Role of Src family kinases and N-Myc in spermatogonial stem cell proliferation

Spermatogonial stem cells are required for the initiation of spermatogenesis and the continuous production of sperm. In addition, they can acquire pluripotency and differentiate into derivatives of the three embryonic germ layers when cultured in the appropriate conditions. Therefore, understanding the signaling pathways that lead to self-renewal or differentiation of these cells is of paramount importance for the treatment of infertility, the development of male contraceptives, the treatment of testicular cancers, and ultimately for tissue regeneration. In this report, we studied some of the signaling pathways triggered by glial cell line-derived neurotrophic factor (GDNF), a component of the spermatogonial stem cell niche produced by the somatic Sertoli cells. As model systems, we used primary cultures of mouse spermatogonial stem cells, a mouse spermatogonial stem cell line and freshly isolated testicular tubules. We report here that GDNF promotes spermatogonial stem cell proliferation through activation of members of the Src kinase family, and that these kinases exert their action through a PI3K/Akt-dependent pathway to up-regulate N-myc expression. Thus, to proliferate, spermatogonial stem cells activate mechanisms that are similar to the processes observed in brain stem cells and lung progenitors.     

Efficiency of adult mouse spermatogonial stem cell colony formation under several culture conditions

The aim of this study was to compare the in vitro effects of glial cell line-derived neurotrophic factor, stem cell factor, granulocyte macrophage-colony stimulating factor, and co-culture with Sertoli cells on the efficiency of adult mouse spermatogonial stem cells colony formation. For these purpose, both Sertoli and spermatogonial cells were isolated from adult mouse testes. The identity of the cells was confirmed through analysis of alkaline phosphatase activity, immunocytochemistry against OCT-4, c-kit, and vimentin, and also by transplantation of these cells in the recipient testes. The isolated spermatogonial cells were treated either with various concentrations of the above mentioned factors or co-cultured with Sertoli cells for 3 wk. The spermatogonial cells of the resulting colonies were transplanted via rete testis into the mouse testes, which were irradiated with 14 Gy. The results indicated that glial cell line-derived neurotrophic factor is the most appropriate factor for in vitro colonization of adult mice spermatogonial cells compared with other cytokines and growth factors. A short-term co-culture with Sertoli cells showed a significant increase in the number and diameter of the colonies compared with the treated growth factors and the control group. We have also demonstrated that mouse spermatogonial stem cells in the colonies after co-culturing with Sertoli cells could induce spermatogenesis in the recipient testes after transplantation.     

Restoration of spermatogenesis in infertile mice by Sertoli cell transplantation

The niche is considered to play an important role in stem cell biology. Sertoli cells are the only somatic cells in the seminiferous tubule that closely interact with germ cells to create a favorable environment for spermatogenesis. However, little is known about how Sertoli cells develop to form the male germ line niche. We report here that Sertoli cells recovered and dissociated from testes of donor male mice can be microinjected into recipient testes, form mature seminiferous tubule structures, and support spermatogenesis. Sertoli cells from perinatal donors had a dramatically greater capacity for generating seminiferous tubules than those from adult donors. Furthermore, transplantation of wild-type Sertoli cells into infertile Steel/Steel(dickie) testes created a permissive testicular microenvironment for generating spermatogenesis and spermatozoa. Thus, our results demonstrate that the male germ line stem cell niche can be transferred between animals. In addition, the technique provides a novel tool with which to analyze spermatogenesis and might provide a mechanism for correcting fertility in males suffering from supporting cell defects.     

精原干细胞与睾丸生殖衰老的研究进展

雄性睾丸内精子的生成及其质量随年龄增长逐渐降低。精原干细胞是精子生成的起点,其数量和质量决定了精子的生成,而精原干细胞niche是调节精原干细胞自我更新与分化的重要因素。在衰老过程中,干细胞微环境退化,精原干细胞自我更新和分化失衡,被认为是衰老导致睾丸生殖功能衰退的的主要因素。本文将综述衰老引起的精原干细胞与niche变化及其对生殖的影响相关研究进展。     

