Spermatogenic cycle length and spermatogenic efficiency in the gerbil (Meriones unguiculatus)

The gerbil (Meriones unguiculatus) is a rodent native of the arid regions of Mongolia and China. Because the gerbil can be easily bred in laboratory conditions, this species has been largely used as an experimental model in biomedical research. However, there is still little information concerning the testis structure and function in the gerbil. In this regard, we performed a detailed morpho-functional analysis of the gerbil testis and estimated the spermatogenic cycle length utilizing 3H-thymidine as a marker for germ cell progression during their evolution through the spermatogenic process. The stage frequencies of the XII stages characterized according to the acrosome formation and development were (I-XII) 13.8, 10.1, 8.1, 7.8, 4.0, 11.2, 7.5, 7.1, 5.9, 7.6, 8.1, and 8.9. The mean duration of each seminiferous epithelium cycle was determined to be 10.6 +/- 1.0 days and the total duration of spermatogenesis, based on 4.5 cycles, was approximately 47.5 days. The volume density of tubular and interstitial compartments was approximately 92% and 8%, respectively. Based on the volume occupied by seminiferous tubules in the testis and the tubular diameter, about 9 and 18 m of seminiferous tubules were found per testis and per gram of testis, respectively. Twelve primary spermatocytes were formed from each type A1 spermatogonia. The meiotic index was 2.8, indicating that 30% of cell loss occurs during meiosis. The number of Leydig and Sertoli cells per gram of the testis was 28 million and each Sertoli cell was able to support approximately 13 spermatids. The daily sperm production per gram of testis (spermatogenic efficiency) was 33 million. Taken together, these data indicate that, mainly due to the high seminiferous tubule volume density and Sertoli cell support capacity for germ cells, the gerbil presents high spermatogenic efficiency compared with other mammalian species already investigated. The data obtained in the present study might provide the basis for future research involving the reproductive biology in this species.     

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.     

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)     

The spermatogenic cycle in the blue fox (Alopex lagopus): relative frequency and absolute duration of the different stages

The spermatogenic cycle of the blue fox was divided into eight distinct stages, based on an analysis of different cell associations of the seminiferous epithelium. The criteria used for classification of the stages were the type of spermatogonia, the occurrence of meiotic figures, and the shape and location of spermatids. The relative frequencies of the stages I to VIII were 25.7, 9.8, 8.7, 5.9, 13.8, 9.9, 10.6 and 15.5%, respectively. The duration of one cycle of the seminiferous epithelium was 12.0 +/- 0.2 days as determined from the progression of 5-bromo-2-deoxyuridine (BrdU)-labelled cells at various time intervals. The absolute duration of stages I to VIII was calculated to be 3.1, 1.2, 1.0, 0.6, 1.7, 1.2, 1.3 and 1.9 days, respectively. The estimated life span of primary spermatocytes was 19.2 days, of secondary spermatocytes less than 0.6 days, of spermatids with round nuclei 9.2 days and of spermatids with elongated nuclei 8.9 days.     

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)     

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.     

Spermatogenesis in the immature mouse proceeds faster than in the adult

The first appearance of spermatogenic cell types related to the age of the animal was studied in sections and tubular whole mounts of testes of normal mice (Cpb-N strain) up to 34 days p.p. The first intermediate spermatogonia and leptotene spermatocytes were seen at days 4 and 7 p.p., respectively. It was found that the subsequent types of spermatogenic cells appear earlier than could be expected if spermatogenesis was to proceed at adult speed. [³H]thymidine labelling studies revealed that within a given interval of time, spermatocytes and spermatids in immature mice develop into more advanced cell types than in adults. The labelling studies and the observation that the cellular associations are always identical to those in the adult, indicate that the rate of acceleration in young mice is the same for spermatogonia, spermatocytes and spermatids. The mean duration of the cycle of the seminiferous epithelium during the age interval of 10 to 30 days p.p. is 7.51 pL 0.10 days, compared to 8.61 pL 0.08 in the adult. It increases gradually towards the adult level, reaching the value of 8.45 pL 0.17 days between days 33 and 56 p.p.     

