Superoxide dismutase activity along rat seminiferous epithelial wave: effects of ethane dimethanesulphonate and 3.0 Gy of X—irradiation

Summary. Changes in generation of reactive oxygen species and antioxidant enzyme activities are associated with differentiation processes. The authors have studied the activity of superoxide dismutase (SOD) in sequentially cut stage-defined segments of rat seminiferous tubules. Great variation was observed in SOD activity along the seminiferous epithelial wave. At its highest, fourfold increases were observed in individual tubules. However, these changes showed no clear correlation to the stages of the cycle. To determine the effect of testosterone withdrawal, rats treated with ethane dimethanesulphonate (EDS) were studied. This treatment had no effect on the pattern of SOD activity along the seminiferous epithelial wave. Testes of other rats were exposed to local 3.0 Gy X—irradiation to cause selective loss of germ-cell populations. SOD activity in the seminiferous epithelium was not affected at 30 min or 7 d after X—irradiation. On day 31 post-irradiation, SOD activity increased at stages XIV-VI, peaking at stage III ( P < 0.01 for comparison of stages XIV-VI with the other stages). The data presented here suggest that the activity of SOD in seminiferous epithelium is regulated over a wide range during spermatogenesis. Testosterone plays no major role in the control of seminiferous tubule SOD activity. The loss of spermatocytes and early spermatids by day 31 after X-irradiation revealed a stage-specific increase in SOD activity, which may be associated with the differentiation of elongated spermatids.     

Stage-specific degeneration of germ cells in the seminiferous tubules of non-obese diabetic mice

The cause of fertility problems in insulin-dependent diabetes is largely unknown. To evaluate the role of autoimmunity-associated phenomena in the testis as a possible cause of the derangement in spermatogenesis, the stage-specific apoptosis of germ cells in the insulitis phase of pre-diabetes was quantified in the testes of non-obese diabetic (NOD) mice. The seminiferous epithelium of normal BALB/c and NOD mice contained cells positive for in-situ end-labelling (ISEL) of DNA. ISEL-positive germ cells formed clusters in the seminiferous epithelium of the NOD mice in marked contrast to the seminiferous epithelium of the BALB/c mice, which contained only individual cells positive for ISEL. ISEL-positive cells were present in the basal and luminal compartments of the epithelium. Ultrastructural analysis and demonstration of externalized phosphatidyl serine confirmed that the cells were undergoing apoptosis. The ultrastructurally apoptotic cells included spermatogonia, spermatocytes and spermatids. In cytological squash preparations of segments of seminiferous tubules from NOD mice aged 17–20 weeks, the number of ISEL-positive cells/mm tubule was significantly lower in segments at stages I–II of the seminiferous epithelial wave but higher at stages III–IV in comparison to BALB/c mice. The numbers of ISEL-positive cells/mm tubule in the other stages were similar in the two strains of mice. Analysis of ³²P-3' -end labelled DNA from the testes showed that the BALB/c mice had relatively more DNA fragmentation than did the NOD mice. These data suggest that autoimmune insulitis in the NOD mice is associated with increased amounts and abnormal stage distribution of apoptosis in the seminiferous epithelium, resulting in derangement of spermatogenesis.     

Relative Positions of the Spermatogenic Stages in the Mouse Testis: Morphological Evidences for their Non-Randomized Adjacencies

The topographical distribution pattern of the stages of the murine seminiferous epithelium cycle was investigated. PAS-hematoxylin stained testicular sections from adult mice representative of the apical, equatorial and caudal region of both testes, were used. The relative frequencies (RF) of the stages of the seminiferous epithelium cycle was estimated on the basis of more than 10,000 cross-sectioned seminiferous tubules identified according to the criteria of Leblond and Clermont (1952). It was found that in the testicular sections the stages of adjacent seminiferous tubules are not distributed randomly. The comparison of the RF of the stages (calculated over all the testicular sections) with the RF of the stages that are adjacent to a given seminiferous tubule stage suggests a clustered occurrence of numerically identical stages. These comparisons very often show statistically significant differences. The finding of such associations among adjacent segments of seminiferous tubules (stages) suggest the existence of an ordered distribution of the seminiferous tubules inside the testis possibly controlled by substances with local control capacity of spermatogenesis. On the basis of the findings here presented, it is suggested an interpretation of the phenomenon of modulations of the waves of the seminiferous epithelium.     