Sertoli cells dictate spermatogonial stem cell niches in the mouse testis

Sustained spermatogenesis in adult males relies on the activity of spermatogonial stem cells (SSCs). In general, tissue-specific stem cell populations such as SSCs are influenced by contributions of support cells that form niche microenvironments. Previous studies have provided indirect evidence that several somatic cell populations and the interstitial vasculature influence SSC functions, but an individual orchestrator of niches has not been described. In this study, functional transplantation of SSCs, in combination with experimental alteration of Sertoli cell content by polythiouracil (PTU)-induced transient hypothyroidism, was used to explore the relationship of Sertoli cells with SSCs in testes of adult mice. Transplantation of SSCs from PTU-treated donor mice into seminiferous tubules of normal recipient mice revealed a greater than 3-fold increase in SSCs compared to those from testes of non-PTU-treated donors. In addition, use of PTU-treated mice as recipients for transplantation of SSCs from normal donors revealed a greater than 3-fold increase of accessible niches compared to those of testes of non-PTU treated recipient mice with normal numbers of Sertoli cells. Importantly, the area of seminiferous tubules bordered by interstitial tissue and percentage of seminiferous tubules associated with blood vessels was found to be no different in testes of PTU-treated mice compared to controls, indicating that neither the vasculature nor interstitial support cell populations influenced the alteration of niche number. Collectively, these results provide direct evidence that Sertoli cells are the key somatic cell population dictating the number of SSCs and niches in mammalian testes.     

Characterization of spermatogonial stem cell maturation and differentiation in neonatal mice

Initiation of the first wave of spermatogenesis in the neonatal mouse testis is characterized by the differentiation of a transient population of germ cells called gonocytes found in the center of the seminiferous tubule. The fate of gonocytes depends upon these cells resuming mitosis and developing the capacity to migrate from the center of the seminiferous tubule to the basement membrane. This process begins approximately Day 3 postpartum in the mouse, and by Day 6 postpartum differentiated type A spermatogonia first appear. It is essential for continual spermatogenesis in adults that some gonocytes differentiate into spermatogonial stem cells, which give rise to all differentiating germ cells in the testis, during this neonatal period. The presence of spermatogonial stem cells in a population of cells can be assessed with the use of the spermatogonial stem cell transplantation technique. Using this assay, we found that germ cells from the testis of Day 0-3 mouse pups can colonize recipient testes but do not proliferate and establish donor-derived spermatogenesis. However, germ cells from testes of Day 4-5 postpartum mice colonize recipient testes and generate large areas of donor-derived spermatogenesis. Likewise, germ cells from Day 10, 12, and 28 postpartum animals and adult animals colonize and establish donor-derived spermatogenesis, but a dramatic reduction in the number of colonies and the extent of colonization occurs from germ cell donors Days 12-28 postpartum that continues in adult donors. These results suggest spermatogonial stem cells are not present or not capable of initiating donor-derived spermatogenesis until Days 3-4 postpartum. The analysis of germ cell development during this time frame of development and spermatogonial stem cell transplantation provides a unique system to investigate the establishment of the stem cell niche within the mouse testis.     

Akt mediates self-renewal division of mouse spermatogonial stem cells

Spermatogonial stem cells have unique properties to self-renew and support spermatogenesis throughout their lifespan. Although glial cell line-derived neurotrophic factor (GDNF) has recently been identified as a self-renewal factor for spermatogonial stem cells, the molecular mechanism of spermatogonial stem cell self-renewal remains unclear. In the present study, we assessed the role of the phosphoinositide-3 kinase (PI3K)-Akt pathway using a germline stem (GS) cell culture system that allows in vitro expansion of spermatogonial stem cells. Akt was rapidly phosphorylated when GDNF was added to the GS cell culture, and the addition of a chemical inhibitor of PI3K prevented GS cell self-renewal. Furthermore, conditional activation of the myristoylated form of Akt-Mer (myr-Akt-Mer) by 4-hydroxy-tamoxifen induced logarithmic proliferation of GS cells in the absence of GDNF for at least 5 months. The myr-Akt-Mer GS cells expressed spermatogonial markers and retained androgenetic imprinting patterns. In addition, they supported spermatogenesis and generated offspring following spermatogonial transplantation into the testes of infertile recipient mice, indicating that they are functionally normal. These results demonstrate that activation of the PI3K-Akt pathway plays a central role in the self-renewal division of spermatogonial stem cells.     

Anchorage-independent growth of mouse male germline stem cells in vitro

Spermatogenesis originates from a small number of spermatogonial stem cells that reside on the basement membrane and undergo self-renewal division to support spermatogenesis throughout the life of adult animals. Although the recent development of a technique to culture spermatogonial stem cells allowed reproduction of self-renewal division in vitro, much remains unknown about how spermatogonial stem cells are regulated. In this study, we found that spermatogonial stem cells could be cultured in an anchorage-independent manner, which is characteristic of stem cells from other types of self-renewing tissues. Although the cultured cells grew slowly (doubling time, approximately 4.7 days), they expressed markers of spermatogonia, and grew exponentially for at least 5 months to achieve 1.5 x 10(10) -fold expansion. The cultured cells underwent spermatogenesis following transplantation into the seminiferous tubules of infertile animals and fertile offspring were obtained by microinsemination of germ cells that had developed within the testes of recipients of the cultured cells. These results indicate that spermatogonial stem cells can undergo anchorage-independent, self-renewal division, and suggest that stem cells have the common property to survive and proliferate in the absence of exogenous substrata.     

