Use of seminiferous tubule segments to study stage specificity of unscheduled DNA synthesis in rat spermatogenic cells

DNA repair in spermatogenic cells at various stages of maturity was determined by quantitation of unscheduled DNA synthesis (UDS). Male F-344 rats were exposed (i.p.) to methyl methanesulfonate (MMS, 35 mg/kg); 1 hr later, segments of seminiferous tubules corresponding to spermatogenesis stages II, IV-V, VI, VII, VIII, IX-X, XII, and XIV were isolated with the transillumination pattern of the tubules as a guide. Intact tubule segments were cultured 24 hr in the presence of [3H]thymidine, and UDS was quantitated by autoradiography as net grains/nucleus (NG). In primary spermatocytes from treated rats, NG count increased with increasing maturity from leptotene primary spermatocytes (3.5 NG) up through stage VIII and IX-X pachytene spermatocytes (22 NG), after which NG decreased in stage-XII pachytene and diplotene spermatocytes (to 16 NG and 8 NG, respectively). Round spermatids of steps 2-8 of spermiogenesis all exhibited approximately the same UDS response (8 NG). Elongating spermatids as mature as step 14 underwent UDS after exposure to MMS, but step-15 and later-step spermatids did not. The DNA repair response of pachytene spermatocytes cultured within segments of seminiferous tubule corresponding to stages VIII and IX-X was 4 to 25 times greater, depending on the dose of MMS, than pachytene spermatocytes isolated by enzymatic digestion and cultured in suspension [Bentley and Working, Mutat Res 203:135-142, 1988]. Thus, the use of segments of seminiferous tubule both increased the sensitivity of UDS as an indicator of DNA damage in rat germ cells and enabled the study of UDS in spermatogenic cells at different stages of maturity.     

Quantitative aspects of water buffalo (Bubalus bubalis) spermatogenesis.

In the buffalo, seminiferous tubules occupy about 82% of the testis. Spermatogenesis can be divided into 6 stages according to characteristic cellular associations in the seminiferous epithelium. A-spermatogonia have a volume of approximately 1,400 microns3 and the highest absolute mitochondrial volume of all spermatogenic cells. B-spermatogonia display cellular, nuclear and mitochondrial volumes of approximately half the values of A-spermatogonia. From preleptotene (approximately 470 microns3) to late diplotene (approximately 2,300 microns3), the volume* of primary spermatocytes increases nearly five-fold; their nuclear volumes increase by 3.5 times within the same period. During zygotene mitochondrial cristae start to dilate. Grouping of mitochondria by a dense intermitochondrial substance is most prominent during pachytene and diplotene. In pachytene the absolute size of the Golgi apparatus more than doubles, indicating a high secretory activity. Through zygotene only rER is encountered; in pachytene and diplotene a tubular sER makes its first appearance. Secondary spermatocytes are found only in stage 4 of the cycle. Due to partial cell necrosis and autolytic events, late maturation phase spermatids display no more than 25% of the size of cap phase spermatids. There is no morphological evidence for an active uptake and digestion of residual bodies by the Sertoli cells. Also, no lipid cycle is present in the buffalo seminiferous epithelium. Morphometric evaluations reveal that 63% of all theoretically possible germ cells disappear from the seminiferous epithelium during spermatogenesis. Heavy cell loss is observed in stage 4 of the cycle in the spermatogonial fraction as well as during the second meiotic division.     

Degeneration of germ cells in normal,hypophysectomized and hormone treated hypophysectomized rats