The effect of selective destruction and regeneration of rat Leydig cells on the intratesticular distribution of testosterone and morphology of the seminiferous epithelium

This study was designed to explore the relationship between the intratesticular distribution of testosterone and spermatogenesis by completely destroying the Leydig cells of mature male rats with injection of a single i.p. dose of ethane dimethanesulphonate. After such treatment, testosterone levels in serum, testicular interstitial fluid, seminiferous tubules, and whole testis declined significantly 6 to 24 hours after injection and fell below assay detection limits between 3 and 7 days. At 3 and 7 days, serum LH and FSH levels rose significantly and remained elevated up to 4 and 6 weeks, respectively, in comparison with vehicle-treated controls. Leydig cells disappeared from the interstitium by day 3, but between 2 and 4 weeks postinjection a new generation of fetal-like Leydig cells repopulated the testicular interstitium and, during weeks 6 to 10, were transformed into, or replaced by, Leydig cells with an adult type of morphology. Histologic examination of the seminiferous tubules showed progressive disruption of spermatogenesis between 3 and 14 days post-ethane dimethanesulphonate. The first histologic sign of spermatogenic damage was noted at day 3, with the occurrence of stage-specific degenerating pachytene primary spermatocytes at stages VII to VIII of the spermatogenic cycle. On day 7, these cells and degenerating round, or step 19, spermatids often were observed during stages VII to XI, although qualitatively normal spermatogenesis also was seen in these and all other stages of the cycle. Maximum impairment of spermatogenesis occurred 2 weeks post-ethane dimethane sulphonate, at which time the tubules commonly lacked one or more germ cell generations or, alternatively, showed accumulation of lipid inclusions, extracellular spaces, and variable numbers of degenerating germ cells. Following repopulation of the testis by Leydig cells during weeks 3 and 4, spermatogenesis recovered. By 10 weeks after treatment, qualitatively normal spermatogenesis was seen in the great majority of seminiferous tubules, although a few tubules still remained in which the germ cell complement was severely reduced, and contained only Sertoli cells and spermatogonia.(ABSTRACT TRUNCATED AT 400 WORDS)     

Evaluation of the effect of selective germ cell depletion on subsequent spermatogenesis and fertility in the rat

Rats were treated with a single high dose of methoxy acetic acid (MAA; 650 mg/kg) specifically to deplete seminiferous tubules of pachytene and later spermatocytes. The impact of this selective depletion on subsequent spermatogenesis, sperm output and fertility was then evaluated at intervals ranging from 3 days to 10 weeks. Cauda epididymal sperm number was reduced progressively beyond 2 weeks post-treatment and reached a nadir at 5-6 weeks (28-34% of control values) before recovering progressively back to control levels at 10 weeks. Sperm motility was reduced significantly at 4-7 weeks post-treatment with a nadir at 6 weeks (35% of control values). Thus, at 5-6 weeks after MAA treatment, motile sperm output was reduced by 82-88%. Despite these changes, there was little evidence for infertility in the majority of treated males during a serial mating trial. Evaluation of seminiferous tubule morphology combined with germ cell counts at stage VII of the spermatogenic cycle confirmed that, initially, MAA induced the specific loss of pachytene and later spermatocytes at all stages other than early to mid stage VII. Maturation depletion of germ cells at later intervals was consistent with the initial effects of MAA, although at 21 days post-treatment a number of unpredicted (? secondary) changes in spermatogenesis were observed. These were (a) a reduction in number of pachytene spermatocytes at late stage VII/early stage VIII, (b) retention of sperm at stages IX-XIV, and (c) increased degeneration of pachytene spermatocytes and round spermatids at stage VII and of secondary spermatocytes at stages XIV-I. Whilst none of these changes was severe, together they probably accounted for the unexpectedly prolonged drop in sperm output. It is concluded that whilst deleterious changes in spermatogenesis may occur secondarily following MAA treatment, for the most part spermatogenesis proceeds normally and fertility is largely maintained despite a massive but transient decrease in sperm output.     