Functional analysis of the cooled rat testis

Direct cooling of the testis results in the depletion of most germ cells in vivo. Germ cell-depleted testes are now commonly used to investigate spermatogenic regeneration and can serve as recipients for germ cell transplantation. The present study explored the effects of cooling rat testes on the depletion of endogenous germ cells, spermatogenic regeneration, and Sertoli cell function. Adult rat testes were cooled with iced Ringer's solution for 60 minutes, which results in the initiation of apoptotic germ cell loss within 8 hours. Pachytene spermatocytes at stages XII-I were the cells most sensitive to cooling. In 46%-67% of seminiferous tubule cross-sections, only Sertoli cells remained in the cooled testes 3-10 weeks after treatment. Germ cell loss was accompanied by a significant decrease in circulating inhibin B and an increase in follicle-stimulating hormone concentrations, which indicated a change in Sertoli cell function. Quantitative analysis of mRNA expression associated with apoptotic signals showed no significant uniform changes among the cooled testes, although some individuals had a distinct up-regulation of FAS mRNA at 24 hours. Attempts to use the cooled testes as recipient testes for mouse-to-rat germ cell transplantation were undertaken, but none of the mouse germ cells transplanted into the testes 15-34 days after cooling appeared to have undergone spermatogenesis 64-92 days after transplantation. These data suggest that modifications to Sertoli cell function resulting from testicular cooling create an environment that is unable to support spermatogenesis by donor germ cells.     

The selective removal of pachytene spermatocytes using methoxy acetic acid as an approach to the study in vivo of paracrine interactions in the testis

Testicular weight and morphology, serum gonadotropins, intratesticular levels of testosterone and ABP levels in testicular interstitial fluid were studied in adult rats at intervals of 1 to 70 days after a single oral dose of 650 mg/kg methoxy acetic acid. At 3 days, this treatment resulted in the selective loss or depletion of pachytene and later spermatocytes from seminiferous tubules at all stages other than VIII to XI of the spermatogenic cycle. At later times this lesion was expressed as an absence mainly of round (14 days) or elongated (21 days) spermatids from the majority of seminiferous tubules. Other than these changes, spermatogenesis did not appear to be affected by treatment and was qualitatively normal in all tubules at 70 days after treatment. As deduced from cell counts at 3 days posttreatment, the initial action of methoxy acetic acid was restricted to late zygotene spermatocytes (stage XII) and pachytene spermatocytes at all stages other than early- to mid-stage VII. Levels of FSH in serum and those of ABP in testicular interstitial fluid indicated that Sertoli cell function was altered in rats treated with methoxy acetic acid. Both were increased at 1 to 3 days posttreatment, returned to normal at 7 to 14 days but were increased again at 21 days before finally returning to control levels at 28 days. In contrast, the levels of testosterone in serum, isolated seminiferous tubules and testicular interstitial fluid were unaffected by treatment, as also were the serum levels of LH. The two periods of increase in FSH and ABP levels coincided with the times of greatest decrease (approximately 20%) in testicular weight, and may be related either to the type of germ cell missing from the affected tubules and/or to the stage of the cycle of the affected (or unaffected) tubules. These data suggest that chemicals such as methoxy acetic acid may prove useful in the study of paracrine interactions in vivo.     

Expression of beta-catenin in human testes with spermatogenic defects

beta-catenin is a multifunctional molecule that functions in intercellular adhesion and signal transduction during assembly of AJs between Sertoli cells as well as between Sertoli cells and germ cells. To assess changes in the testicular beta-catenin in male infertility conditions, testicular tissues from obstructive azoospermia with normal spermatogenesis, spermatogenic arrest (SA) and Sertoli cell-only syndrome (SCO) patients were examined for immunohistochemical localization of beta-catenin. In normal spermatogenic tissue, expression of beta-catenin was largely found in the Sertoli cell-germ cell (primarily spermatocytes) contact areas. Interestingly, perinuclear localization of beta-catenin was found in spermatocytes and spermatids. In spermatogenic arrest, beta-catenin in cell contact areas between Sertoli cells and germ cells was greatly decreased, but perinuclear beta-catenin in spermatocytes was not. In SCO, weak or negligible immunoreactivity of beta-catenin was found in cell contacts between Sertoli cells. Nuclear localization of beta-catenin was found in myotubular cells in all samples. Taken together, altered expression of beta-catenin in cell contacts within the seminiferous epithelia in spermatogenic arrest and SCO suggests that interactions between Sertoli cells and germ cell are crucial for expression of beta-catenin, and thus functional development of AJs in seminiferous epithelia in human testis. It should be also emphasized that perinuclear beta-catenin in germ cells may play a specific role in spermatogenesis.     

Quantitative morphology of the testicular tubular epithelium in the water buffalo (Bubalus bubalis).

Ultrastructural features and morphometric evaluations of water buffalo seminiferous epithelium are reported for the 6 phases of the spermatogenic cycle. The relative Sertoli cell volume varies between 30% (phase 4) and 39% (phase 8), the calculated volume of a Sertoli cell between 7118 microns3 and 8968 microns3 (phase 4). Smooth ER is the organelle that exhibits the most prominent changes in Sertoli cells during the spermatogenic cycle: it occupies about 6% in phase 3 and 21% in phase 4. All spermatogenic cells of the same clone present cytoplasmic bridges among them. From preleptotene (about 470 microns3) to late diplotene (about 2300 microns3) the volume of a primary spermatocyte increases nearly 5-fold; their nuclear volumes increase 3.5-fold in the same period. Secondary spermatocytes are found only in phase 4 of the cycle. Due to partial cell necrosis and autolysis late maturation phase spermatids display not more than 25% of the size of early cap phase spermatids. 63% of all numerically possible germ cells disappear from the seminiferous epithelium during spermatogenesis. Particularly heavy cell loss is observed in phase 4 and involves the spermatogonial fraction as well as cells during the second meiotic division.     