In normal adult rats some germ cells degenerate at several vulnerable steps of spermatogenesis. These are the type A spermatogonia, midpachytene spermatocytes, primary and secondary spermatocytes which degenerate during their respective maturation divisions and step 7 and 19 spermatids. In the present study, these degenerating cells were examined under the electron microscope, and their frequency was determined in toluidine blue stained semithin sections of testes from normal, hypophysectomized (at 5.5 days after operation) and hypophysectomized rats injected with FSH and LH separately or in combination. With the exception of the step 19 spermatids, the degenerating germ cells underwent necrosis in vacuolated spaces delimited by Sertoli cells. In the case of the affected step 19 spermatids, an apical cytoplasmic process of the Sertoli cell initially ensheathed a long segment of their flagellum, and then each degenerating cell was drawn deep in the seminiferous epithelium where it was phagocytozed by the Sertoli cell. Soon after hypophysectomy the incidence of degenerating mid-pachytene spermatocytes, step 7 and 19 spermatids which are present in stages VII or VIII of the cycle of the seminiferous epithelium, increased significantly. In contrast the number of degenerating primary or secondary spermatocytes during the meiotic divisions seen in stage XIV of the cycle or of any other germinal cell was not significantly modified. While the injection of FSH alone had no influence on the number of degenerating cells in hypophysectomized rats, injections of LH at the two doses administered (0.7 μg or 20 μg) reduced significantly the number of degenerating cells seen in stages VII-VIII of the cycle; combined injections of FSH and LH (20 μg) reduced the number of these degenerating cells to the normal low values. Thus it appeared that the mid-pachytene spermatocytes and the step 7 and 19 spermatids, all present in the adluminal compartment of the seminiferous epithelium in stages VII or VIII of the cycle, were more sensitive to the presence of absence of gonadotropic hormones than the other germ cells present in the seminiferous epithelium.     

Fas expression correlates with human germ cell degeneration in meiotic and post-meiotic arrest of spermatogenesis

Degeneration of human male germ cells was analysed by means of light (LM) and transmission electron (TEM) microscopy. The frequency of degenerating cells was correlated with that of Fas-expressing germ cells in human testes with normal spermatogenesis (n = 10), complete early maturation arrest (EMA) (n = 10) or incomplete late maturation arrest (LMA; n = 10) of spermatogenesis. LM analysis of testis sections with normal spermatogenesis indicated that degenerating germ cells were localized in the adluminal compartment of the seminiferous epithelium. TEM showed that apoptotic cells were mostly primary spermatocytes and, to a lesser extent, round or early elongating spermatids. Apoptotic germ cells appeared to be eliminated either in the seminiferous lumen or by Sertoli cell phagocytosis. An increased number of degenerating cells was observed in testes with LMA as compared with normal testes and testes with EMA of spermatogenesis (P < 0.001, Wilcoxon's rank sum test). Comparison of these results with those obtained from immunohistochemistry experiments demonstrated a tight correlation between the number of apoptotic cells and the number of Fas-expressing germ cells (P = 0.001, Spearman's rank = 0.69). These findings suggest that altered meiotic and post-meiotic germ cell maturation might be associated with an up-regulation of Fas gene expression capable of triggering apoptotic elimination of defective germ cells.     

The seminiferous epithelial cycle and microanatomy of the koala (Phascolarctos cinereus) and southern hairy‐nosed wombat (Lasiorhinus latifrons) testis

The koala (Phascolarctos cinereus) and southern hairy‐nosed wombat (Lasiorhinus latifrons) are iconic Australian fauna that share a close phylogenetic relationship but there are currently no comparative studies of the seminiferous epithelial cell or testicular microanatomy of either species. Koala and wombat spermatozoa are unusual for marsupials as they possess a curved stream‐lined head and lateral neck insertion that superficially is similar to murid spermatozoa; the koala also contains Sertoli cells with crystalloid inclusions that closely resemble the Charcot–Bottcher crystalloids described in human Sertoli cells. Eighteen sexually mature koalas and four sexually mature southern hairy‐nosed (SHN) wombats were examined to establish base‐line data on quantitative testicular histology. Dynamics of the seminiferous epithelial cycle in the both species consisted of eight stages of cellular association similar to that described in other marsupials. Both species possessed a high proportion of the pre‐meiotic (stages VIII, I – III; koala – 62.2 ± 1.7% and SHN wombat – 66.6 ± 2.4%) when compared with post‐meiotic stages of the seminiferous cycle. The mean diameters of the seminiferous tubules found in the koalas and the SHN wombats were 227.8 ± 6.1 and 243.5 ± 3.9 μm, respectively. There were differences in testicular histology between the species including the koala possessing (i) a greater proportion of Leydig cells, (ii) larger Sertoli cell nuclei, (iii) crystalloids in the Sertoli cell cytoplasm, (iv) a distinctive acrosomal granule during spermiogenesis and (v) a highly eosinophilic acrosome. An understanding of the seminiferous epithelial cycle and microanatomy of testis is fundamental for documenting normal spermatogenesis and testicular architecture; recent evidence of orchitis and epididymitis associated with natural chlamydial infection in the koala suggest that this species might be useful as an experimental model for understanding Chlamydia induced testicular pathology in humans. Comparative spermatogenic data of closely related species can also potentially reflect evolutionary divergence and differences in reproductive strategies.     

