Recombinant human insulin-like growth factor I stimulates all stages of 11-ketotestosterone-induced spermatogenesis in the Japanese eel, Anguilla japonica, in vitro.

In this study, we examined the in vitro effects of insulin-like growth factor I (IGF-I) in the presence or absence of 11-ketotestosterone (11-KT: the spermatogenesis-inducing hormone) on the proliferation of Japanese eel (Anguilla japonica) testicular germ cells. Initially, a short-term culture (15 days) of testicular tissue with only type A and early type B spermatogonia (preproliferated spermatogonia) was carried out in Leibovitz-15 growth medium supplemented with different concentrations of recombinant human IGF (rhIGF)-I or -II in the presence or absence of 10 ng/ml of 11-KT. Late type B spermatogonia (proliferated spermatogonia) were observed in treatments of 100 ng/ml of both rhIGF-I and -II in combination with 11-KT, indicating the onset and progression of spermatogenesis. In all tested rhIGF-I concentrations (except 0.1 ng/ml) supplemented with 11-KT, late type B spermatogonia were detected in at least one individual. Then, we proceeded with an in vitro 45-day culture of testicular tissue with 100 ng/ml of rhIGF-I in the presence or absence of 10 ng/ml of 11-KT to test the long-term effects of rhIGF-I on the spermatogenetic cycle. The presence of all types of germ cells, including spermatozoa, in the testis cultured with the admixture of the two hormones indicated that the germ cells underwent complete spermatogenesis whereas no germ cell proliferation was observed when the rhIGF-I was applied alone. These results suggest that IGF-I in the presence of 11-KT plays an essential role in the onset, progress, and regulation of spermatogenesis in the testis of the Japanese eel.     

Human chorionic gonadotropin induces all stages of spermatogenesis in vitro in the male Japanese eel (Anguilla japonica)

In the cultivated male Japanese eel, spermatogonia are the only germ cells present in the testis. Using a newly developed organ culture system, we obtained evidence that human chorionic gonadotropin (HCG) can induce the entire process of spermatogenesis, in vitro, from spermatogonia to spermatozoa within 24 days. The HCG-induced spermatogenesis in vitro was accompanied by a marked activation of Sertoli cells and Leydig cells, occurring prior to the beginning of spermatogonial proliferation. These results indicate that gonadotropin triggers spermatogenesis in the Japanese eel and further suggest that this effect of gonadotropin is mediated through the actions of testicular somatic cells.     

Follicle-stimulating hormone induces spermatogenesis mediated by androgen production in Japanese eel, Anguilla japonica

Follicle-stimulating hormone (FSH) plays important roles in spermatogenesis. However, the biologic activity of FSH can vary in different vertebrate classes, and the definitive function of FSH has not been established. In this study, we investigated the functions of FSH on spermatogenesis using an in vitro culture system for Japanese eel testis. The eel Fsh receptor was expressed in testis tissue during the whole process of spermatogenesis, mainly by Leydig cells that produce steroid hormones and by Sertoli cells surrounding type A spermatogonia and early type B spermatogonia. In an in vitro organ culture, recombinant eel Fsh (r-eFsh) induced complete spermatogenesis from the proliferation of spermatogonia to spermiogenesis during 36 days of culture; also, spermatozoa were observed in the testicular fragments. Spermatogenesis induced by r-eFsh was inhibited by trilostane, a specific inhibitor of 3beta-hydroxysteroid dehydrogenase. However, trilostane did not inhibit spermatogenesis induced by 11-ketotestosterone. These results clearly show that the main function of FSH in eel is to induce spermatogenesis via stimulating androgen production.     

Spermatogenesis and related plasma androgen levels in Atlantic halibut (Hippoglossus hippoglossus L.)