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.     

A stereological analysis of the response of spermatogenesis to an acute inflammatory episode in adult rats

Male fertility is inhibited by inflammatory disease, but the mechanisms responsible are poorly defined. The effects of acute systemic inflammation induced by a single IP injection of lipopolysaccharide (LPS) on spermatogenic function in adult male rats were investigated using detailed stereological analysis. The earliest effect observed was a significant maturational delay of meiosis during the leptotene/zygotene phase (at stages IX-XIII) within 24 hours. This was followed within 6 days by an increase in premature release of these cells and the adjacent, more luminally located generation of round spermatids from the seminiferous epithelium. An increase in germ cell apoptosis within stages IX-XIII also occurred at this time. These data indicate that the initial effects of acute inflammation on the seminiferous epithelium are most pronounced on stages IX-XIII. The effects were not consistent with a loss of hormonal regulation, suggesting that a direct effect of inflammation on the function of the Sertoli cell during this critical stage of meiosis is involved. In the longer term, however, the consequences of this acute inflammatory episode were relatively minor: within 28 days there had been a compensatory increase in the efficiency of the seminiferous epithelium, restoring the spermatogenic capacity of the testis towards preinflammation levels.     

The cycle of the seminiferous epithelium in humans: a need to revisit?

Understanding the dynamics of spermatogenesis is central to clinical andrology or to probing environmental effects on human testes. This review considers what is known about renewal and proliferation of spermatogonia, how germ cells are organized in cellular associations constituting the cycle of the seminiferous epithelium, relative frequencies of cellular associations, durations of the cycle of the seminiferous epithelium and spermatogenesis, and measurement of daily sperm production. Daily sperm production (DSP) per testis tends to decline with advancing age. Regardless of age, there is substantial loss of potential sperm from degeneration of spermatocytes, but not spermatids. DSP per gram testis parenchyma or DSP per testis cannot be predicted on the basis of testis size or age of a man. The review shows why our 1960s data base is neither robust nor precise and suggests how deficiencies might be rectified. New cellular associations should be defined, with none representing >15% of the cycle of the seminiferous epithelium. Then determine when A(pale)-spermatogonia become committed to proliferate or how many mitotic divisions occur thereafter. Restudy the duration of spermatogenesis because the accepted value might be in error by approximately 6 days. Restudying human spermatogenesis will benefit clinicians, toxicologists, and epidemiologists probing testis function by direct evaluations or indirectly via evaluations of quantity and quality of sperm ejaculated. It also will benefit scientists interested in renewal and proliferation of spermatogonia, or a spermatogonium as a prototype stem cell.     

In vivo analysis of germ cell apoptosis reveals the existence of stage-specific `social' control of germ cell death in the seminiferous epithelium

It has become clear in recent years that programmed cell death is regulated during development by signals from other cells. Nevertheless, compared to the `social' control of cell proliferation, relatively little is known about the `social' control of cell death in other systems. Since in a previous study we showed that induced germ cell apoptosis occurs at specific stages of the spermatogenic cycle, in this study we aimed to ascertain the existence of supracellular control of germ cell death during spermatogenesis. Therefore, the TUNEL technique has been used to analyse whether all of the different germ cell types are induced to die at these specific stages in animals injected intratesticularly with one of several inducers of apoptosis. Our findings suggest that all of the investigated agents trigger apoptosis in all the diverse progenies of germ cells existing at stages I, XII or XIV of the spermatogenic cycle. In contrast, at most other stages the number of apoptotic cells was similar to that found in control animals. These data are consistent with the existence of an intercellular control of germ cell death during spermatogenesis. We conclude that the seminiferous epithelium provides a suitable in vivo model to study the mechanisms underlying the `social' control of apoptosis.     