Early G1 in the male rat meiotic cell cycle is hypersensitive to N-methyl-N-nitrosourea-induced micronucleus formation

The effects of the known carcinogenic and teratogenic agentN-methyl-N-nitrosourea (MNU) were studied on male rat meiosis.To examine possible cell-cycle delay, an immunohistochemicaltechnique based on 5-bromo-2'-deoxyuridine (BrdU) labellingof S-phase cells was developed. BrdU tablets were implantedsubcutaneously in adult male rats. A single i.p. injection of10 mg/kg of MNU was given simultaneously. After 16–22days, preparations of stage 1 of the seminiferous epitheliumwere made and stained immunohistochemically using anti-BrdUantibodies. MNU did not cause any significant meiotic delay,but did cause a slight non-significant reduction of the percentagesof BrdU-labelled step 1 spermatids at 18 days (80%) comparedto controls (95%). In addition, the induction of meiotic micronucleiwas studied after short (1–3 days: late meiotic stages)and long (16–22 days: early spermatocytes and B spermatogonia)exposure times. The peak induction occurs between 21 and 20days, indicating that the M–G₁ transition or the verybeginning of G₁ of the cell cycle of primary spermatocytes arethe most sensitive stages to the action of MNU. The number ofstep 1 spermatids decreased dramatically in animals treatedfor 22 days, denoting a highly toxic effect on type-B spermatogonia.No unscheduled DNA synthesis was detected in any meiotic stageof spermatogenesis by using this BrdU labelling method. Theresults indicate that the spermatid micronucleus test basedon microdissection of seminiferous tubules can accurately pointout the most sensitive stage for chemically induced clastogenesis.More-over, the BrdU-immunohistochemical application enablesthe simultaneous study of cell cycle kinetics. The probablereasons for hypersensitivity of spermatocytes to MNU in thebeginning of G₁ are discussed. ¹To whom correspondence should be addressed     

Seasonal changes in spermatogenesis of the Japanese lesser horseshoe bat,Rhinolophus cornutus from a morphological viewpoint

Seasonal changes in spermatogenesis of Japanese lesser horseshoe bats, Rhinolophus cornutus, captured in Aomori Prefecture (Japan) were examined by light microscopy. In March, the seminiferous tubules revealed almost no lumen. The seminiferous epithelium consisted of Sertoli cells and spermatogonia. The interstitium occupied a relatively large area. In June, the seminiferous tubules gradually increased in diameter. Lumen was clearly seen at the center of seminiferous tubules. Mitotic figures of spermatogonia and spermatocytes were occasionally recognized. Interstitium occupation was still abundant. In August, the diameter of seminiferous tubules maximized. The interstitium occupied only a small area. Active spermatogenesis was obvious at this time. Released spermatozoa were frequently observed within the expanded lumen. In October, although spermatogenesis was still active, the diameter of seminiferous tubules tended to decrease in size. In December, active spermatogenesis completely disappeared. The diameter of tubules greatly decreased. In most cases, the seminiferous epithelium contained only Sertoli cells and spermatogonia. Thus, spermatogenesis in Japanese lesser horseshoe bats occurs from the middle or late summer to the middle autumn in Aomori Prefecture. In epididymal tracts, aggregated spermatozoa were recognized throughout the year. The cytoplasm of all Leydig cells in the interstitium was positive for 3beta-hydroxysteroid dehydrogenase throughout the year.     

