Biology Of Spermatogonial Stem Cells Research Articles

Production of fertile sperm from in vitro propagating enriched spermatogonial stem cells of farmed catfish, Clarias batrachus.

Spermatogenesis is a highly co-ordinated and complex process. In vitro propagation of spermatogonial stem cells (SSCs) could provide an avenue in which to undertake in vivo studies of spermatogenesis. Very little information is known about the SSC biology of teleosts. In this study, collagenase-treated testicular cells of farmed catfish (Clarias batrachus, popularly known as magur) were purified by Ficoll gradient centrifugation followed by magnetic activated cell sorting using Thy1.2 (CD90.2) antibody to enrich for the spermatogonial cell population. The sorted spermatogonial cells were counted and gave ~3 × 106 cells from 6 × 106 pre-sorted cells. The purified cells were cultured in vitro for >2 months in L-15 medium containing fetal bovine serum (10%), carp serum (1%) and other supplements. Microscopic observations depicted typical morphological SSC features, bearing a larger nuclear compartment (with visible perinuclear bodies) within a thin rim of cytoplasm. Cells proliferated in vitro forming clumps/colonies. mRNA expression profiling by qPCR documented that proliferating cells were Plzf + and Pou2+, indicative of stem cells. From 60 days onwards of cultivation, the self-renewing population differentiated to produce spermatids (~6 × 107 on day 75). In vitro-produced sperm (2260 sperm/SSC) were free swimming in medium and hence motile (non-progressive) in nature. Of those, 2% were capable of fertilizing and generated healthy diploid fingerlings. Our documented evidence provides the basis for producing fertile magur sperm in vitro from cultured magur SSCs. Our established techniques of SSC propagation and in vitro sperm production together should trigger future in vivo experiments towards basic and applied biology research.

Establishment of a culture condition for strong proliferation and enrichment of chicken spermatogonial stem cells in vitro

Poultry spermatogonial stem cells (SSCs) have the potential to serve as a model for studying the basic biology of SSC and they can also be used for biotechnological purposes. However, the small number of SSCs and the presence of the testicular somatic cells with SSCs have limited their applications. Therefore, this study was undertaken for the first time to investigate the effect of a serum-free medium supplemented with a combination of specific growth factors and B27 on the proliferation and enrichment of newborn chicken SSCs in vitro. Newborn chicken testicular cells were cultured in a serum-free DMEM, supplemented with GDNF, bFGF, LIF, and EGF growth factors and also B27 as an alternative for FBS. Presence and maintenance of the SSCs in the enriched cultures were evaluated by detection of alkaline phosphatase (AP) activity and ASZ1, POU5F1, CVH and GPR125 gene expression. A small number of clusters and colonies were emerged in testicular cell cultures before treatment with the enriched cell culture medium. Enrichment of the DMEM with the above indicated factors strongly promoted the proliferation of the chicken SSCs. Moreover, this culture condition declined attachment and maintenance of the testicular somatic cells and thus they decreased gradually in the cultures. The enriched SSCs were positive for AP activity and with detectable levels of ASZ1, POU5F1, CVH and GPR125 gene expression. This study shows that serum-free medium supplemented with a combination of B27 and the above indicated growth factors induces proliferation and enrichment of chicken SSCs in vitro in a short period of time.

In vitro spermatogenesis using bovine testis tissue culture techniques

Spermatogenesis is a complex process initiated by spermatogonial stem cells (SSCs) that have the ability to differentiate into mature spermatozoa or to self-renew to maintain the SSC population and long-term fertility. However, a technique for complete spermatogenesis in vitro using cell culture has not yet been developed. In the present study, we developed in vitro spermatogenesis techniques using bovine testis tissue culture. The effects of specific temperatures and different media on maintaining tubule and germ cell competency were investigated. We found that the optimal temperature and media were 37°C and mouse serum-free medium (mSFM), respectively. In addition, the efficacy of various hormones and growth factors on spermatogenesis in bovine testis tissues maintained in vitro was evaluated. We found that the addition of triiodothyronine (T3) and stem cell factor (SCF) induced spermatogenesis of bovine SSCs in vitro. Therefore, tissue fragments were cultured in the presence of T3 and SCF for three months to induce spermatogenesis in vitro. Overall, in vitro spermatogenesis was enhanced 2.4- to 2.7-fold. Our tissue culture technique may serve as a model system that leads to a more comprehensive understanding of the biology of SSCs as well as the factors that regulate male fertility. Furthermore, the results of this study will be integral for the continued refinement of techniques to manipulate bovine SSCs.

