Phenotypic and functional characteristics of spermatogonial stem cells in rats

Spermatogonial stem cells (SSCs) are at the foundation of the highly productive spermatogenic process that continuously produces male gametes throughout postnatal life. However, experimental evaluation of SSCs in postnatal testes is complicated because these cells are extremely rare and few defining morphology or biochemical characteristics are known. In this study, we used the spermatogonial transplantation functional assay, combined with fluorescence-activated cell sorting (FACS) analysis to identify cellular, biochemical and surface antigenic characteristics of SSCs in rat testes during development. Our results demonstrated that forward scatter (FSc)(hi), side scatter (SSc)(hi), mitochondria membrane potential (DeltaPsim)(lo), Ep-CAM(+), Thy-1(+), beta3-integrin(+) stem cells in neonate rat testes become SSc(lo), DeltaPsim(hi), Ep-CAM(+), Thy-1(lo), beta3-integrin(-) stem cells in pup rat testes. Furthermore, prospective identification of rat testis cell populations (Ep-CAM(+)), highly enriched for SSCs (1 in 13 for neonate; 1 in 8.5 for pup) enabled us to predict the Thy-1 and beta3-integrin status of stem cells in neonate and pup testes, which was subsequently confirmed by transplantation analyses. Systematic characterization of SSCs enabled the production of testis cell populations highly enriched (up to 120-fold) for SSCs and will facilitate future investigations of functional and genomic characteristics.     

Expression patterns of cell-surface molecules on male germ line stem cells during postnatal mouse development

Spermatogonial stem cells (SSCs) are stem cells of the male germ line. In mice, SSCs are quiescent at birth but actively proliferate during the first postnatal week, while they rarely divide in adult, suggesting an age-dependent difference in SSC characteristics. As an approach to evaluate this possibility, we studied the expression pattern of cell-surface molecules on neonatal, pup, and adult mouse SSCs. Using immunomagnetic cell sorting, testis cells were selected for the expression of alpha(6) integrin, alpha(v) integrin, c-kit receptor tyrosine kinase (Kit), or a binding subunit of glial-cell-line-derived neurotrophic factor (GDNF) receptor, GFRalpha1. Selected cells were assayed for their stem cell activity using spermatogonial transplantation. The results showed that SSCs expressed alpha(6) integrin, but not alpha(v) integrin and Kit, regardless of age. The SSC activity in pup GFRalpha1(+) cells was higher than that in adult and neonatal cells, indicating that the expression pattern of GFRalpha1 varied age-dependently. To evaluate if SSCs show an age-dependent difference in their response to GDNF, we cultured highly enriched pup and adult SSCs with GDNF: we could not observe such an age-dependent difference in vitro. In addition, we failed to immunologically detect the expression of two types of GDNF receptor signaling subunits on SSCs. These results indicate that SSCs may change the expression patterns of cell-surface molecules during postnatal development, and suggest that GDNF receptor molecules may not be abundantly or specifically expressed in the in vivo population of mouse SSCs.     

Generation of mice by transplantation of an adult spermatogonial cell line after cryopreservation

Objectives:  The key to fertility in adult males is production of mature spermatogenic cells. Spermatogonial stem cells (SSC) have the dual capacity of self-renewal and of differentiation into mature sperm. SSC transplantation may provide potential treatment for specific male infertilities. However, until now, there has been no evidence of offspring produced by transplantation of adult SSC line cells in humans or other mammals.
Materials and methods:  A new line of SSCs from adult C57BL/6 mouse was established by using magnetic-activated cell sorting. The cell line was characterized by immunocytochemistry, karyotype analysis and telomeric repeat amplification protocol (TRAP) telomerase activity assay. Spermatogenic function was examined by allograft into germ cell-ablated recipient mice.
Results:  For more than 14 months with more than 65 maintenance passages, the cell line showed a normal karyotype (40, XY) and high telomerase activity. It represented a Thy-1+, Oct4+, SSEA-1-, c-kit- (99 ± 1%) cell subpopulation. We cryopreserved these SSCs and successfully produced normal offspring after transplanting them into testes of busulphan-sterilized mice.
Conclusions:  We established and long-term maintained an adult SSC line with normal spermatogenic function, without the need of genetic modification; thus, this study provides a model system for basic research and clinical application.     