Germ cell transfer into rat, bovine, monkey and human testes.

Germ cell transplantation is a potentially valuable technique offering oncological patients gonadal protection by reinitiating spermatogenesis from stem cells which were reinfused into the seminiferous tubules. In order to achieve an intratubular germ cell transfer, intratubular microinjection, efferent duct injections and rete testis injections were applied on dissected testes of four different species: rat, bull, monkey and man. Ultrasound-guided intratesticular rete testis injection was the best and least invasive injection technique with maximal infusion efficiency for larger testes. Deep infiltration of seminiferous tubules was only achieved in immature or partially regressed testes. This technique was applied in vivo on two cynomolgus monkeys. In the first monkey a deep infusion of injected cells and dye into the lumen of the seminiferous tubules was achieved. In the second, transplanted germ cells were present in the seminiferous epithelium 4 weeks after the transfer. These cells were morphologically identified as B-spermatogonia and located at the base of the seminiferous epithelium. In summary, this paper describes a promising approach for germ cell infusion into large testes. The application of this technique is the first successful attempt of a germ cell transfer in a primate.     

Live human germ cells in the context of their spermatogenic stages

BACKGROUND: Various types of live, dispersed, human testicular cells in vitro were previously compared with the morphologic characteristics of human spermatogenic germ cells in situ within seminiferous tubules. The current study extends those observations by placing live human germ cells in the context of their developmental steps and stages of the spermatogenic cycle. METHODS: Live human testicular tissue was obtained from an organ-donating, brain-dead person. A cell suspension was obtained by enzymatic digestion, and dispersed cells were observed live with Nomarski optics. Testes from 10 men were obtained at autopsy within ten hours of death, fixed in glutaraldehyde, further fixed in osmium, embedded in Epon, sectioned at 20 microm, and observed unstained by Nomarski optics. RESULTS: In both live and fixed preparations, Sertoli cells have oval to pear-shaped nuclei with indented nuclear envelopes and large nucleoli, which makes their appearance distinctly different from germ cells. For germ cells, size, shape, and chromatic pattern of nuclei, the presence of meiotic metaphase figures, acrosomic vesicles/structures, tails, and/or mitochondria in the middle piece are characteristically seen in live dispersed cells and those in the fixed seminiferous tubules. These lead to identification of live germ cells in man and placement of each in the context of their developmental steps of spermatogenesis at corresponding stages of the spermatogenic cycle. CONCLUSIONS: This comparative approach allows verification of the identity of individual germ cells seen in vitro and provides a checklist of distinguishing characteristics of live human germ cells to be used in clinical procedures or by scientists interested in studying live cells at known steps in spermatogenic development characteristic of germ cells in specific stages of the spermatogenic cycle.     

Adult rat seminiferous tubules secrete a fraction greater than 30 kDa to regulate spermatogenesis

The present study was designed to examine the effects of a >30kDa fraction of medium conditioned for 2 days by adult rat seminiferoustubules on inhibin secretion by cultured tubules, and on spermatogenesisand fertility of male rats. Inhibin secretion was assayed byadding the >30 kDa fraction to 5 cm segments of adult ratseminiferous tubules and measuring inhibin by radioimmunoassayat 2 day intervals. Fertility was assayed by injecting malerats daily for up to 45 days with the >30 kDa fraction andthen mating them with a proestrus female, or by injecting for15 days and mating them with two female rats. The assay usedto evaluate the in-vivo effect of the >30 kDa fraction onthe testis involved an assessment of frequencies of seminiferoustubule stages scored by transillumination on intact tubules.The addition of the >30 kDa fraction to the adult rat seminiferoustubules cultured for 2 days resulted in an inhibition of inhibinsecretion into the medium. This effect was reversed when thefraction was removed and changed with fresh medium and culturedfor a further 4 days. The >30 kDa fraction administered i.p.to adult male rats resulted in a low fertilization rate comparedto control rats (67%) (P < 0.05). The assessment of frequenciesof seminiferous tubule stages scored by transillumination showedan increased frequency of stage VI and decreased frequency ofstages VII and VIII after treatment. The results of the presentstudy provide additional evidence that local regulation of Sertolicell function is mediated by a >30 kDa component or componentssecreted by adult seminiferous tubules which could arrest spermatogenesis.     