Factors supporting long-term culture of bovine male germ cells.

Spermatogonial stem cells (SSCs) are unipotent in nature, but mouse SSCs acquire pluripotency under the appropriate culture conditions. Although culture systems are available for rodent and human germ-cell lines, no proven culture system is yet available for livestock species. Here, we examined growth factors, matrix substrates and serum-free supplements to develop a defined system for culturing primitive germ cells (gonocytes) from neonatal bovine testis. Poly-L-lysine was a suitable substrate for selective inhibition of the growth of somatic cells and made it possible to maintain a higher gonocyte:somatic cell ratio than those maintained with gelatin, collagen or Dolichos biflorus agglutinin (DBA) substrates. Among the serum-free supplements tested in our culture medium, knockout serum replacement (KSR) supported the proliferation and survival of gonocytes better than the supplements B-27 and StemPro-SFM after sequential passages of colonies. Under our optimised culture conditions consisting of 15% KSR supplement on poly-L-lysine-coated dishes, the stem-cell and germ-cell potentials of the cultured gonocytes were maintained with normal karyotype for more than 2 months (over 13 passages). The proposed culture system, which can maintain a population of proliferating bovine germ stem cells, could be useful for studying SSC biology and germline modifications in livestock animals.

Spermatogonial stem cells: Current biotechnological advances in reproduction and regenerative medicine.

Spermatogonial stem cells (SSCs) are the germ stem cells of the seminiferous epithelium in the testis. Through the process of spermatogenesis, they produce sperm while concomitantly keeping their cellular pool constant through self-renewal. SSC biology offers important applications for animal reproduction and overcoming human disease through regenerative therapies. To this end, several techniques involving SSCs have been developed and will be covered in this article. SSCs convey genetic information to the next generation, a property that can be exploited for gene targeting. Additionally, SSCs can be induced to become embryonic stem cell-like pluripotent cells in vitro. Updates on SSC transplantation techniques with related applications, such as fertility restoration and preservation of endangered species, are also covered on this article. SSC suspensions can be transplanted to the testis of an animal and this has given the basis for SSC functional assays. This procedure has proven technically demanding in large animals and men. In parallel, testis tissue xenografting, another transplantation technique, was developed and resulted in sperm production in testis explants grafted into ectopical locations in foreign species. Since SSC culture holds a pivotal role in SSC biotechnologies, current advances are overviewed. Finally, spermatogenesis in vitro, already demonstrated in mice, offers great promises to cope with reproductive issues in the farm animal industry and human clinical applications.

Busulfan pretreatment for transplantation of rat spermatogonia differentially affects immune and reproductive systems in male recipient mice.

Testicular cell transplantation has generally been performed by using immune-deficient recipient mice to investigate the biology of spermatogonial stem cells (SSCs), the production of transgenic animals, and restoration of fertility. Recently, we demonstrated that rat spermatogenesis can occur in the seminiferous tubules of immune-competent recipient mice via pretreatment with busulfan (Myleran, 1, 4-butanediol methanesulfonate, 40mg/kg) after transplantation of rat SSCs. However, considering the immunosuppressive effect of busulfan, there is a possibility that busulfan itself causes immune suppression in immune-competent recipient mice. The aim of this study was to determine the effects of busulfan on the immune system and spermatogenesis in immune-competent recipient mice. The results showed that at 60days after busulfan treatment, just the same time as the transplantation, the recovery could be seen in the immune system including cell counts and functions of T and B lymphocytes in the spleen, but the spermatogenesis was more compromised. This study demonstrated that after busulfan pretreatment the immune system in immune-competent recipient mice had recovered by the time that rat spermatogenesis could occur in the murine testis. It became clear that xenogenic spermatogenesis can be tolerated in seminiferous tubules in the testes of immune-competent mice.

The quest for male germline stem cell markers: PAX7 gets ID'd.