Dibromoacetic acid, a prevalent by-product of drinking water disinfection, compromises the synthesis of specific seminiferous tubule proteins following both in vivo and in vitro exposures.

Dibromoacetic acid (DBA) is a by-product of drinking water disinfection that alters spermatogenesis in adult male rats. To identify a mechanism by which DBA alters spermatogenesis, seminiferous tubules representing specific groups of spermatogenic stages were exposed either in vivo or in vitro, and structural and functional consequences were evaluated. Seminiferous tubules representing stages I-V, VI-VIII, and IX-XIV were isolated from testes of adult rats and cultured overnight in conditions of reduced oxygen and temperature. For in vivo exposures, seminiferous tubules were recovered from animals that had received 250 mg/kg DBA via gavage for 5 days. For in vitro exposures, 180 and 600 microM concentrations were tested; these concentrations bracket the concentration of DBA observed within the testis following in vivo exposure. Protein synthesis was evaluated by 35S-methionine labeling overnight and quantitative analysis of radiolabeled proteins in mini, 2-dimensional (2D) sodium dodecyl sulfate-polyacrylamide gel electrophoresis gels. Radio-inert cultures were processed for light and electron microscopy. Morphologicaf evaluation indicated that all spermatogenic stages of the seminiferous tubules from control animals were well maintained during the isolation and culture period. Although no treatment-related lesions were observed following in vivo exposure, histological alterations were observed at the lowest in vitro exposure. There was a significant diminution (P < .05) in the synthesis of 4 cytosolic proteins following both in vivo and in vitro exposures. Diminution in these proteins was restricted to stages I-V and IX-XIV of spermatogenesis, suggesting that proteins involved in the early stages of spermiogenesis are uniquely sensitive to DBA exposure. Because histology and protein synthesis were affected by relevant in vitro exposures, this indicates that DBA is capable of altering spermatogenesis directly.     

Lepidium meyenii （Maca） reduces spermatogenic damage induced by a single dose of malathion in mice

AIM: To observe the effect of the aqueous extract of hypocotyls of the plant Lepidium meyenii (Maca) on spermatogenic damage induced by the organophosphate insecticide malathion in mice. METHODS: Mice were treated with 80 mg/kg of malathion in the presence or absence of an aqueous extract of Maca, which was orally administered 7, 14 or 21 days after injection of the malathion. Stages of the seminiferous epithelium were assessed by transillumination on days 0, 7, 14 and 21. RESULTS: The administration of Maca increased significantly the length of stage VIII on days 7, 14 and 21 of treatment compared with the controls. An increase in the length of stage IX occurred on day 14 of treatment. Malathion affected spermatogenesis by reducing the lengths of stage IX on day 7, stages VII and IX-XI on day 14 and a recovery of stages IX-XII on day 21. The magnitude of alteration in the length of stage IX produced by malathion was significantly reduced by Maca on days 7 and 14. The length of stage VIII was increased when Maca was administered to mice treated with malathion. Assessment of the relative length of stages of the seminiferous epithelium showed that Maca treatment resulted in rapid recovery of the effect of malathion. CONCLUSION: Maca enhances spermatogenesis following spermatogenic damage caused by the organophosphorous pesticide.     

Transillumination to evaluate spermatogenesis: effect of testosterone enanthate in adult male rats

The present study has been designed to determine which stages of seminiferous cycle were modified by in vivo intramuscular administration of one or two doses of 25 mg of testosterone enanthate. Testicular weight was significantly reduced after treatment with two doses of testosterone enanthate (p < .05). Assessment of total lengths of stages per 100 mm of seminiferous tubules scored by transillumination showed that testosterone enanthate increased significantly the length of stages VI-VII, but it reduced total lengths of stages I, XII, and XIII-XIV. A dose-dependent reduction in the absolute and relative frequency of stage I was observed with testosterone enanthate treatment, whereas stages VI-VII were significantly increased. Analysis of relative frequencies of stages showed that stages XIII-XIV and stages I-V were significantly below the control value (1), whereas stages VI-VIII were over 1. In summary, results of the present study showed that transillumination is an adequate technique to assess the effect of drugs on spermatogenesis, and that testosterone enanthate modifies the pattern of the stages of the seminiferous epithelium cycle, before testicular weight is affected.     