Establishment of a short-term in vitro assay for mouse spermatogonial stem cells

Spermatogonial stem cells (SSCs) are responsible for life-long, daily production of male gametes and for the transmission of genetic information to the next generation. Unequivocal detection of SSCs has relied on spermatogonial transplantation, in which functional SSCs are analyzed qualitatively and quantitatively based on their regenerative capacity. However, this technique has some significant limitations. For example, it is a time-consuming procedure, as data acquisition requires at least 8 weeks after transplantation. It is also laborious, requiring microinjection of target cells into the seminiferous tubules of individual testes. Donor-recipient immunocompatibility for successful transplantation and large variations in data obtained represent further limitations of this technique. In the present study, we provide evidence that a recently developed SSC culture system can be employed as a reliable, short-term in vitro assay for SSCs. In this system, donor cells generate three-dimensional structures of aggregated germ cells (clusters) in vitro within 6 days. We show that each cluster originates from a single cell. Thus, by counting the clusters, cluster-forming cells can be quantified. We observed a strong linear correlation between the numbers of clusters and SSCs over extended culture periods. Therefore, cluster numbers faithfully reflect SSC numbers. These results indicate that by simply counting the number of clusters, functional SSCs can be readily detected within 1 week in a semi-quantitative manner. The faithfulness of this in vitro assay to the transplantation assay was further confirmed under two experimental situations. This in vitro cluster formation assay provides a reliable short-term technique to detect SSCs.     

Homing of mouse spermatogonial stem cells to germline niche depends on beta1-integrin

Spermatogonial stem cells (SSCs) provide the foundation for spermatogenesis. In a manner comparable to hematopoietic stem cell transplantation, SSCs colonize the niche of recipient testes and reinitiate spermatogenesis following microinjection into the seminiferous tubules. However, little is known about the homing mechanism of SSCs. Here we examined the role of adhesion molecules in SSC homing. SSCs isolated from mice carrying loxP-tagged beta1-integrin alleles were ablated for beta1-integrin expression by in vitro adenoviral cre transduction. The beta1-integrin mutant SSCs showed significantly reduced ability to recolonize recipient testes in vivo and to attach to laminin molecules in vitro. In contrast, genetic ablation of E-cadherin did not impair homing, and E-cadherin mutant SSCs completed normal spermatogenesis. In addition, the deletion of beta1-integrin on Sertoli cells reduced SSC homing. These results identify beta1-integrin as an essential adhesion receptor for SSC homing and its association with laminin is critical in multiple steps of SSC homing.     

Establishment of Alternative Culture Method for Spermatogonial Stem Cells Using Knockout Serum Replacement

Since spermatogonial stem cells (SSCs) are capable of both self-renewal and differentiation to daughter cells for subsequent spermatogenesis, the development of an efficient in vitro culture system is essential for studies related to spermatogenesis. Although the currently available system is serum-free and contains only chemically-defined components, it highly relies upon bovine serum albumin (BSA), a component with batch-to-batch quality variations similar to those of fetal bovine serum. Thus, we searched for an alternative BSA-free culture system that preserved the properties of SSCs. In this study, we utilized Knockout Serum Replacement (KSR) in the SSC culture medium, as a substitute for BSA. The results demonstrated that KSR supported the continuous growth of SSCs in vitro and the SSC activity in vivo without BSA, in a feeder-cell combination with mouse embryonic fibroblasts. The addition of BSA to KSR further facilitated cell cycle progression, whereas a transplantation assay revealed that the addition of BSA did not affect the number of SSCs in vivo. The combination of KSR with BSA also allowed the elimination of GFRA1 and FGF2, and the reduction of the GDNF concentration from 20 ng/ml to 5 ng/ml, while maintaining the growth rate and the expression of SSC markers. Furthermore, KSR was also useful with SSCs from non-DBA/2 strains, such as C57BL/6 and ICR. These results suggested that KSR is an effective substitute for BSA for long-term in vitro cultures of SSCs. Therefore, this method is practical for various studies related to SSCs, including spermatogenesis and germ stem cell biology.     