Spermatogenesis in male Atlantic halibut (Hippoglossus hippoglossus L.) was investigated by sampling blood plasma and testicular tissue from 15-39-month-old fish. The experiment covered a period in which all fish reached puberty and completed sexual maturation at least once. The germinal compartment in Atlantic halibut testis appears to be organized in branching lobules of the unrestricted spermatogonial type, because spermatocysts with spermatogonia were found throughout the testis. Spermatogenesis was characterized histologically, and staged according to the most advanced type of germ cell present: spermatogonia (Stage I), spermatogonia and spermatocytes (Stage II), spermatogonia, spermatocytes and spermatids (Stage III), spermatogonia, spermatocytes, spermatids and spermatozoa (Stage IV), and regressing testis (Stage V). Three phases could be distinguished: first, an initial phase with low levels of circulating testosterone (T; quantified by RIA) and 11-ketotestosterone (11-KT; quantified by ELISA), spermatogonial proliferation, and subsequently the initiation of meiosis marked by the formation of spermatocytes (Stage I and II). Secondly, a phase with increasing T and 11-KT levels and with haploid germ cells including spermatozoa present in the testis (Stage III and IV). Thirdly, a phase with low T and 11-KT levels and a regressing testis with Sertoli cells displaying signs of phagocytotic activity (Stage V). Circulating levels of 11-KT were at least four-fold higher than those of T during all stages of spermatogenesis. Increasing plasma levels of T and 11-KT were associated with increasing testicular mass throughout the reproductive cycle. The absolute level of, or the relation between, testis growth and circulating androgens were not significantly different in first time spawners compared to fish that underwent their second spawning season. These results provide reference levels for Atlantic halibut spermatogenesis.     

A rapid activation of immature testis of Japanese eel (Anguilla japonica) by a single injection of human chorionic gonadotropin

The testis of Japanese eel (Anguilla japonica) consists of type A and early type B spermatogonia together with inactive Leydig and Sertoli cells. A single injection of human chorionic gonadotropin induced marked changes in the morphology of the testis and in the serum androgen levels within a period of 72 h. Morphological changes include spermatogonial proliferation, activation of Leydig and Sertoli cells, organization of seminiferous lobules and formation of lobular lumen in the testis. Leydig cells were enlarged, exhibiting characteristics of steroid-producing cells. Sertoli cells become elongated, show signs of high cellular activity and remain in close contact with spermatogonia. The lobular organization was achieved much earlier than the progression of spermatogenesis to late type B spermatogonia. Even 6 h after hCG injection, a significant increase in plasma levels of 11-ketotestosterone was observed, followed by a further time dependent increase. Plasma testosterone levels were also increased after injection, but the increase was much less than that of 11-ketotestosterone.     

Trout sertoli and leydig cells: Isolation,separation, and culture

Trout testes at various stages of maturation were dissociated by perfusion at 12°C with collagenase plus pronase and then with collagenase alone, followed by slight shaking overnight in 1% bovine albumin. This step provided a suspension of isolated somatic and germ cells, clusters of interstitial cells, and either intact spermatogenetic cysts (meiotic testes) or clusters of Sertoli cells (other testes). Most of the spermatozoa were removed from the testis cell suspension by centrifugation in Percoll (density 1.065 g/ml). Sertoli and Leydig cells were prepared by a two-step separation method: (1) the testis cell suspension was separated by sedimentation at unit gravity into “isolated cell” and “cell cluster” populations; (2) these populations were fractionated by isopyknic centrifugation in Percoll gradients. In terms of somatic cell composition, a nearly pure Sertoli cell (clusters) population was obtained between 1.017 and 1.033 g/ml and a Leydig cell (clusters) enriched population of between 1.033 and 1.048 g/ml (testes resuming spermatogenesis) or 1.048 and 1.062 g/ml (other testes). These various cell populations were cultured in modified Leibovitz L15 medium for 10–15 days. When seeded, the Sertoli cells had a normal ultrastructure that remained unchanged for at least 10 days, and the steroidogenic activity of Leydig cells could be stimulated by salmon gonadotropin. Leydig cells remained 3β-HSD positive and produced progesterone and 17α, 20β-OH progesterone for at least 11 days. This study points out that viable and differentiated trout somatic testicular cells can be prepared and cultured for several days.     