精原干细胞自我更新和分化的调控

精原干细胞（spermatogonial stem cells,SSCs）是体内自然状态下惟一能将遗传信息传至子代的成体干细胞,它们能通过维持自我更新和分化的稳定从而保证雄性生命过程中精子发生的持续进行。了解SSCs自我更新和分化的调节机制有助于阐明精子发生机理,并为探究其他组织中成体干细胞增殖分化的调节机制提供依据。然而目前对于SSCs自我更新和分化的调控机制所知甚少。SSCs的更新与分化遵循特定模式,受以睾丸支持细胞为主要成分的微环境及各种内分泌因素如胶质细胞源神经营养因子（GDNF）、维生素、Ets转录因子ERM/Etv5等的调控。本文评述了SSCs更新与分化的模式以及上述因素对其更新、分化的调控,探讨了其中可能涉及的信号通路,以期为本领域及其他成体干细胞相关研究提供借鉴。     

探索Sertoli细胞对去除精原细胞的动态反应

目的探索Sertoli细胞对去除小鼠精原细胞后睾丸的动态反应。方法采用15、30和44 mg/kg的白消安腹腔注射法建立不同程度去除精原细胞的动物模型,处理后5 d和28 d时对睾丸进行组织学检测,评价精子发生状态,并运用实时定量荧光PCR技术检测这两个时期睾丸GDNF、PLZF、Nanog和GFRα1基因mRNA的表达量。结果在白消安处理后第5天,GDNF出现显著升高,且呈剂量依赖趋势,而PLZF与GFRɑ1并无显著变化,睾丸组织学观察亦无明显变化。在白消安处理后28 d时,GDNF、PLZF、Nanog、GFRɑ1基因mRNA相对表达量均出现大幅度的升高,睾丸组织学切片观察显示随着给药剂量的增加,精子发生受到的损伤愈加严重。结论 Sertoli细胞早在白消安处理后第5天就对精原细胞的变化发生了反应,Sertoli细胞分泌GDNF的能力发生代偿性增加,进而刺激精原干细胞自我更新速度加快,体现在Nanog和PLZF水平提高,从而实现精子发生的重建。     

Spermatogonial depletion in adult Pin1-deficient mice

Spermatogonia in the mouse testis arise from early postnatal gonocytes that are derived from primordial germ cells (PGCs) during embryonic development. The proliferation, self-renewal, and differentiation of spermatogonial stem cells provide the basis for the continuing integrity of spermatogenesis. We previously reported that Pin1-deficient embryos had a profoundly reduced number of PGCs and that Pin1 was critical to ensure appropriate proliferation of PGCs. The current investigation aimed to elucidate the function of Pin1 in postnatal germ cell development by analyzing spermatogenesis in adult Pin1-/- mice. Although Pin1 was ubiquitously expressed in the adult testis, we found it to be most highly expressed in spermatogonia and Sertoli cells. Correspondingly, we show here that Pin1 plays an essential role in maintaining spermatogonia in the adult testis. Germ cells in postnatal Pin1-/- testis were able to initiate and complete spermatogenesis, culminated by production of mature spermatozoa. However, there was a progressive and age-dependent degeneration of the spermatogenic cells in Pin1-/- testis that led to complete germ cell loss by 14 mo of age. This depletion of germ cells was not due to increased cell apoptosis. Rather, detailed analysis of the seminiferous tubules using a germ cell-specific marker revealed that depletion of spermatogonia was the first step in the degenerative process and led to disruption of spermatogenesis, which resulted in eventual tubule degeneration. These results reveal that the presence of Pin1 is required to regulate proliferation and/or cell fate of undifferentiated spermatogonia in the adult mouse testis.     