小鼠精原干细胞在三种培养基中的生长行为

目的：建立小鼠精原干细胞（SSCs）的体外长期培养体系。方法：用分别添加了等量的胶质细胞源神经营养因子（GDNF）、可溶性GFRα1和hFGF的DMEM／F12、KSR和StemPro-34 SFM三种无血清培养基和MEF饲养层分别培养经差异贴壁分选富集的小鼠SSCs,通过形态观察、标志基因的RT-PCR和免疫细胞化学分析检测其SSCs本原。结果：DMEM／F12与KSR可支持小鼠SSCs在体外存活6-7d,而StemPro-34 SFM能能维持SSCs体外增值一个月。结论：StemPro-34 SFM支持小鼠SSCs的体外增殖。     

Magnetic activated cell sorting allows isolation of spermatogonia from adult primate testes and reveals distinct GFRa1‐positive subpopulations in men

Background Isolation of spermatogonial stem cells (SSCs) could enable in vitro approaches for exploration of spermatogonial physiology and therapeutic approaches for fertility preservation. SSC isolation from adult testes is difficult due to low cell numbers and lacking cell surface markers. Glial cell‐derived neurotrophic factor family receptor alpha‐1 (GFRα1) plays a crucial role for the maintenance of SSCs in rodents and is expressed in monkey spermatogonia. Methods Magnetic activated cell sorting was employed for the enrichment of GFRα1+ spermatogonia from adult primate testes. Results Magnetic activated cell sorting of monkey cells enriched GFRα1+ cells threefold. 11.4% of GFRα1+ cells were recovered. 42.9% of GFRα1+ cells were recovered in sorted fractions of human testicular cells, representing a fivefold enrichment. Interestingly, a high degree of morphological heterogeneity among the GFRα1+ cells from human testes was observed. Conclusions Magnetic activated cell sorting using anti‐GFRα1 antibodies provides an enrichment strategy for spermatogonia from monkey and human testes.     

Establishment of a proteome profile and identification of molecular markers for mouse spermatogonial stem cells

Spermatogonial stem cells (SSCs) are undifferentiated cells that are required to maintain spermatogenesis throughout the reproductive life of mammals. Although SSC transplantation and culture provide a powerful tool to identify the mechanisms regulating SSC function, the precise signalling mechanisms governing SSC self‐renewal and specific surface markers for purifying SSCs remain to be clearly determined. In the present study, we established a steady SSC culture according to the method described by Shinohara's lab. Fertile progeny was produced after transplantation of cultured SSCs into infertile mouse testis, and the red fluorescence exhibited by the culture cell membranes was stably and continuously transmitted to the offspring. Next, via advanced mass spectrometry and an optimized proteomics platform, we constructed the proteome profile, with 682 proteins expressed in SSCs. Furthermore bioinformatics analysis showed that the list contained several known molecules that are regulated in SSCs. Several nucleoproteins and membrane proteins were chosen for further exploration using immunofluorescence and RT‐PCR. The results showed that SALL1, EZH2, and RCOR2 are possibly involved in the self‐renewal mechanism of SSCs. Furthermore, the results of tissue‐specific expression analysis showed that Gpat2 and Pld6 were uniquely and highly expressed in mouse testes and cultured SSCs. The cellular localization of PLD6 was further explored and the results showed it was primarily expressed in the spermatogonial membrane of mouse testes and cultured SSCs. The proteins identified in this study form the basis for further exploring the molecular mechanism of self‐renewal in SSCs and for identifying specific surface markers of SSCs.     

GABA exists as a negative regulator of cell proliferation in spermaogonial stem cells

γ-amino butyric acid (GABA) is the main inhibitory neurotransmitter in the mammalian central nervous system. GABA is also found in many peripheral tissues, where it has important functions during development. Here, we identified the existence of the GABA system in spermatogonial stem cells (SSCs) and found that GABA negatively regulates SSC proliferation. First, we demonstrated that GABA and its synthesizing enzymes were abundant in the testes 6 days postpartum (dpp), suggesting that GABA signaling regulates SSCs function in vivo. In order to directly examine the effect of GABA on SSC proliferation, we then established an in vitro culture system for long-term expansion of SSCs. We showed that GABA_A receptor subunits, including α1, α5, β1, β2, β3 and γ3, the synthesizing enzyme GAD67, and the transporter GAT-1, are expressed in SSCs. Using phosphorylated histone H3 (pH3) staining, we demonstrated that GABA or the GABA_AR-specific agonist muscimol reduced the proliferation of SSCs. This GABA regulation of SSC proliferation was shown to be independent of apoptosis using the TUNEL assay. These results suggest that GABA acts as a negative regulator of SSC proliferation to maintain the homeostasis of spermatogenesis in the testes.     