Spermatogenesis-preventing substance in Japanese eel

Under fresh-water cultivation conditions, spermatogenesis in the Japanese eel is arrested at an immature stage before initiation of spermatogonial proliferation. A single injection of human chorionic gonadotropin can, however, induce complete spermatogenesis, which suggests that spermatogenesis-preventing substances may be present in eel testis. To determine whether such substances exist, we have applied a subtractive hybridisation method to identify genes whose expression is suppressed after human chorionic gonadotropin treatment in vivo. We found one previously unidentified cDNA clone that was downregulated by human chorionic gonadotropin, and named it 'eel spermatogenesis related substances 21' (eSRS21). A homology search showed that eSRS21 shares amino acid sequence similarity with mammalian and chicken Müllerian-inhibiting substance. eSRS21 was expressed in Sertoli cells of immature testes, but disappeared after human chorionic gonadotropin injection. Expression of eSRS21 mRNA was also suppressed in vitro by 11-ketotestosterone, a spermatogenesis-inducing steroid in eel. To examine the function of eSRS21 in spermatogenesis, recombinant eSRS21 produced by a CHO cell expression system was added to a testicular organ culture system. Spermtogonial proliferation induced by 11-ketotestosterone in vitro was suppressed by recombinant eSRS21. Furthermore, addition of a specific anti-eSRS21 antibody induced spermatogonial proliferation in a germ cell/somatic cell co-culture system. We conclude that eSRS21 prevents the initiation of spermatogenesis and, therefore, suppression of eSRS21 expression is necessary to initiate spermatogenesis. In other words, eSRS21 is a spermatogenesis-preventing substance.     

Impaired spermatogenesis in the Japanese eel, Anguilla japonica: Possibility of the existence of factors that regulate entry of germ cells into meiosis

In the cultivated male Japanese eel, spermatogonia are the only germ cells present in the testis. Weekly injections of human chorionic gonadotropin (HCG) can induce complete spermatogenesis from proliferation of spermatogonia to spermiogenesis. In some cases, however, HCG injection fails to induce complete spermatogenesis. Testicular morphological observations revealed that HCG-injected eels could be classified into three types based on their testicular conditions. Type 1 eels had a well-developed testis and the milt could be acquired by hand-stripping. In type 2 eels, spermatogenesis was also induced by HCG injection, but testicular size was remarkably smaller than that of type 1 eels, and the milt could not be hand-stripped. At the end of the experiment, type 2 fish had only spermatogonia and a small amount of spermatozoa, but no spermatocytes or spermatids, in their testis. Type 3 eels had thready testis, which did not develop any germ cells during the experimental period. These results suggest that, despite elevations of plasma 11–ketotestosterone levels, HCG injections were not successful in inducing the completion of spermatogenesis in type 2 and type 3 eels. In most spermatogonia of type 2 eels, meiosis was not induced by HCG injections. Furthermore, only few mitotic divisions had occurred as evidenced by the presence of 2³ to 2⁶ late type B spermatogonia in most cysts. This suggests that spermatogonial stem cells undergo four or five, and occasionally six, mitotic divisions before the interruption of spermatogenesis in type 2 eels. It is proposed that those numbers of mitotic divisions are related to a mediator that regulates entry of spermatogonia of the Japanese eel into meiosis.     