Histological organization of roe deer testis throughout the seasonal cycle: variable and constant components of tubular and interstitial compartment

Seasonally regulated breeding in roe deer, Capreolus capreolus, is associated with significant changes in testis mass, structure and function. This study has quantified seasonal changes of morphometric parameters and cellular composition in roe deer testis parenchyma. Tissue samples were collected bimonthly during a complete annual cycle. Morphometric parameters of seminiferous tubules were measured and the number of different cell types was counted using a computer-aided image-analyzing system. A scheme of eight tubular epithelium stages for active spermatogenesis was devised according to the spermatid development. Stage I is characterized by the occurrence of new round spermatids, stage IV by spermiation and stage VIII by the meiotic division of spermatocytes. The average diameter of seminiferous tubules varied between 88.4±3.6 µm (February) and 216.8±9.2 µm (June). Also numbers of spermatogonia, spermatocytes and spermatids per tubule cross-section showed considerable seasonal changes. In December and February the germinative epithelium mainly consists of Sertoli cells and spermatogonia. In February, the first differentiated spermatogonia enter meiosis, and in April even spermatids occasionally occur, which reach their highest numbers during the rut in August. Both the expansion and the proportion of tubular and interstitial compartment change seasonally and result in differing cell densities. Assuming numerically constant populations of Sertoli cells and interstitial cells during the entire year, the hypothetical cell numbers per mm² of the tubular and interstitial areas were calculated for the seasonally variable total areas of tissue cross-sections. The concordance of these theoretical values with measured cell densities provided evidence that the total numbers of Sertoli cells, as well as interstitial cells, remain really constant throughout the seasonal cycle. The exact quantification of variable and constant components provides basic data for characterization of cell type and stage-specific processes of spermatogenesis.     

Induction of apoptosis involving multiple pathways is a primary response to cyclin A1-deficiency in male meiosis.

The meiotic arrest in male mice null for the cyclin A1 gene (Ccna1) was associated with apoptosis of spermatocytes. To determine whether the apoptosis in spermatocytes was triggered in response to the arrest at G2/M phase, as opposed to being a secondary response to overall disruption of spermatogenesis, we examined testes during the first wave of spermatogenesis by terminal deoxynucleotidyl transferase-mediated deoxyuridinetriphosphate nick end-labeling (TUNEL) staining. We observed enhanced apoptosis coinciding with the arrest point in postnatal day 22 tubules, with no overt degeneration. Along with activation of caspase-3, an increase in the levels and change of subcellular localization of Bax protein was observed in cyclin A1-deficient spermatocytes, which coincided with the detection of apoptosis. As p53 is implicated in the activation of Bax-mediated cell death, we generated mice lacking both cyclin A1 and p53. Although the absence of p53 did not rescue the meiotic arrest, there was a decrease in the number of apoptotic cells in the double-mutant testes. This finding suggested that p53 may be involved in the process by which the arrested germ cells are removed from the seminiferous tubules but that other pathways function as well to ensure removal of the arrested spermatocytes.     