Testosterone and spermatogenesis. Identification of stage-specific, androgen-regulated proteins secreted by adult rat seminiferous tubules.

The aim of this study was to identify potential androgen-regulated proteins (ARP) that might mediate the supportive effects of testosterone on spermatogenesis. Adult rats were injected with ethane dimethane sulphonate (EDS) to destroy Leydig cells and thus induce complete testosterone withdrawal. Other EDS-treated rats were injected with 25 mg testosterone esters (TE) every 3 days to maintain quantitatively normal spermatogenesis. A timeframe for the study of androgen action on spermatogenesis was deduced from enumeration of degenerating germ cells at stage VII of the spermatogenic cycle in perfusion-fixed testes from rats in the early stages (4 to 8 days) after EDS treatment. Based on this data and changes in testicular interstitial fluid volume, long seminiferous tubule segments were isolated from control rats and from EDS-treated rats (+/- TE-supplementation) at stages II-V, VI-VIII, or IX-XII, 2 days to 6 days after EDS treatment. Seminiferous tubule segments were incubated for 22 hours with 60 microCi 35S-labelled methionine. Incorporation into newly synthesized proteins in the seminiferous tubule culture medium (= secreted proteins) or in seminiferous tubule lysates (= intracellular proteins) was determined by trichloroacetic acid-precipitation followed by analysis using two-dimensional sodium dodecylsulfate polyacrylamide gel electrophoresis. In control rats, incorporation of 35S-methionine into proteins secreted by isolated seminiferous tubules was more than twice as great at stages VI-VIII than at stages II-V or IX-XII. This doubling in methionine incorporation into stages VI-VIII secreted proteins was abolished, however, 4 days after EDS treatment (when germ cell degeneration at stage VII was only just evident). A similar change occurred 4 days after testosterone withdrawal induced by immunoneutralization of luteinizing hormone. In the latter case and after EDS treatment, TE-supplementation of rats from day 0 maintained the normal control pattern of methionine incorporation into seminiferous tubule secreted proteins, although 6 days after EDS and TE treatment, incorporation into stages VI-VIII secreted proteins was 19% lower (P less than 0.05) than in the control group. In contrast, incorporation of methionine into proteins secreted by seminiferous tubules at stages II-V and IX-XII was unaffected by EDS and TE pretreatment, as was incorporation into intracellular proteins at all stages.(ABSTRACT TRUNCATED AT 400 WORDS)     

Spermatogonial stem cells alone are not sufficient to re-initiate spermatogenesis in the rat testis following adjudin-induced infertility

The blood-testis barrier (BTB) is a unique ultrastructure in the testis, which creates a specialized microenvironment in the seminiferous epithelium known as the apical (or adluminal) compartment for post-meiotic germ-cell development and for maintenance of an immunological barrier. In this study, we have demonstrated unequivocally that a functional and intact BTB is crucial for the initiation of spermatogenesis, in particular, the differentiation of spermatogonial stem cells (SSCs). It was shown that adult rats (～300 g body weight, b.w.) treated with adjudin at 50 (low-dose) or 250 (high-dose) mg/kg b.w. by gavage led to germ-cell depletion from the seminiferous tubules and that >98% of the tubules were devoid of germ cells by ～2 week and rats became infertile in both groups after the sperm reserve in the epididymis was exhausted. While the population of SSC/spermatogonia in the seminiferous tubules from both groups was similar to that of normal rats, only rats from the low-dose group were capable of re-initiating spermatogenesis; and by 20 weeks, greater than 75% of the tubules displayed normal spermatogenesis and the fertility of these rats rebounded. Detailed analysis by dual-labelled immunofluorescence analysis and a functional BTB integrity assay revealed that in both treatment groups, the BTB was disrupted from week 6 to week 12. However, the disrupted BTB 'resealed' in the low-dose group, but not in the high-dose group. Our findings illustrate that SSC/spermatogonia failed to differentiate into spermatocytes beyond A(aligned) spermatogonia in the high-dose group with a disrupted BTB. In short, these findings illustrate the critical significance of the BTB for re-initiation of spermatogenesis besides SSC and spermatogonia.     

