Change in expression of a 90-kDa glycoprotein GP90-MC301 during prenatal and postnatal testicular development: a differentiation marker for rat germ cells

GP90-MC301, a 90-kDa glycoprotein recognized by the monoclonal antibody MC301, is a reliable stage-specific marker for preleptotene to pachytene spermatocytes in adult rat testes. In this study we confirmed that the glycoprotein is also useful as a marker for germ cells in prenatal and postnatal testes. Immunohistochemical analysis showed a dramatic change in GP90-MC301 expression in germ cells during testis development. Strong expression was detected in primordial germ cells at embryonic day (E) 13 and in gonocytes at E16, and the expression was then markedly reduced at around the time (E18) gonocytes undergo G1/G0 arrest, and was not restored in gonocytes or spermatogonia afterward. Thereafter, it reappeared in primary spermatocytes in the prepubertal period. Testicular somatic cells such as Sertoli cells, Leydig cells, and peritubular myoid cells expressed GP90-MC301 during specific periods which were largely correlated with periods of active proliferation of these testicular somatic cells. Western blotting showed that GP90-MC301 was expressed during testis development without a change in its molecular size. Thus, GP90-MC301 is potentially useful for the analysis of not only spermatogenesis but also early testis development.     

Effects of different Sertoli cell types on the maintenance of adult spermatogonial stem cells in vitro

Spermatongonial stem cells (SSCs) are unique testis cells that are able to proliferate, differentiate, and transmit genetic information to the next generation. However, the effect of different Sertoli cell types on the expression of specific SSC genes is not yet well understood. In this study, we compare the in vitro effect of adult Sertoli cells, embryonic Sertoli cells, and TM4 (a Sertoli cell line) as feeder layers on the expression of SSC genes. SSCs were isolated from the testis of adult male mice and purified by differential plating. Following enrichment, SSCs were cultivated for 1 and 2 wk in the presence of various feeders. The expression of SSC-specific genes (Mvh, ZBTB, and c-kit) was evaluated by real-time polymerase chain reaction. Our results revealed that expression of the specific SSC genes was significantly higher in the embryonic Sertoli cells after 1 and 2 wk compared to the adult Sertoli cells and the TM4 group. Our finding suggest that co-culturing of SSCs with embryonic Sertoli cells is helpful for in vitro cultivation of SSCs and might improve the self-renewal of these stem cells.     

Gene expression profiling revealed specific spermatogonial stem cell genes in mouse

Mammalian spermatogenesis originates from spermatogonial stem cells (SSCs), which undergo mitosis, meiosis and spermiogenesis in order to generate mature spermatozoa. SSCs are adult stem cells that can both self‐renew and differentiate. To maintain pluripotency, SSCs are regulated by both extrinsic factors secreted from surrounding somatic cells and intrinsic factors including specific gene expression programs. Using fluorescent labeled germ line stem cells, mouse gonocytes and SSCs were purified up to 97% by improved FACS method. Through microarray analyses, global gene expression profiles of gonocytes, SSCs, and differentiated cells were compared. A large number of distinctive genes were found to be enriched in respective cell populations, indicating different functional requirements of each cell type. Functional clustering analyses revealed that while gonocytes and SSCs preferentially express genes implicated in gene expression regulation and epigenetic modifications, differentiated cells including somatic cells are enriched with genes encoding proteins involved in various cellular activities. Further in situ hybridization and RT‐PCR experiments confirmed SSC specific expression of several genes of which functions have not been characterized in SSCs. The comparative gene expression profiling provides a useful resource for gene discovery in relation to SSC regulation and opens new avenues for the study of molecular mechanisms underlying SSC self‐renewal and differentiation. genesis 51:83–96, 2013. © 2012 Wiley Periodicals, Inc.     

Asymmetric Distribution of UCH‐L1 in Spermatogonia Is Associated With Maintenance and Differentiation of Spermatogonial Stem Cells

Asymmetric division of germline stem cells in vertebrates was proposed a century ago; however, direct evidence for asymmetric division of mammalian spermatogonial stem cells (SSCs) has been scarce. Here, we report that ubiquitin carboxy‐terminal hydrolase 1 (UCH‐L1) is expressed in type A (A_s, A_pr, and A_al) spermatogonia located at the basement membrane (BM) of seminiferous tubules at high and low levels, but not in differentiated germ cells distant from the BM. Asymmetric segregation of UCH‐L1 was associated with self‐renewal versus differentiation divisions of SSCs as defined by co‐localization of UCH‐L1^high and PLZF, a known determinant of undifferentiated SSCs, versus co‐localization of UCH‐L1^low/? with proteins expressed during SSC differentiation (DAZL, DDX4, c‐KIT). In vitro, gonocytes/spermatogonia frequently underwent asymmetric divisions characterized by unequal segregation of UCH‐L1 and PLZF. Importantly, we could also demonstrate asymmetric segregation of UCH‐L1 and PLZF in situ in seminiferous tubules. Expression level of UCH‐L1 in the immature testis where spermatogenesis was not complete was not affected by the location of germ cells relative to the BM, whereas UCH‐L1‐positive spermatogonia were exclusively located at the BM in the adult testis. Asymmetric division of SSCs appeared to be affected by interaction with supporting somatic cells and extracelluar matrix. These findings for the first time provide direct evidence for existence of asymmetric division during SSCs self‐renewal and differentiation in mammalian spermatogenesis. J. Cell. Physiol. 220: 460–468, 2009. © 2009 Wiley‐Liss, Inc.     