Male germline or spermatogonial stem cells (SSCs) are conserved across many species and essential for uninterrupted production of sperm over long periods of reproductive life span. A better understanding of SSC biology provides limitless opportunities in male reproductive health, fertility preservation, and regenerative medicine. Although several potential markers define SSCs, not many definitive markers exist that are specific for a rare subset of SSCs that self-renew and have the ability to give rise to other progenitors, eventually contributing to all stages of spermatogenesis. In the September 2014 issue of the JCI, Aloisio and colleagues report that PAX7 is a new marker expressed uniquely in a rare subset of SSCs in mouse testes. PAX7+ cells fulfill all the criteria required for bona fide SSCs. Surprisingly, male germline-specific deletion of Pax7 indicates that it is dispensable for spermatogenesis.

The histone methyltransferase ESET is required for the survival of spermatogonial stem/progenitor cells in mice.

Self-renewal and differentiation of spermatogonial stem cells (SSCs) are the foundation of spermatogenesis throughout a male's life. SSC transplantation will be a valuable solution for young male patients to preserve their fertility. As SSCs in the collected testis tissue from the patients are very limited, it is necessary to expansion the SSCs in vitro. Previous studies suggested that histone methyltransferase ERG-associated protein with SET domain (ESET) represses gene expression and is essential for the maintenance of the pool of embryonic stem cells and neurons. The objective of this study was to determine the role of ESET in SSCs using in vitrocell culture and germ cell transplantation. Cell transplantation assay showed that knockdown of ESET reduced the number of seminiferous tubules with spermatogenesis when compared with that of the control. Knockdown of ESET also upregulated the expression of apoptosis-associated genes (such as P53, Caspase9, Apaf1), whereas inhibited the expression of apoptosis-suppressing genes (such as Bcl2l1, X-linked inhibitor of apoptosis protein). In addition, suppression of ESET led to increase in expression of Caspase9 and activation of Caspase3 (P17) as well as cleavage of poly (ADP-ribose) polymerase. Among the five ESET-targeting genes (Cox4i2, spermatogenesis and oogenesis Specific Basic Helix-Loop-Helix 2, Nobox, Foxn1 and Dazl) examined by ChIP assay, Cox4i2 was found to regulate SSC apoptosis by the rescue experiment. BSP analyses further showed that DNA methylation in the promoter loci of Cox4i2was influenced by ESET, indicating that ESET also regulated gene expression through DNA methylation in addition to histone methylation. In conclusion, we found that ESET regulated SSC apoptosis by suppressing of Cox4i2 expression through histone H3 lysine 9 tri-methylation and DNA methylation. The results obtained will provide unique insights that would broaden the research on SSC biology and contribute to the treatment of male infertility.

Characterization, Isolation, and Culture of Mouse and Human Spermatogonial Stem Cells

Spermatogenesis is a special process by which spermatogonial stem cells (SSCs) divide and differentiate to male gametes called mature spermatozoa. SSCs are the unique cells because they are adult stem cells that transmit genetic information to subsequent generations. Accumulating evidence has demonstrated that SSCs can be reprogrammed to acquire pluripotency to become embryonic stem-like cells that differentiate into all cell lineages of the three germ layers, highlighting potential important applications of SSCs for regenerative medicine. Recent studies from peers and us have made great achievements on the characterization, isolation, and culture of mouse and human SSCs, which could lead to better understanding the biology of SSCs and the applications of SSCs in both reproductive and regenerative medicine. In this review, we first compared the cell identity and biochemical phenotypes between mouse SSCs and human SSCs. Notably, the cell types of mouse and human SSCs are distinct, and human SSCs share some but not all phenotypes with mouse SSCs. The approaches for isolating SSCs as well as short- and long-term culture of mouse SSCs and short-period culture of human SSCs were also discussed. We further addressed the new advances on the self-renewal of SSCs with an aim to establish the long-term culture of human SSCs which has not yet been achieved.