Cultivation of boar spermatogonia on Sertoli cells

We studied the in vitro effect of Sertoli cells on boar spermatogonia isolated from the testes of 60-day-old crossbred boars. In order to enrich the culture with spermatogonia, the cells were purified by density gradient centrifugation with the use of Percoll gradient followed by separation based on adhesive capacities of cells. We found lipid drops stained by Oil Red O in Sertoli cells. The experiments showed that the cultivation of boar spermatogonia in the presence of Sertoli cells (for up to 35 days) provide the same way of differentiation as in testes in natural conditions. After 10 days of cultivation, spermatogenic cells form groups, chains, and suspension clusters. By this time, spermatogenic colonies are formed; we analyzed the expression of Nanog and Plzf genes in these colonies by real-time PCR. The expression rate of Nanog gene in experimental cell clones obtained by the short-term cultivation of spermatogonia cells in the presence of Sertoli cells was 200 times higher than in freshly isolated spermatogonia cells. The product of Plzf gene expression was found both in freshly isolated spermatogenic cells and in cell clones obtained in vitro. After long-term cultivation of spermatogonia on Sertoli cells, we observed in vitro differentiation to the lineage of spermatogenesis and formation of separate motile sperm cells after 30–33 days. At this stage, the cell population was heterogeneous. In the absence of Sertoli cells, the differentiation of boar spermatogonia cells in culture stopped after 7 days of cultivation. The data show that the cultivation of boar spermatogonia cells on Sertoli cells contributes to their in vitro differentiation to the lineage of spermatogenesis and can help to obtain boar sperm cell culture.     

Potency of testicular somatic environment to support spermatogenesis in XX/Sry transgenic male mice

The sex-determining region of Chr Y (Sry) gene is sufficient to induce testis formation and the subsequent male development of internal and external genitalia in chromosomally female mice and humans. In XX sex-reversed males, such as XX/Sry-transgenic (XX/Sry) mice, however, testicular germ cells always disappear soon after birth because of germ cell-autonomous defects. Therefore, it remains unclear whether or not Sry alone is sufficient to induce a fully functional testicular soma capable of supporting complete spermatogenesis in the XX body. Here, we demonstrate that the testicular somatic environment of XX/Sry males is defective in supporting the later phases of spermatogenesis. Spermatogonial transplantation analyses using XX/Sry male mice revealed that donor XY spermatogonia are capable of proliferating, of entering meiosis and of differentiating to the round-spermatid stage. XY-donor-derived round spermatids, however, were frequently detached from the XX/Sry seminiferous epithelia and underwent cell death, resulting in severe deficiency of elongated spermatid stages. By contrast, immature XY seminiferous tubule segments transplanted under XX/Sry testis capsules clearly displayed proper differentiation into elongated spermatids in the transplanted XY-donor tubules. Microarray analysis of seminiferous tubules isolated from XX/Sry testes confirmed the missing expression of several Y-linked genes and the alterations in the expression profile of genes associated with spermiogenesis. Therefore, our findings indicate dysfunction of the somatic tubule components, probably Sertoli cells, of XX/Sry testes, highlighting the idea that Sry alone is insufficient to induce a fully functional Sertoli cell in XX mice.     

Excess type I interferon signaling in the mouse seminiferous tubules leads to germ cell loss and sterility

Type I (α and β) interferons (IFNs) elicit antiproliferative and antiviral activities via the surface receptor IFNAR. Serendipitous observations in transgenic mice in 1988 strongly suggested that IFNα/β overexpression in the testis disrupts spermatogenesis. Here, we compare a new mouse strain transgenic for IFNβ (Tg10) and a sister strain lacking the IFNAR1 subunit of IFNAR (Tg10-Ifnar1(-/-)), both strains expressing the transgene in the testis. The main source of IFNβ RNA was the spermatid population. Importantly, the Tg10 mice, but not the double mutant Tg10-Ifnar1(-/-), showed altered spermatogenesis. The first IFNAR-dependent histological alteration was a higher apoptosis index in all germ cell categories apart from non-dividing spermatogonia. This occurred 3 weeks after the onset of IFNβ production at postnatal day 20 and in the absence of somatic cell defects in terms of cell number, expression of specific cell markers, and hormonal activities. Several known interferon-stimulated genes were up-regulated in Tg10 Sertoli cells and prepachytene germ cells but not in pachytene spermatocytes and spermatids. In concordance with this, pachytene spermatocytes and spermatids isolated from wild-type testes did not display measurable amounts of IFNAR1 and phosphorylated STAT1 upon IFNβ challenge in vitro, suggesting hyporesponsiveness of these cell types to IFN. At day 60, Tg10 males were sterile, and Sertoli cells showed increased amounts of anti-Mullerian hormone and decreased production of inhibin B, both probably attributable to the massive germ cell loss. Type I interferon signaling may lead to idiopathic infertilities by affecting the interplay between germ cells and Sertoli cells.     