In vivo and in vitro aging is detrimental to mouse spermatogonial stem cell function

The development of techniques to maintain the spermatogonial stem cell (SSC) in vivo and in vitro for extended periods essentially allows for the indefinite continuation of an individual germline. Recent evidence indicates that the aging of male reproductive function is due to failure of the SSC niche. SSCs are routinely cultured for 6 mo, and no apparent effect of culture over this period has been observed. To determine the effects of SSC aging, we utilized an in vitro culture system, followed by quantitative transplantation experiments. After culture for 6 mo, SSCs that had been aged in vivo for 1500 days had a slower proliferation rate than SSCs that were aged in vivo to 8 or 300 days. Examination of methylation patterns revealed no apparent difference in DNA methylation between SSCs that were aged 8, 300, or 1500 days before culture. Long-term culture periods resulted in a loss of stem cell potential without an obvious change in the visual appearance of the culture. DNA microarray analysis of in vivo- and in vitro-aged SSCs identified the differential expression of several genes important for SSC function, including B-cell CLL/lymphoma 6, member B (Bcl6b), Lim homeobox protein 1 (Lhx1), and thymus cell antigen 1, theta (Thy1). Collectively, these data indicate that, although both in vitro and in vivo aging are detrimental to SSC function, in vitro aging results in greater loss of function, potentially due to a decrease in core SSC self-renewal gene expression and an increase in germ cell differentiation gene expression.     

Petasites japonicus Stimulates the Proliferation of Mouse Spermatogonial Stem Cells

Oriental natural plants have been used as medical herbs for the treatment of various diseases for over 2,000 years. In this study, we evaluated the effect of several natural plants on the preservation of male fertility by assessing the ability of plant extracts to stimulate spermatogonial stem cell (SSC) proliferation by using a serum-free culture method. In vitro assays showed that Petasites japonicus extracts, especially the butanol fraction, have a significant effect on germ cells proliferation including SSCs. The activity of SSCs cultured in the presence of the Petasites japonicus butanol fraction was confirmed by normal colony formation and spermatogenesis following germ cell transplantation of the treated SSCs. Our findings could lead to the discovery of novel factors that activate SSCs and could be useful for the development of technologies for the prevention of male infertility.     

Epigenetic modifications and self-renewal regulation of mouse germline stem cells

Germline stem (GS) cells were established from gonocytes and spermatogonia of postnatal mouse testes. GS cells proliferate in the presence of several kinds of cytokines, and a small percentage of GS cells also show spermatogonial stem cell (SSC) activity, i.e., they differentiate into sperm after being transplanted into infertile mouse testes without endogenous spermatogenesis. Interestingly, in GS cell culture, we also found that pluripotent stem cells (multipotent germline stem cells (mGS cells)) could be derived and these mGS cells do not have normal androgenetic genomic imprinting marks that are shown in GS cells, e.g., H19 hypermethylation. A new culture system for fetal male germ cells (embryonic GS (eGS) cells) has also been recently developed. Although these cells exhibited SSC potential, the offspring from cultured cells showed heritable imprinting defects in their DNA methylation patterns. In an attempt to understand the self-renewal machinery in SSCs, we transfected H-Ras and cylin D2 into GS cells, and successfully reconstructed the SSC self-renewal ability without using exogenous cytokines. Although these cells showed SSC activity in germ cell transplantation assays, we also found development of seminomatous tumors, possibly induced by excessive self-renewing signal. These stem cell culture systems are useful tools not only for understanding the mechanisms of self-renewal or epigenetic reprogramming but also for clarifying the mechanism of germ cell tumor development.     

KnockoutTM SR无血清培养基支持小鼠精原干细胞的短期存活(简报)

精原干细胞(spermatogonial stem cells,SSCs)是睾丸内具有自我复制和分化为精子潜能的干细胞,它的体外培养是精子发生机理研究和制作转基因动物等的新途径[1,2].近几年的研究表明,SSCs在体外的自我增殖需要GDNF(glial cell line-derived neu-rotrophie factor)因子和饲养层细胞等的支持[3-10].并且睾丸支持细胞(Sertoli's cells)和血清都导致培养的SSCs分化[1,6].因此,使用无血清培养基培养高度纯化的SSCs是培养成败的关键之一.     