The chemokine CXCL12 and its receptor CXCR4 are implicated in human seminoma metastasis

Seminoma and non-seminoma tumours increasingly occur within the western population. These tumours originate from carcinoma in situ (CIS) cells, which arise from dysfunctional gonocytes. CXCL12 and its receptors, CXCR4 and CXCR7, have been implicated in migration, proliferation and survival of gonocytes and their precursors and progeny, primordial germ cells and spermatogonial stem cells respectively. We previously found evidence that several miRNA molecules predicted to modulate CXCR4 signalling are differentially expressed during the differentiation of gonocytes into spermatogonia in mice. Bioinformatic analysis predicted these miRNA to modulate CXCR4 signalling, leading us to hypothesize that CXCL12-mediated CXCR4 signalling is involved in the disrupted differentiation of gonocytes that underpins CIS formation. Indeed, we detected CXCL12 in Sertoli cells of normal human testis, and relatively high expression in tumour stroma with concomitant weak staining in dispersed tumour cells. In contrast, CXCR4 was expressed in spermatogonial and meiotic germ cells of normal testis and in the majority of tumour cells. Quantitative RT-PCR identified elevated CXCR4 transcript levels in seminoma compared with normal testis and to non-seminoma, potentially reflecting the higher proportion of dysfunctional germ cells within seminomas. In the normal testis, expression of CXCR4 downstream signalling molecules phospho-MEK1/2 and phospho-ERK1/2 correlated with CXCR4/CXCL12 expression. Strikingly, this correlation was absent in seminoma and non-seminoma samples, suggesting that CXCL12 signalling is disrupted. Proliferation rate and cell survival were not altered by CXCL12 in either seminoma (TCam-2) or non-seminoma (833ke) cell lines. However, CXCL12 exposure induced TCam-2 cell invasion though simulated basement membrane, while in contrast, we provide the novel evidence that CXCR4-expressing non-seminoma cell lines 833ke and NTera2/D1 do not invade in response to CXCL12. These findings indicate that CXCL12 expression in the human testis may selectively influence seminoma migration and metastasis, correlating with its importance in gonocyte and spermatogonial stem cell biology.

Hidden gems in the niche: a new approach to the study of spermatogonial stem cells

Hidden gems in the niche: a new approach to the study of spermatogonial stem cells

Propagation of Adult SSCs: From Mouse to Human

Adult spermatogonial stem cells (SSCs) represent a distinctive source of stem cells in mammals for several reasons. First, by giving rise to spermatogenesis, SSCs are responsible for the propagation of a father's genetic material. As such, autologous SSCs have been considered for treatment of infertility and other purposes, including correction of inherited disorders. Second, adult spermatogonia can spontaneously produce embryonic-like stem cells in vitro, which could be used as an alternative for therapeutic, diagnostic, or drug discovery strategies for humans. Therefore, an increasing urgency is driving efforts to understand the biology of SSCs and improve techniques to manipulate them in vitro as a prerequisite to achieve the aforementioned goals. The characterization of adult SSCs also requires reproducible methods to isolate and maintain them in long-term culture. Herein, we describe recent major advances and challenges in propagation of adult SSCs from mice and humans during the past few years, including the use of unique cell surface markers and defined cultured conditions.

Effect of Oct-4 Silencing on Proliferation and Differentiation of Mouse Undifferentiated Type a Spermatogonial Cells

Spermatogenesis is a complex process involving cell division and differentiation of Spermatogonial Stem Cells (SSCs), mediated by coordinated expression of a number of genes. The study of SSC biology was challenging due to the unavailability of proper SSC markers and their culture methods. In recent years, these hurdles have been somewhat overcome. A number of markers for undifferentiated spermatogonia are known to be involved in the process of SSC self-renewal. Oct-4 is one such marker expressed from Primordial Germ Cells (PGCs) of prenatal stages till undifferentiated spermatogonia of postnatal adult testes. Though, expressed by undifferentiated spermatogonia, its role in the process of their self-renewal, proliferation and differentiation is not clearly understood. In the current study, using shRNA mediated gene silencing approach, we show that Oct-4 silencing in undifferentiated type A spermatogonia leads to phenotypic differentiation of these cells to type A1-A4 spermatogonia, marked by the increased c-KIT expression, and decreased proliferation, marked by decreased PCNA expression. The study also demonstrates that Oct-4 silencing causes down-regulation of Plzf, Gfra-1, c-Ret, Bcl6b and Etv5 mRNA and protein. Therefore the current study suggests that Oct-4 does play an important role in deciding the fate of undifferentiated spermatogonia by controlling their proliferation and differentiation. In conclusion, the present study may provide useful insights into understanding the involvement of Oct-4 in proliferation and differentiation of undifferentiated spermatogonia in mice.