Acute effects and long-term sequelae of 1,3-dinitrobenzene on male reproduction in the rat. II. Quantitative and qualitative histopathology of the testis

This study determined the quantitative and qualitative histopathologic effects of a single oral dose of 1,3-dinitrobenzene (48 mg/kg) on the rat testis from 1 to 175 days postexposure. The testis was damaged severely by hour 24, as evidenced by increased numbers of regressive seminiferous tubules that exhibited degenerating pachytene spermatocytes, chromatin margination in spermatids, giant cells, deformed spermatid heads, retained spermatids, and reduced numbers of meiotic figures. The major effects during the first 48 hours posttreatment were degeneration or exfoliation of pachytene spermatocytes and round spermatids and the retention of step 19 spermatids. These regressive effects continued until 24 days, after which the tubules either recovered or became atrophic. At the end of the study (175 days), three males were normal, one had regressed testicles, and three males had atrophic tubules (15 to 45%). Several cellular abnormalities were common throughout the period. In addition, the frequency of the stages of spermatogenesis was altered, an indication of a disturbance in the kinetics of spermatogenesis. 1,3-Dinitrobenzene produced profound and specific lesions in the seminiferous tubules, and recovery was slow and incomplete. Atrophic tubules seemed to form if the normal cellular associations were not reestablished within 24 days, possibly due to the inability of Sertoli cells to reorganize the synchrony of germ cell development.     

Quantitative analysis of spermatogenic DNA synthesis in the rat using a monoclonal anti-5-bromodeoxyuridine antibody

Summary. The utility of the 5-bromodeoxy-uridine (BrdUrd) labelling technique for the quantitative analysis of spermatogenic deoxyribonucleic acid (DNA) synthesis was investigated in the rat. Rat testicles were labelled by a single intraperitoneal injection of 100 mg kg⁻¹ of BrdUrd. The testicles were removed 1 h after injection, fixed in Bouin's fluid and embedded in paraffin. BrdUrd-labelled cells were detected by immunohistochemical staining using a monoclonal anti-BrdUrd antibody. The number of BrdUrd-labelled tubules per total number of tubules (percent L.T.), the number of BrdUrd-labelled cells per total number of tubules (tubular ratio) and the number of BrdUrd-labelled cells per number of Sertoli cells (Sertoli cell ratio in BrdUrd-labelled cells) were calculated as indices of spermatogenic DNA synthesis during each stage of the seminiferous epithelial wave. BrdUrd labelling was found exclusively in the nuclei of spermatogonia and in preleptotene spermatocytes in the seminiferous epithelium. The percent L.T. was generally greater than 50%, except in stages VI, VII and XIV, and the tubular as well as Sertoli cell ratios in BrdUrd-labelled cells was greater than 2.0 and 0.15, respectively, in stages I, II-III, V, VIII, X, and XII. The tubular ratio and Sertoli cell ratio in BrdUrd-labelled cells along the seminiferous epithelial wave had two distinct peaks. The distribution of the tubular ratio using the BrdUrd-labelling technique correlated well with the distribution previously established by measuring tritiated thymidine uptake per tubule. Thus, the BrdUrd labelling technique, which is more efficient than the tritiated thymidine labelling technique, can be used to quantitatively evaluate spermatogenic DNA synthesis.     

Spermatogenese

Spermatogenesis takes place within the testicular seminiferous tubules which consist of the peritubular lamina propria and the seminiferous epithelium. The latter is composed of germ cells and somatic Sertoli cells. Sertoli cells trigger germ cell development by mediating follicle-stimulating hormone and androgen hormonal stimuli. Spermatogenesis comprises proliferation of spermatogonia, meiosis of spermatocytes, and differentiation of spermatids into spermatozoa (spermiogenesis). There are six distinct and specific germ cell associations (I–VI). These “stages of spermatogenesis” occur sequentially along the length of a tubule. Different defects in spermatogenesis occur in adjacent seminiferous tubules (mixed atrophy) and are associated with deficits in differentiation of Sertoli cells. Biopsy specimens should be fixed in Bouin’s solution. Diagnosis of preinvasive carcinoma in situ is based on the immunohistochemical demonstration of placental-like alkaline phosphatase (PLAP), which is expressed exclusively in carcinoma in situ cells. Histological evaluation should be performed using a score count system, and the use of histological techniques for protein and mRNA expression. Testicular biopsy should only be performed in accordance with strict indication criteria, and histological evaluation should be carried out in specialist centres, i.e. as recommended by the European Academy of Andrology (EAA).     