Regulation of spermatogonial stem cell differentiation by Sertoli cells-derived exosomes through paracrine and autocrine signaling

In the orchestrated environment of the testicular niche, the equilibrium between self-renewal and differentiation of spermatogonial stem cells (SSCs) is meticulously maintained, ensuring a stable stem cell reserve and robust spermatogenesis. Within this milieu, extracellular vesicles, specifically exosomes, have emerged as critical conveyors of intercellular communication. Despite their recognized significance, the implications of testicular exosomes in modulating SSC fate remain incompletely characterized. Given the fundamental support and regulatory influence of Sertoli cells (SCs) on SSCs, we were compelled to explore the role of SC-derived exosomes (SC-EXOs) in the SSC-testicular niche. Our investigation hinged on the hypothesis that SC-EXOs, secreted by SCs from the testes of 5-day-old mice—a developmental juncture marking the onset of SSC differentiation—participate in the regulation of this process. We discovered that exposure to SC-EXOs resulted in an upsurge of PLZF, MVH, and STRA8 expression in SSC cultures, concomitant with a diminution of ID4 and GFRA1 levels. Intriguingly, obstructing exosomal communication in a SC-SSC coculture system with the exosome inhibitor GW4869 attenuated SSC differentiation, suggesting that SC-EXOs may modulate this process via paracrine signaling. Further scrutiny revealed the presence of miR-493-5p within SC-EXOs, which suppresses Gdnf mRNA in SCs to indirectly restrain SSC differentiation through the modulation of GDNF expression—an indication of autocrine regulation. Collectively, our findings illuminate the complex regulatory schema by which SC-EXOs affect SSC differentiation, offering novel perspectives and laying the groundwork for future preclinical and clinical investigations.     

Notch signaling in Sertoli cells regulates cyclical gene expression of Hes1 but is dispensable for mouse spermatogenesis

Mammalian spermatogenesis is a highly regulated system dedicated to the continuous production of spermatozoa from spermatogonial stem cells, and the process largely depends on microenvironments created by Sertoli cells, unique somatic cells that reside within a seminiferous tubule. Spermatogenesis progresses with a cyclical program known as the "seminiferous epithelial cycle," which is accompanied with cyclical gene expression changes in Sertoli cells. However, it is unclear how the cyclicity in Sertoli cells is regulated. Here, we report that Notch signaling, which is known to play an important role for germ cell development in Drosophila and Caenorhabditis elegans, is cyclically activated in Sertoli cells and regulates stage-dependent gene expression of Hes1. To elucidate the regulatory mechanism of stage-dependent Hes1 expression and the role of Notch signaling in mouse spermatogenesis, we inactivated Notch signaling in Sertoli cells by deleting protein O-fucosyltransferase 1 (Pofut1), using the cre-loxP system, and found that stage-dependent Hes1 expression was dependent on the activation of Notch signaling. Unexpectedly, however, spermatogenesis proceeded normally. Our results thus indicate that Notch signaling regulates cyclical gene expression in Sertoli cells but is dispensable for mouse spermatogenesis. This highlights the evolutionary divergences in regulation of germ cell development.     

精原干细胞的生命历程

精原干细胞是动物体内的一种成体干细胞,在睾丸微环境中可以像胚胎干细胞一样具有增殖、分化潜能。近年来借助于各种细胞学技术,人们对精原干细胞在不同睾丸微环境中的分化和发育状况进行了深入研究,睾丸内不同种类细胞间的相互作用以及特定微环境对干细胞转分化的影响,已成为本领域的热点核心内容。将从精原干细胞生命历程的角度讨论该过程中所取得的研究成果和存在的问题。     

Proteome analysis of spermatogonia: identification of a first set of 53 proteins

During spermatogenesis, the various classes of germ cells synthesize proteins necessary for their own functioning and for regulation of the Sertoli cells. However, the nature of these proteins has been little studied, especially in spermatogonia, the germ stem cells. In this study, the electrophoretic patterns of high-resolution, silver-stained, two-dimensional polyacrylamide gels of intracellular spermatogonial protein extracts were studied by computerized gel image analysis. We detected 675 individual spots, some of which we identified by mass spectrometry and database searching. We present here a first set of 53 proteins identified. They include housekeeping proteins never before detected in spermatogonia, ten proteins previously detected in the reproductive tract but not in spermatogonia, including stathmin, a protein previously shown to be involved in cell proliferation and differentiation, and one new testicular protein named translationally controlled tumor protein (TCTP), also known as a growth-related protein. Immunohistochemistry demonstrated that the two latter proteins were indeed highly expressed in spermatogonia in situ, and their possible involvement in spermatogonial division and proliferation is currently under investigation in our laboratory. We conclude that this type of experimental strategy, known as proteomics, is a very powerful way to analyze germ cell proteins comprehensively and should rapidly greatly improve our understanding of spermatogenesis.     