Spermatogonial Stem Cell Biology and Niche in Fish

Spermatogonial Stem Cell Biology and Niche in Fish

Human spermatogonial stem cells: a possible origin for spermatocytic seminoma

In mammals, spermatogenesis is maintained throughout life by a small subpopulation of type A spermatogonia called spermatogonial stem cells (SSCs). In rodents, SSCs, or Asingle spermatogonia, form the self-renewing population. SSCs can also divide into Apaired (Apr) spermatogonia that are predestined to differentiate. Apaired spermatogonia produce chains of Aaligned (Aal) spermatogonia that divide to form A1 to A4, then type B spermatogonia. Type B spermatogonia will divide into primary spermatocytes that undergo meiosis. In human, there are only two different types of A spermatogonia, the Adark and Apale spermatogonia. The Adark spermatogonia are considered reserve stem cells, whereas the Apale spermatogonia are the self-renewing stem cells. There is only one generation of type B spermatogonia before differentiation into spermatocytes, which makes human spermatogenesis less efficient than in rodents. Although the biology of human SSCs is not well known, a panel of phenotypic markers has recently emerged that is remarkably similar to the list of markers expressed in mice. One such marker, the orphan receptor GPR125, is a plasma membrane protein that can be used to isolate human SSCs. Human SSCs proliferate in culture in response to growth factors such as GDNF, which is essential for SSC self-renewal in mice and triggers the same signalling pathways in both species. Therefore, despite differences in the spermatogonial differentiation scheme, both species use the same genes and proteins to maintain the pool of self-renewing SSCs within their niche. Spermatocytic seminomas are mainly found in the testes of older men, and they rarely metastasize. It is believed that these tumours originate from a post-natal germ cell. Because these lesions can express markers specific for meiotic prophase, they might originate from a primary spermatocyte. However, morphological appearance and overall immunohistochemical profile of these tumours indicate that the cell of origin could also be a spermatogonial stem cell.

Isolation of enriched carp spermatogonial stem cells from Labeo rohita testis for in vitro propagation

The in vitro culture system for spermatogonial stem cells (SSCs) is a powerful tool for exploring molecular mechanisms of male gametogenesis and gene manipulation. Very little information is available for fish SSC biology. Our aim was to isolate highly pure SSCs from the testis of commercially important farmed carp, Labeo rohita. The minced testis of L. rohita was dissociated with collagenase. Dissociated cells purified by two-step Ficoll gradient centrifugation followed by magnetic activated cell sorting (MACS) using Thy1.2 (CD90.2) antibody dramatically heightened recovery rate for spermatogonial cells. The purified cells were cultured in vitro conditions for more than two months in L-15 media containing 10% fetal bovine serum (FBS), 1% carp serum, and other nutrients. The proliferative cells were dividing as validated by 5-bromo-2′-deoxyuridine (BrdU) incorporation assay and formed colonies/clumps with the typical characteristics of SSCs A majority of enriched cell population represented a Vasa+, Pou5f1/pou5f1+, Ssea-1+, Tra-1-81+, plzf+, Gfrα1/gfrα1−, and c-Kit/c-kit− as detected by immunocytochemical and/or quantitative real-time polymerase chain reaction (RT-PCR) analyses. Thus, Thy1+ SSCs were enriched with greater efficiency from the mixed population of testicular cells of L. rohita. A population of enriched spermatogonial cells could be cultured in an undifferentiated state. The isolated SSCs could provide avenue for undertaking research on basic and applied reproductive biology.

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.