Evaluation of damage to the testicular cells of golden hamsters caused by experimental cryptorchidism using flow cytometry and confocal microscopy

Artificial unilateral cryptorchidism was performed in golden hamsters which were then held for different periods of time. The non-operated side was used as a control. At various times from 4 to 15 days, hamsters were killed, testes were removed and weighed, single cell suspensions were prepared for flow cytometry analysis and seminiferous tubules were fixed for confocal microscopy. Using DNA staining by propidium iodide or acridine orange followed by flow cytometry analysis, a marked decrease in the haploid condensed cell fraction was detected at the beginning stages of experimental cryptorchidism. In correlation with flow cytometry results, spermiogenic arrest at stages IX and X of seminiferous epithelium was detected in these animals by confocal microscopy and there were no mature forms of haploid cells in the cryptorchid testis. In the testis with more severe damage, there were almost no haploid cells in the seminiferous tubules of cryptorchid animals. In addition, a significant decrease in tetraploid cell fraction and an increase in S-phase fraction was obtained in severe cases. This may be explained by cell arrest before entrance into meiosis. Destruction of tubule structure and cell arrangement were also observed by confocal microscopy in such cases. In conclusion, flow cytometry, combined with confocal analysis, added useful information about spermatogenesis disturbances in cryptorchid testis and it may be used as diagnostic tools in other cases of spermatogenic disorders.     

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.     

Repeated interruptions of the testicular blood flow do not have long-term effects on spermatogenesis in the ram

Summary. The effect of repeated interruptions of the testicular blood flow on spermatogenesis was studied in mature Texel rams. Reversible interruption of the blood flow was achieved by an inflatable occluder, placed around the testicular artery at the level of the spermatic cord. In eight testes the blood flow was successfully interrupted six times for 1 h within 3 weeks and in 14 testes nine times for 1 h within 3 weeks. Nine weeks after the last blood flow interruption spermatogenesis was evaluated in histological sections of the testes. Both after six and nine blood flow interruptions a qualitatively complete epithelium was found in at least 90% of the seminiferous tubules. Cell counts in stages VII and VIII of the spermatogenic cycle revealed a slight decrease of spermatocytes and spermatids in the tubules with a complete epithelium after nine occlusions, which was only statistically significant for Preleptotene Spermatocytes. After six occlusions the numbers of all cell types were at or even slightly above control levels. These results show that repeated periods of ischaemia for 1 h do not result in conspicious long-term damage to spermatogenesis.     

Cellular regulation of follicle-stimulating hormone (FSH) binding in rat seminiferous tubules

Stage-specific binding of follicle-stimulating hormone (FSH) was measured in rat seminiferous tubules. The binding in single-point assays was over 3-fold higher (P less than 0.05) in stages XIII to I than in stages VI to VII of the epithelial cycle. No difference was found between the equilibrium association constants (Ka) of FSH binding in stages XIV to IV (10 +/- 1.9 X 10(9) 1/mol) and VII to VIII (9.2 +/- 0.6 X 10(9) 1/mol, mean +/- SEM, n = 5). In another experiment, the testes were dosed locally with 3 Gy of 4 MV x-irradiation to selectively lower the number of spermatogonia. After irradiation, FSH binding in staged seminiferous tubule segments was measured when the desired types of spermatogenic cells were reduced in number. Seven days after irradiation when differentiating spermatogonia and preleptotene spermatocytes were reduced in number, FSH binding was decreased in all stages of the cycle, but the cyclic variation remained. Seventeen days after irradiation when intermediate and type B spermatogonia and spermatocytes up to diplotene of stage XIII showed low numbers, FSH binding was decreased in all stages of the cycle and the stage-dependent variation disappeared. At 38 days when pachytene spermatocytes and early spermatids were reduced in number, similar results were found. But at 52 days postirradiation when all spermatids were low in number, FSH binding was slightly elevated compared with days 17 and 38. There were no significant differences in serum FSH or LH levels between irradiated and non-irradiated animals. These findings suggest that all spermatogenic cell types may stimulate FSH binding in the Sertoli cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

转录因子E2F1在非梗阻性无精症睾丸组织中的表达

目的旨在探讨E2F1核转录因子在人类睾丸组织中的表达与生精功能的关系。方法选取32例人类非梗阻性无精子症睾丸组织石蜡标本，采用HE染色观察曲细精管病理变化，同时用免疫组化SP法检测睾丸组织中核转录因子E2F1的表达;对照组选取13例人类正常睾丸组织。通过分析病理组HE染色，比较E2F1阳性染色范围及程度，评价E2F1核转录因子与生精功能的关系。结果非梗阻性无精子症睾丸组织HE染色显示精曲小管中无或仅少量精子，精曲小管的生精上皮脱落、排列紊乱，精曲小管壁部分有玻变、纤维变，生精细胞萎缩。32例非梗阻性无精子症睾丸组织中E2F1阳性表达8例，阴性表达24例，阳性率25%;13例正常睾丸组织中E2F1的阳性表达9例，阴性表达4例，阳性率69.23%;x2=7.694，差异有显著性（P〈0.01）。结论（1）E2F1核转录因子表达缺失与睾丸生精功能障碍密切相关;（2）非梗阻性无精子症睾丸组织精曲小管的生精上皮脱落、排列紊乱，生精阻滞。