Biochemical analysis of programmed cell death during premeiotic stages of spermatogenesis in vivo and in vitro

Control points of regulator action during spermatogenesis are not completely known. Using the shark testis model, which facilitates analysis of spermatogenesis stage-by-stage in vivo and in vitro, an early biochemical marker of programmed cell death (PCD) was detected. Nucleosomal oligomers were seen in DNA extracts of testis and isolated spermatocysts (clonal germ cell/ Sertoli cell units) at premeiotic (PrM), but not meiotic (M) or postmeiotic (PoM), stages. Cell nuclei isolated from M stages of development were susceptible to cleavage by micrococcal nuclease, suggesting that developmental control of factors other than a nuclease-insensitive chromatin structure may account for stage specificity. Cytological features of apoptosis were seen in germ cells, but not Sertoli cells, of a subset of isolated PrM spermatocysts and appeared to be all-or-none in affected clones. In culture, DNA fragmentation occurred on schedule with or without various additives, but the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine (IBMX) decreased accumulation of DNA breakdown products. Identification of the apoptotic form of PCD as a major, variable component of normal spermatogenesis and the use of PrM spermatocysts as an in vitro test system will allow further definition of mechanisms and developmental and physiological controls. © 1995 Wiley-Liss, Inc.     

Survival and proliferation of rat gonocytes in vitro

Quiescent gonocytes were isolated from fetal testes of rat 18-day post coitum and cultured alone or on monolayers of somatic cells from different origins. The gonocytes specifically adhered to Sertoli cells, isolated from 21 to 23-day-old rat testes; this adherence was necessary for their survival in vitro. Addition of follicle-stimulating hormone and testosterone to these cultures did not increase the viability of the gonocytes. Serum was found to be deleterious to the germ cells. Electron-microscopic examination of Sertoli-cell-gonocyte co-cultures revealed the presence of numerous adhesion plaques between these cells, indicating that Sertoli cells and gonocytes are able to communicate in vitro. Gonocytes, in co-culture with Sertoli cells, were viable for at least 9 days. The gonocytes did not spontaneously resume proliferation. The simple culture system described in the present paper should be useful in studying the nature of the factors that are responsible for sending the quiescent gonocytes into the cell cylce and for stimulating the formation of A spermatogonia, a process characterizing the start of spermatogenesis.     

Connexin 43 a potential regulator of cell proliferation and apoptosis within the seminiferous epithelium

The gap junction proteins, connexins (Cx), are present in the testis and among them Cx43 play an essential role in spermatogenesis. By using an in vitro proliferation model of germ cells and Sertoli cells, we tempted here to clarify the role of Cx43 in the control of Sertoli and germ cell proliferation and apoptosis. Cx43 was detected in purified preparations of Sertoli cells and spermatogonia and immunolocalized in both cell types identified by vimentin and c-kit, respectively. Inhibition of gap junction coupling by the gap junction inhibitor α-GA significantly enhanced BrdU incorporation in Sertoli cells and reduced the number of activated caspase-3 positive germ cells. Similarly, inhibitory Cx43 and pan-Cx mimetic inhibitory peptides increased proliferation of Sertoli cells and stimulated survival of germ cells. Cx32 mimetic inhibitory peptide also stimulated Sertoli cell proliferation without altering germ cell proliferation and apoptosis. The present results reveal that Cx43 gap junctions between Sertoli cells participate in the control of Sertoli cell proliferation and that Cx43 gap junctions between Sertoli cells and spermatogonia are indirectly involved in germ cell number increase by controlling germ cell survival rather than germ cell proliferation.     