Spermatogonial stem cell biology in the bull: development of isolation, culture, and transplantation methodologies and their potential impacts on cattle production

Widespread adoption of artificial insemination as a breeding practice has allowed for expanded use of desirable genetics from specific sires and greatly influenced production traits in dairy cattle populations worldwide. In fact, the average dairy cow in the US in 2009 produced 4.5 times more milk than in 1940 when commercialization of artificial insemination began. While many factors have contributed to this rapid increase in levels of milk production, genetic gain through expanded utilization of germlines from specific sires has been a major contribution. In comparison, use of artificial insemination in beef cattle populations has been limited due to challenges with implementing intensive management strategies required for success. Thus, there is need for alternative reproductive tools to expand use of desirable male genetics in the beef cattle industry. The process of sperm production, termed spermatogenesis, is supported by a tissue-specific stem cell population referred to as spermatogonial stem cells (SSCs). These unique cells have the capacity for infinite self-renewal and long-term regeneration of spermatogenesis following transplantation. In rodents, methods for isolating, culturing, and transplanting SSCs have been devised. For beef cattle, transplanting SSCs isolated from a donor male into the testes of recipient males in which donor-derived spermatogenesis occurs and offspring with donor genetics are produced from natural breeding has great potential as an alternative to artificial insemination. This potential reproductive strategy would allow for expansive use of genetics from desirable sires that overcomes the logistical challenges of artificial insemination. Translation of the methods devised for rodents to cattle is at the forefront of development. Devising means for isolating an SSC-enriched cell fraction from donor testes and identifying conditions that support long-term maintenance and proliferation of bovine SSCs in vitro are two tools that would greatly accelerate the pace at which transplantation will become a commercially viable option for cattle industries. Recent studies showed that expression of THY1 by SSCs is a conserved phenotype between rodents and cattle, and selection of the THY1 + fraction from donor testes can be used for isolating an SSC-enriched germ cell population. In addition, the conditions devised for expanding the number of rodent SSCs in vitro continues to serve as the basis for developing conditions that support bovine SSCs. With these tools in hand major advances in developing implementable reproductive tools with SSCs for commercial cattle production will be made in the coming decade.

A New and Fast Technique to Generate Offspring after Germ Cells Transplantation in Adult Fish: The Nile Tilapia (Oreochromis niloticus) Model

BackgroundGerm cell transplantation results in fertile recipients and is the only available approach to functionally investigate the spermatogonial stem cell biology in mammals and probably in other vertebrates. In the current study, we describe a novel non-surgical methodology for efficient spermatogonial transplantation into the testes of adult tilapia (O. niloticus), in which endogenous spermatogenesis had been depleted with the cytostatic drug busulfan.Methodology/Principal FindingsUsing two different tilapia strains, the production of fertile spermatozoa with donor characteristics was demonstrated in adult recipient, which also sired progeny with the donor genotype. Also, after cryopreservation tilapia spermatogonial cells were able to differentiate to spermatozoa in the testes of recipient fishes. These findings indicate that injecting germ cells directly into adult testis facilitates and enable fast generation of donor spermatogenesis and offspring compared to previously described methods.ConclusionTherefore, a new suitable methodology for biotechnological investigations in aquaculture was established, with a high potential to improve the production of commercially valuable fish, generate transgenic animals and preserve endangered fish species.

Development of a Short-Term Fluorescence-Based Assay to Assess the Toxicity of Anticancer Drugs on Rat Stem/Progenitor Spermatogonia In Vitro1

In vitro culture of rodent spermatogonial stem cells (SSCs) has become an important asset in the study of mammalian SSC biology. Supported by added growth factors, SSCs divide in culture and form aggregates of stem/progenitor spermatogonia, termed clusters. Recent studies have shown that serial passaging of clusters results in long-term maintenance and amplification of the SSC pool and that this culture system can also be used for short-term semiquantification of SSC activity. Here, we report the development of an automated assay to assess the activity of rat stem/progenitor spermatogonia in vitro and its application for investigating the cytotoxicity of chemotherapeutic drugs on these cells. Cultures of EGFP-expressing rat spermatogenic cells allowed us to determine the number and two-dimensional surface area of clusters using an automated fluorescence imaging system, thereby providing quantitative data of SSC activity. Using this assay, we examined the germ cell toxicity of three drugs that are routinely used in testicular cancer therapy, namely, bleomycin, cisplatin, and etoposide, alone and in combination. All three drugs showed a significant and dose-dependent reduction of cluster number and surface area, indicating their adverse effects specific to spermatogonia. The inhibitory concentration at which cluster number and surface area are inhibited by 50% (IC(50)) was the lowest with etoposide and the highest with cisplatin, implying that etoposide was most toxic to spermatogonia in vitro. These results suggest that the SSC culture should provide an effective and efficient system to assess the germ cell toxicity of various drugs and chemical compounds.