins secreted from milk in goats. While studies in other species exist, research on goat SSC culture remains limited. We investigated the impact of different testosterone concentrations on the survival and colonisation of cocultured goat SSCs with Sertoli cells. Cells were isolated from immature goats using two-step enzymatic digestion and enriched by differential exclusion method. DMEM/F12 culture medium containing 1% antibiotic and 5% FBS, supplemented with GDNF (20 ng/mL), EGF, bFGF and LIF (10 ng/mL), was used with different testosterone concentrations (0, 60, 120 and 240 μg/mL) and cultured for 10 days. SC subpopulations were confirmed using PGP9.5 immunocytochemistry, and the expression of germ cell markers (ID-4, UCHL-1, THY-1, β1-integrin, BCL6B, VASA, PLZF and OCT-4) was evaluated through RT-PCR. Alkaline phosphatase activity provided additional SSC presence. The survival rate of SSCs after isolation and the number and area of colonies on Days 4, 7 and 10 were measured using an inverted microscope. The presence of PGP 9.5 antigens and germ cell markers (ID-4, UCHL-1, THY-1, β1-integrin, BCL6B, VASA, PLZF and OCT-4) was confirmed by immunocytochemistry and RT-PCR, respectively. According to the results, the group with 60 μg/mL testosterone had the highest number and area of colonies. The number of colonies in the 60 μg/mL testosterone group was significantly higher than the control group (p < 0.05), but no significant difference was observed compared to other groups (p ≥ 0.05). This study suggests that a low testosterone concentration (60 μg/mL) is optimal for goat SSC colonisation and viability in coculture with Sertoli cells, potentially leading to advancements in goat reproductive technologies.

Accelerated mitochondrial dynamics promote spermatogonial differentiation

At different stages of spermatogenesis, germ cell mitochondria differ remarkably in morphology, architecture, and functions. However, it remains elusive how mitochondria change their features during spermatogonial differentiation, which in turn impacts spermatogonial stem cell fate decision. In this study, we observed that mitochondrial fusion and fission were both upregulated during spermatogonial differentiation. As a result, the mitochondrial morphology remained unaltered. Enhanced mitochondrial fusion and fission promoted spermatogonial differentiation, while the deficiency in DRP1-mediated fission led to a stage-specific blockage of spermatogenesis at differentiating spermatogonia. Our data further revealed that increased expression of pro-fusion factor MFN1 upregulated mitochondrial metabolism, whereas DRP1 specifically regulated mitochondrial permeability transition pore opening in differentiating spermatogonia. Taken together, our findings unveil how proper spermatogonial differentiation is precisely controlled by concurrently accelerated and properly balanced mitochondrial fusion and fission in a germ cell stage-specific manner, thereby providing critical insights about mitochondrial contribution to stem cell fate decision.