Spermatogenesis--physiology and pathophysiology

Spermatogenesis takes place within the testicular seminiferous tubules which consist of the peritubular lamina propria and the seminiferous epithelium. The latter is composed of germ cells and somatic Sertoli cells. Sertoli cells trigger germ cell development by mediating follicle-stimulating hormone and androgen hormonal stimuli.Spermatogenesis comprises proliferation of spermatogonia, meiosis of spermatocytes, and differentiation of spermatids into spermatozoa (spermiogenesis). There are six distinct and specific germ cell associations (I-VI). These "stages of spermatogenesis" occur sequentially along the length of a tubule. Different defects in spermatogenesis occur in adjacent seminiferous tubules (mixed atrophy) and are associated with deficits in differentiation of Sertoli cells. Biopsy specimens should be fixed in Bouin's solution. Diagnosis of preinvasive carcinoma in situ is based on the immunohistochemical demonstration of placental-like alkaline phosphatase (PLAP), which is expressed exclusively in carcinoma in situ cells. Histological evaluation should be performed using a score count system, and the use of histological techniques for protein and mRNA expression. Testicular biopsy should only be performed in accordance with strict indication criteria, and histological evaluation should be carried out in specialist centres, i.e. as recommended by the European Academy of Andrology (EAA).     

Development of stage-specific paracrine regulation of Leydig cells by the seminiferous tubules

The size of peritubular Leydig cells surrounding tubules in different stages of the spermatogenic cycle was determined in 43- and 47-day-old male rats. A stage-dependent variation in the size of peritubular Leydig cells was not present in 43-day-old rats, but by 47 days those Leydig cells closely adjacent to tubules at stages VII-VIII were larger than others. At 43 days of age spermatogenesis had developed up to step 18 spermatids in late stage VI tubules. At 47 days of age the first mature sperm had just been released from the seminiferous epithelium, and consequently the first wave of the spermatogenic cycle was completed. Tubules at stages VII-VIII therefore acquire the ability to influence surrounding Leydig cells when they contain step 19 spermatids. It remains to be shown whether this maturation step is due to inherent maturation of the Sertoli cells or if step 19 spermatids specifically modulate Sertoli cell function.     

Expression of the integrin subunits alpha 5, alpha 6 and beta 1 in the testes of the common marmoset

Integrin subunits alpha 5, alpha 6 and beta 1 were localized in the testis of pre-pubertal or adult non-human primates (Callithrix jacchus) by immunofluorescence staining and in situ hybridization. In animals of all ages subunits alpha 5 and beta 1 were localized in cells of the lamina propria of the seminiferous epithelium. In prepubertal animals, the integrin subunits alpha 5, alpha 6, as well as beta 1, were distributed all over the plasma membrane of Sertoli cells. In adult animals the integrin subunits were confined to those plasma membrane regions of Sertoli cells which are assigned to the basal compartment, including the basement membrane of the seminiferous tubules. Protein expression of integrin subunits alpha 6 and beta 1 was most pronounced in tubular stages in which elongated spermatids were not yet present in the adluminal compartment of the epithelium, suggesting that these integrin subunits are particularly essential at certain developmental stages of spermatogenesis. Non-radioactive in situ hybridization revealed that the mRNA for integrin subunits alpha 5, alpha 6 and beta 1 was expressed by Sertoli cells. In situ hybridization, together with immunofluorescence data, shows that these integrin subunits were exclusively synthesized in Sertoli cells. As to functional aspects, it is concluded that during primate spermatogenesis. Sertoli cell integrins may be involved in both cell matrix as well as cell-cell interactions, particularly during early spermatogenesis.     