Spermatogonial stem cells in the testis of an endangered bovid: Indian black buck (Antilope cervicapra L.)

Numerous wild bovids are facing threat of extinction owing to the loss of habitat and various other reasons. Spermatogonial stem cells (SSCs) represent the only germline stem cells in adult body that are capable of self-renewal and that can undergo differentiation to produce haploid germ cells. SSCs can, therefore, serve as a useful resource for preservation of germplasm of threatened and endangered mammals. The Indian black buck (Antilope cervicapra L.) is a small Indian antelope that is listed as endangered by the Indian Wildlife Protection Act, 1972. Immunohistochemical analysis of testes tissues of black buck revealed the presence of spermatogonia that were specifically stained by lectin-Dolichos biflorus agglutinin (DBA). The expression of pluripotent cell-specific markers, NANOG and stage-specific embryonic antigen-1 (SSEA-1), was detected in spermatogonia. Interestingly, the expression of POU5F1 (OCT3/4) was absent from spermatogonia, however, it was detected in differentiating cells such as spermatocytes and round spermatids but not in elongated spermatids. The expression of NANOG protein was also present in spermatocytes but absent in round and elongated spermatids. Using the testis transplantation assay, stem cell potential of black buck spermatogonia was confirmed as indicated by the presence of colonized DBA-stained cells in the basal membrane of seminiferous tubules of xenotransplanted mice testis. The findings from this study suggest the presence of SSCs in the testis of an endangered bovid for the first time and open new possibility to explore the use of SSCs in conservation.     

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.     

Involvement of the D-type cyclins in germ cell proliferation and differentiation in the mouse

Using immunohistochemistry, the expression of the D-type cyclin proteins was studied in the developing and adult mouse testis. Both during testicular development and in adult testis, cyclin D(1) is expressed only in proliferating gonocytes and spermatogonia, indicating a role for cyclin D(1) in spermatogonial proliferation, in particular during the G(1)/S phase transition. Cyclin D(2) is first expressed at the start of spermatogenesis when gonocytes produce A(1) spermatogonia. In the adult testis, cyclin D(2) is expressed in spermatogonia around stage VIII of the seminiferous epithelium when A(al) spermatogonia differentiate into A(1) spermatogonia and also in spermatocytes and spermatids. To further elucidate the role of cyclin D(2) during spermatogenesis, cyclin D(2) expression was studied in vitamin A-deficient testis. Cyclin D(2) was not expressed in the undifferentiated A spermatogonia in vitamin A-deficient testis but was strongly induced in these cells after the induction of differentiation of most of these cells into A(1) spermatogonia by administration of retinoic acid. Overall, cyclin D(2) seems to play a role at the crucial differentiation step of undifferentiated spermatogonia into A(1) spermatogonia. Cyclin D(3) is expressed in both proliferating and quiescent gonocytes during testis development. Cyclin D(3) expression was found in terminally differentiated Sertoli cells, in Leydig cells, and in spermatogonia in adult testis. Hence, although cyclin D(3) may control G(1)/S transition in spermatogonia, it probably has a different role in Sertoli and Leydig cells. In conclusion, the three D-type cyclins are differentially expressed during spermatogenesis. In spermatogonia, cyclins D(1) and D(3) seem to be involved in cell cycle regulation, whereas cyclin D(2) likely has a role in spermatogonial differentiation.     

NOTCH signaling in Sertoli cells regulates gonocyte fate

Gonocytes (or prospermatogonia) are the precursors to spermatogonial stem cells (SSCs), which provide the foundation for spermatogenesis through their ability to both self-renew and generate daughter cells. Despite their relative importance, the regulatory mechanisms that govern gonocyte maintenance and transition to SSCs are poorly understood. Recently, we reported that constitutive activation of NOTCH1 signaling in Sertoli cells causes gonocyte exit from quiescence—the first suggestion of the potential role of this signaling pathway in the testis.

This Extra View will review what is known about NOTCH signaling, particularly in Sertoli cells and germ cells in the testes, by providing a background on germ cell biology and a summary of our recently published data on NOTCH1 signaling in Sertoli cells. We also describe additional data showing that aberrant proliferation and differentiation of gonocytes in response to constitutive activation of NOTCH1 signaling in Sertoli cells involves de novo expression of cell cycle proteins and a marked upregulation of the KIT receptor. These data further suggest that NOTCH signaling orchestrates a dynamic balance between maintenance and differentiation of gonocytes in the perinatal testis.     