Germ Cell Transplantation and Testis Tissue Xenografting in Mice

Germ cell transplantation was developed by Dr. Ralph Brinster and colleagues at the University of Pennsylvania in 1994^1,2. These ground-breaking studies showed that microinjection of germ cells from fertile donor mice into the seminiferous tubules of infertile recipient mice results in donor-derived spermatogenesis and sperm production by the recipient animal². The use of donor males carrying the bacterial β-galactosidase gene allowed identification of donor-derived spermatogenesis and transmission of the donor haplotype to the offspring by recipient animals¹. Surprisingly, after transplantation into the lumen of the seminiferous tubules, transplanted germ cells were able to move from the luminal compartment to the basement membrane where spermatogonia are located³. It is generally accepted that only SSCs are able to colonize the niche and re-establish spermatogenesis in the recipient testis. Therefore, germ cell transplantation provides a functional approach to study the stem cell niche in the testis and to characterize putative spermatogonial stem cells. To date, germ cell transplantation is used to elucidate basic stem cell biology, to produce transgenic animals through genetic manipulation of germ cells prior to transplantation^4,5, to study Sertoli cell-germ cell interaction^6,7, SSC homing and colonization^3,8, as well as SSC self-renewal and differentiation^9,10.Germ cell transplantation is also feasible in large species¹¹. In these, the main applications are preservation of fertility, dissemination of elite genetics in animal populations, and generation of transgenic animals as the study of spermatogenesis and SSC biology with this technique is logistically more difficult and expensive than in rodents. Transplantation of germ cells from large species into the seminiferous tubules of mice results in colonization of donor cells and spermatogonial expansion, but not in their full differentiation presumably due to incompatibility of the recipient somatic cell compartment with the germ cells from phylogenetically distant species¹². An alternative approach is transplantation of germ cells from large species together with their surrounding somatic compartment. We first reported in 2002, that small fragments of testis tissue from immature males transplanted under the dorsal skin of immunodeficient mice are able to survive and undergo full development with the production of fertilization competent sperm¹³. Since then testis tissue xenografting has been shown to be successful in many species and emerged as a valuable alternative to study testis development and spermatogenesis of large animals in mice¹⁴.     

Genetic and epigenetic properties of mouse male germline stem cells during long-term culture

Although stem cells are believed to divide infinitely by self-renewal division, there is little evidence that demonstrates their infinite replicative potential. Spermatogonial stem cells are the founder cell population for spermatogenesis. Recently, in vitro culture of spermatogonial stem cells was described. Spermatogonial stem cells can be expanded in vitro in the presence of glial cell line-derived neurotrophic factor (GDNF), maintaining the capacity to produce spermatogenesis after transplantation into testis. Here, we examined the stability and proliferative capacity of spermatogonial stem cells using cultured cells. Spermatogonial stem cells were cultured over 2 years and achieved approximately 10(85)-fold expansion. Unlike other germline cells that often acquire genetic and epigenetic changes in vitro, spermatogonial stem cells retained the euploid karyotype and androgenetic imprint during the 2-year experimental period, and produced normal spermatogenesis and fertile offspring. However, the telomeres in spermatogonial stem cells gradually shortened during culture, suggesting that they are not immortal. Nevertheless, the remarkable stability and proliferative potential of spermatogonial stem cells suggest that they have a unique machinery to prevent transmission of genetic and epigenetic damages to the offspring, and these characteristics make them an attractive target for germline modification.     

Spermatogonial stem cells, infertility and testicular cancer

The spermatogonial stem cells (SSCs) are responsible for the transmission of genetic information from an individual to the next generation. SSCs play critical roles in understanding the basic reproductive biology of gametes and treatments of human infertility. SSCs not only maintain normal spermatogenesis, but also sustain fertility by critically balancing both SSC self-renewal and differentiation. This self-renewal and differentiation in turn is tightly regulated by a combination of intrinsic gene expression within the SSC as well as the extrinsic gene signals from the niche. Increased SSCs self-renewal at the expense of differentiation result in germ cell tumours, on the other hand, higher differentiation at the expense of self-renewal can result in male sterility. Testicular germ cell cancers are the most frequent cancers among young men in industrialized countries. However, understanding the pathogenesis of testis cancer has been difficult because it is formed during foetal development. Recent studies suggest that SSCs can be reprogrammed to become embryonic stem (ES)-like cells to acquire pluripotency. In the present review, we summarize the recent developments in SSCs biology and role of SSC in testicular cancer. We believe that studying the biology of SSCs will not only provide better understanding of stem cell regulation in the testis, but eventually will also be a novel target for male infertility and testicular cancers.