Application of three-dimensional culture systems to study mammalian spermatogenesis,with an emphasis on the rhesus monkey (Macaca mulatta)

In vitro culture of spermatogonial stem cells (SSCs) has generally been performed using two-dimensional (2D) culture systems; however, such cultures have not led to the development of complete spermatogenesis. It seems that 2D systems do not replicate optimal conditions of the seminiferous tubules (including those generated by the SSC niche) and necessary for spermatogenesis. Recently, one of our laboratories has been able to induce proliferation and differentiation of mouse testicular germ cells to meiotic and postmeiotic stages including generation of sperm in a 3D soft agar culture system (SACS) and a 3D methylcellulose culture system (MCS). It was suggested that SACS and MCS form a special 3D microenvironment that mimics germ cell niche formation in the seminiferous tubules, and thus permits mouse spermatogenesis in vitro. In this review, we (1) provide a brief overview of the differences in spermatogenesis in rodents and primates, (2) summarize data related to attempts to generate sperm in vitro, (3) report for the first time formation of colonies/clusters of cells and differentiation of meiotic (expression of CREM-1) and postmeiotic (expression of acrosin) germ cells from undifferentiated spermatogonia isolated from the testis of prepubertal rhesus monkeys and cultured in SACS and MCS, and (4) indicate research needed to optimize 3D systems for in vitro primate spermatogenesis and for possible future application to man.     

Computer tracking of germ cells in the cycle of the seminiferous epithelium and prediction of changes in cycle duration in animals commonly used in reproductive biology and toxicology.

A computer program called Stages was written to aid the tracking of germ cells and stages forward and backward through time in the cycle of the seminiferous epithelium. The program incorporates the basic kinetics of spermatogenesis in the rat, mouse, hamster, guinea pig, dog, rabbit, bull, stallion, ram, boar, quail, monkey, and man. The program is flexible and permits the user to alter the cycle duration time and the frequency of each stage. Compiled for use on personal computers and available on floppy disks free of charge, Stages is menu-driven and requires no knowledge of programming. The program was tested using published data of testicular toxicity and vitamin A synchronization of stages. In general, predicted cell types were similar to those observed; discrepancies between observed and predicted data are discussed. When cycle duration time was changed, predicted data for stage synchronization coincided with the observed data. This program will improve the speed and accuracy of studying factors that affect spermatogenesis. By using Stages, it is possible to predict the target cell types in a toxicity study and to track affected cells over long periods of time. Predicted cell types may also indicate which cells to examine biochemically as well as morphologically in subsequent experiments. The program will also be useful to beginning students learning the complex patterns of cellular associations and the progression of germ cells in the cycle of the seminiferous epithelium.     

In vitro differentiation of rat seminiferous tubular segments from defined stages of the epithelial cycle morphologic and immunolocalization analysis

Rat seminiferous tubule segments have been cultured in chemically defined medium (F12/DMEM 1:1) without added hormones or growth factors. The segments (1-2 mm) were isolated from defined stages of the cycle of the seminiferous epithelium (VIII and XII) by transillumination-assisted microdissection. The precise stages were examined by phase contrast microscopy of live cells squashed carefully out from the adjacent segments between glass slides. The squash technique was also used for a primary screening of the cultured tubules. Pachytene primary spermatocytes from stages VIII to XII of the cycle were able to complete meiotic divisions in vitro. From stage XII, they differentiated up to step 5 spermatids, expressed their specific antigens, and developed characteristic movement patterns of the flagellum and of the chromatoid body. Preleptotene and zygotene spermatocytes from the same cell association differentiated synchronously, as judged by chromosome morphology, characteristic chromosome rotation in zygotene and early pachytene, and by development of specific antigen expression. The elongation phase of spermiogenesis did not proceed normally in vitro. The rate of differentiation was the same as observed earlier in vivo. Earlier studies with [3H]thymidine labeling and autoradiography only permitted follow-up of the development of preleptotene spermatocytes. With the present method, all stages of spermatogenesis can be traced in culture with great accuracy in experiments relating to local regulation of spermatogenesis.