Expression patterns of germ line specific genes in mouse and human pluripotent stem cells are associated with regulation of ground and primed state of pluripotency

One of the main criteria of pluripotency is ability of cell lines to differentiate into the germ line. Pluripotent stem cell lines in ground state of pluripotency differ from the lines in primed state by their ability to give rise to the mature gametes. To understand molecular mechanisms involved in regulation of different states of pluripotency we investigated the expression patterns of germ line specific genes in different type pluripotent stem cells and mouse and human embryonic teratocarcinoma cells. We found that pluripotent stem cells in vitro, in blastocyst and gonocytes at stage E13.5 had similar expression patterns in contrast to the epiblast cells at stage E6.5. Quantitative real time PCR analysis showed that Vasa/Ddx4 expression in mouse and human embryonic stem cells was significantly lower than in blastocyst and gonocytes. Moreover, Vasa/Ddx4 and E-ras expression was significantly higher in mouse embryonic stem cells than in human embryonic stem cells. Our analysis of germ line specific gene expression in differentiating mouse embryonic stem and embryonic germ cells as well as in mouse embryonic teratocarcinoma cells maintained under conditions promoting cell reprogramming from primed to ground state of pluripotency (2i + LIF) revealed that only pluripotent stem cells are able to regulate the expression level of Oct4 and Vasa/Ddx4 and restore initial ground state, while in embryonic teratocarcinoma cells the expression level of these genes remained unchanged. We suggest that expression patterns of germ lines specific genes, in particular of Vasa/Ddx4, can underlie the regulation of ground and primed states of pluripotency.     

Serial Enrichment of Spermatogonial Stem and Progenitor Cells (SSCs) in Culture for Derivation of Long-term Adult Mouse SSC Lines

Spermatogonial stem and progenitor cells (SSCs) of the testis represent a classic example of adult mammalian stem cells and preserve fertility for nearly the lifetime of the animal. While the precise mechanisms that govern self-renewal and differentiation in vivo are challenging to study, various systems have been developed previously to propagate murine SSCs in vitro using a combination of specialized culture media and feeder cells^1-3.Most in vitro forays into the biology of SSCs have derived cell lines from neonates, possibly due to the difficulty in obtaining adult cell lines⁴. However, the testis continues to mature up until ~5 weeks of age in most mouse strains. In the early post-natal period, dramatic changes occur in the architecture of the testis and in the biology of both somatic and spermatogenic cells, including alterations in expression levels of numerous stem cell-related genes. Therefore, neonatally-derived SSC lines may not fully recapitulate the biology of adult SSCs that persist after the adult testis has reached a steady state.Several factors have hindered the production of adult SSC lines historically. First, the proportion of functional stem cells may decrease during adulthood, either due to intrinsic or extrinsic factors^5,6. Furthermore, as with other adult stem cells, it has been difficult to enrich SSCs sufficiently from total adult testicular cells without using a combination of immunoselection or other sorting strategies⁷. Commonly employed strategies include the use of cryptorchid mice as a source of donor cells due to a higher ratio of stem cells to other cell types⁸. Based on the hypothesis that removal of somatic cells from the initial culture disrupts interactions with the stem cell niche that are essential for SSC survival, we previously developed methods to derive adult lines that do not require immunoselection or cryptorchid donors but rather employ serial enrichment of SSCs in culture, referred to hereafter as SESC^2,3.The method described below entails a simple procedure for deriving adult SSC lines by dissociating adult donor seminiferous tubules, followed by plating of cells on feeders comprised of a testicular stromal cell line (JK1)³. Through serial passaging, strongly adherent, contaminating non-germ cells are depleted from the culture with concomitant enrichment of SSCs. Cultures produced in this manner contain a mixture of spermatogonia at different stages of differentiation, which contain SSCs, based on long-term self renewal capability. The crux of the SESC method is that it enables SSCs to make the difficult transition from self-renewal in vivo to long-term self-renewal in vitro in a radically different microenvironment, produces long-term SSC lines, free of contaminating somatic cells, and thereby enables subsequent experimental manipulation of SSCs.     

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.     

Establishment of a proteomic profile associated with gonocyte and spermatogonial stem cell maturation and differentiation in neonatal mice

Initiation of the first wave of spermatogenesis in the neonatal mouse testis is characterized by differentiation of a transient population of germ cells called gonocytes in the center of the seminiferous tubules. After resuming mitotic activity, gonocytes relocate on the basement membrane, giving rise to spermatogonial stem cells (SSCs). These processes begin from birth in mice, and differentiated type A spermatogonia first appear by day 6 postpartum. During these processes, Sertoli cells within the seminiferous tubules and Leydig cells in the interstitial tissue form the stem cell “niche,” and influence SSC fate decisions. Thus, we collected whole mouse testis tissues during the first wave of spermatogenesis at specific time points (days 0.5, 1.5, 2.5, 3.5, 4.5, and 5.5 postpartum) and constructed a comparative proteomic profile. We identified 252 differentially expressed proteins classified into three clusters based on expression, and bioinformatics analysis correlated each protein pattern to specific cell processes. Expression patterns of nine selected proteins were verified via Western blot, and cellular localizations of three proteins with little known information in testes were further investigated during spermatogenesis. Taken together, the results provide an important reference profile of a functional proteome during neonatal mouse gonocyte and SSC maturation and differentiation.     

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.