Overexpression of ubiquitin carboxyl-terminal hydrolase L1 arrests spermatogenesis in transgenic mice

Ubiquitin carboxyl-terminal hydrolase 1 (UCH-L1) can be detected in mouse testicular germ cells, mainly spermatogonia and somatic Sertoli cells, but its physiological role is unknown. We show that transgenic (Tg) mice overexpressing EF1alpha promoter-driven UCH-L1 in the testis are sterile due to a block during spermatogenesis at an early stage (pachytene) of meiosis. Interestingly, almost all spermatogonia and Sertoli cells expressing excess UCH-L1, but little PCNA (proliferating cell nuclear antigen), showed no morphological signs of apoptosis or TUNEL-positive staining. Rather, germ cell apoptosis was mainly detected in primary spermatocytes having weak or negative UCH-L1 expression but strong PCNA expression. These data suggest that overexpression of UCH-L1 affects spermatogenesis during meiosis and, in particular, induces apoptosis in primary spermatocytes. In addition to results of caspases-3 upregulation and Bcl-2 downregulation, excess UCH-L1 influenced the distribution of PCNA, suggesting a specific role for UCH-L1 in the processes of mitotic proliferation and differentiation of spermatogonial stem cells during spermatogenesis.     

Identification, isolation, and in vitro culture of porcine gonocytes

Gonocytes are primitive germ cells that reside in the seminiferous tubules of neonatal testes and give rise to spermatogonia, thereby initiating spermatogenesis. Due to a lack of specific markers, the isolation and culture of these cells has proven to be difficult in the pig. In the present study, we show that a lectin, Dolichos biflorus agglutinin (DBA), which has specific affinity for primordial germ cells (PCGs) in the genital ridge, binds specifically to gonocytes in neonatal pig testes. The specific affinity of DBA for germ cells was progressively lost with age. This suggests that DBA binds strongly to primitive germ cells, such as gonocytes, weakly to primitive spermatogonia, and not at all to spermatogonia. The presence of alkaline phosphatase (AP) activity in the germ cells of neonatal pig testis confirmed the existence of primitive germ cells. Gonocytes from neonatal pig testis were purified, and a cell population that consisted of approximately 70% gonocytes was obtained, as indicated by the DBA binding assay. Purified gonocytes were cultured in DMEM/F12 supplemented with 10% FBS in the absence of any specific growth factors for 7 days. The cells remained viable and proliferated actively in culture. Initially, the gonocytes grew as focal colonies that transformed to three-dimensional colonies by 7 days of culture. Cultured germ cells expressed SSEA-1, a marker for embryonic stem (ES) cells, and were negative for the expression of somatic cell markers. These results should help to establish a male germ cell line that could be used for studying spermatogenesis in vitro and for genetic modification of pigs.     

Comparative studies between in vivo and in vitro spermatogenesis of Japanese eel (Anguilla japonica)

In order to check the quality of in vitro spermatogenesis of Japanese eel, in vitrol 1-ketotestosterone (11-KT) induced spermatogenesis was compared with in vivo spermatogenesis induced by a single injection of human chorionic gonadotropin (hCG) in detail. DNA contents of germ cells from in vitro and in vivo testicular fragments were compared using flow cytometry. Since the in vitro result of flow cytometry showed prominent 1C peak including spermatozoa and spermatids, the reduction of DNA by meiosis was assumed to progress normally, (i.e., haploid spermatozoa were produced in this in vitro system). In the testes of in vitro culture, however, spermatozoa were not released into lumen. Furthermore, the number of mitotic divisions of the in vitro experiment (6 divisions) was fewer than that of in vivo (10 divisions). In electron microscopy observations, both of in vivo and in vitro spermatozoon had a crescent-shaped nucleus with a flagellum, and a single large spherical mitochondrion. However, the elongation of the sperm head was not sufficient and the mitochondrion was not always located at the anterior end as is observed for the spermatozoa obtained from hCG injected eels. Eel spermatogenesis related substance-11 (eSRS11) is homologue of histone H1 which is up-regulated during spermatogenesis. Using this probe, in vitro spermatogenesis was also evaluated in molecular levels. In Northern blot analysis, eSRS11 mRNA was detected in both in vivo and in vitro testes. However, the expression of in vitro was much weaker than that of in vivo. These differences indicate that the stimulation of 11-KT is not sufficient, and another factors are needed to induce complete spermatogenesis in vitro.