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.     

GDNF family receptor alpha1 phenotype of spermatogonial stem cells in immature mouse testes

Spermatogonial stem cells (SSCs) are essential for spermatogenesis, and these adult tissue stem cells balance self-renewal and differentiation to meet the biological demand of the testis. The developmental dynamics of SSCs are controlled, in part, by factors in the stem cell niche, which is located on the basement membrane of seminiferous tubules situated among Sertoli cells. Sertoli cells produce glial cell line-derived neurotrophic factor (GDNF), and disruption of GDNF expression results in spermatogenic defects and infertility. The GDNF signals through a receptor complex that includes GDNF family receptor alpha1 (GFRA1), which is thought to be expressed by SSCs. However, expression of GFRA1 on SSCs has not been confirmed by in vivo functional assay, which is the only method that allows definitive identification of SSCs. Therefore, we fractionated mouse pup testis cells based on GFRA1 expression using magnetic activated cell sorting. The sorted and depleted fractions of GFRA1 were characterized for germ cell markers by immunocytochemistry and for stem cell activity by germ cell transplantation. The GFRA1-positive cell fraction coeluted with other markers of SSCs, including ITGA6 and CD9, and was significantly depleted of KIT-positive cells. The transplantation results confirmed that a subpopulation of SSCs expresses GFRA1, but also that the stem cell pool is heterogeneous with respect to the level of GFRA1 expression. Interestingly, POU5F1-positive cells were enriched nearly 15-fold in the GFRA1-selected fraction, possibly suggesting heterogeneity of developmental potential within the stem cell pool.     

Glial cell-line derived neurotrophic factor-mediated RET signaling regulates spermatogonial stem cell fate

Normal spermatogenesis is essential for reproduction and depends on proper spermatogonial stem cell (SSC) function. Genes and signaling pathways that regulate SSC function have not been well defined. We report that glial cell-line-derived neurotrophic factor (GDNF) signaling through the RET tyrosine kinase/GFRA1 receptor complex is required for spermatogonial self-renewal in mice. GFRA1 and RET expression was identified in a subset of gonocytes at birth, was restricted to SSCs during normal spermatogenesis, and RET expressing cells were abundant in a cryptorchid model of SSC self-renewal. We used the whole-testis transplantation technique to overcome the limitation of neonatal lethality of Gdnf-, Gfra1-, and Ret-deficient mice and found that each of these genes is required for postnatal spermatogenesis and not for embryological testes development. Each mutant testis shows severe SSC depletion by Postnatal Day 7 during the first wave of spermatogenesis. These defects were due to lack of SSC proliferation and an inability of SSCs to maintain an undifferentiated state. Our results demonstrate that GDNF-mediated RET signaling is critical for the fate of undifferentiated spermatogonia and that abnormalities in this pathway may contribute to male infertility and testicular germ cell tumors.     

Aging of male germ line stem cells in mice

In the present study, we investigated the effect of aging on spermatogonial stem cells (SSCs) and on the testicular somatic environment in ROSA26 mice. First, we examined testis weights at 2 mo, 6 mo, 1 yr, and 2 yr of age. At 1 and 2 yr, bilateral atrophied testes were observed in 50% and 75% of the mice, respectively; the rest of the mice had testis weights similar to those of young mice. Next, we evaluated the number and the activity of aged SSCs using spermatogonial transplantation. Numbers of SSCs in atrophied testes decreased in an age-dependent manner to as low as 1/60 of those in testes of young mice. Numbers of SSCs in nonregressed testes were similar regardless of age. The colony length, which is indicative of the potential of SSCs to regenerate spermatogenesis, was similar with donor cells from atrophied testes of 1-yr-old mice and those from testes of young mice, suggesting that SSCs remaining in 1-yr atrophied testes were functionally intact. Colonies arising from SSCs derived from 2-yr atrophied testes were significantly shorter, however, indicating that both SSC numbers and activity declined with age. Finally, we transplanted donor cells from young animals into 1- and 2-yr atrophied testes. Although the weight of 2-yr testes did not change after transplantation, that of 1-yr testes increased significantly, indicating that 1-yr, but not 2-yr, atrophied testes are permissive for regeneration of spermatogenesis by SSCs from young mouse testes. These results demonstrate that both SSCs and somatic environment in the testis are involved in the aging process.