Targeting Mitosis for Anti-Cancer Therapy

Basic research that has focused on achieving a mechanistic understanding of mitosis has provided unprecedented molecular and biochemical insights into this highly complex phase of the cell cycle. The discovery process has uncovered an ever-expanding list of novel proteins that orchestrate and coordinate spindle formation and chromosome dynamics during mitosis. That many of these proteins appear to function solely in mitosis makes them ideal targets for the development of mitosis-specific cancer drugs. The clinical successes seen with anti-microtubule drugs such as taxanes and the vinca alkaloids have also encouraged the development of drugs that specifically target mitosis. Drugs that selectively inhibit mitotic kinesins involved in spindle and kinetochore functions, as well as kinases that regulate these activities, are currently in various stages of clinical trials. Our increased understanding of mitosis has also revealed that this process is targeted by inhibitors of farnesyl transferase, histone deacetylase, and Hsp90. Although these drugs were originally designed to block cell proliferation by inhibiting signaling pathways and altering gene expression, it is clear now that these drugs can also directly interfere with the mitotic process. The increased attention to mitosis as a chemotherapeutic target has also raised an important issue regarding the cellular determinants that specify drug sensitivity. One likely contribution is the mitotic checkpoint, a failsafe mechanism that delays mitotic exit so that cells whose chromosomes are not properly attached to the spindle have extra time to correct their errors. As the biochemical activity of the mitotic checkpoint is finite, cells cannot indefinitely sustain the delay, as in cases where cells are treated with anti-mitotic drugs. When the mitotic checkpoint activity is eventually lost, cells will exit mitosis and become aneuploid. While many of the aneuploid cells may die because of massive chromosome imbalance, survivors that continue to proliferate will no doubt be selected. This is clearly an undesirable outcome, thus efforts to obtain fundamental insights into why some cells that arrest in mitosis die without exiting mitosis will be exceedingly important in enhancing our understanding of the drug sensitivity of cancer cells.     

Specific expression of the mRNA for 25 kDA heat-shock protein in the spermatocytes of mouse seminiferous tubules

 The 25 kDa heat-shock protein (Hsp25) is a member of the family of small heat-shock proteins. We investigated the expression and cellular localization of Hsp25 mRNA in the testis of adult and developing mice using Northern blotting and in situ hybridization techniques. In the early postnatal days, i.e., before the onset of spermatogenesis, no Hsp25 mRNA was detected in the testis. At around 10 days postpartum, Hsp25 mRNA began to be expressed in the testis in coincidence with the onset of the first wave of spermatogenesis and increased in amount progressively toward adulthood. Throughout the testis development, the signal for Hsp25 mRNA was localized exclusively to germ cells and was not detected in Sertoli or interstitial cells. The testis of W/Wv mutant mice, which lack the germ cell line, exhibited no Hsp25 mRNA expression. In the testis of normal adult mice, the abundance of Hsp25 mRNA differed among the seminiferous tubules in different stages of spermatogenesis. The most intense signal for Hsp25 mRNA was localized to the spermatocytes at leptotene, zygotene and early pachytene phases, which are present in the tubules of stages I–III and IX–XII. The signal decreased in intensity in the late pachytene and diplotene spermatocytes and was not detected in spermatids. Spermatogonia were also devoid of the signal. These results suggested that Hsp25 plays some specific role in the meiotic prophase of the testicular germ cell. Accepted: 27 Oct 1998     

Transcription and imprinting dynamics in developing postnatal male germline stem cells

Postnatal spermatogonial stem cells (SSCs) progress through proliferative and developmental stages to populate the testicular niche prior to productive spermatogenesis. To better understand, we conducted extensive genomic profiling at multiple postnatal stages on subpopulations enriched for particular markers (THY1, KIT, OCT4, ID4, or GFRa1). Overall, our profiles suggest three broad populations of spermatogonia in juveniles: (1) epithelial-like spermatogonia (THY1⁺; high OCT4, ID4, and GFRa1), (2) more abundant mesenchymal-like spermatogonia (THY1⁺; moderate OCT4 and ID4; high mesenchymal markers), and (3) (in older juveniles) abundant spermatogonia committing to gametogenesis (high KIT⁺). Epithelial-like spermatogonia displayed the expected imprinting patterns, but, surprisingly, mesenchymal-like spermatogonia lacked imprinting specifically at paternally imprinted loci but fully restored imprinting prior to puberty. Furthermore, mesenchymal-like spermatogonia also displayed developmentally linked DNA demethylation at meiotic genes and also at certain monoallelic neural genes (e.g., protocadherins and olfactory receptors). We also reveal novel candidate receptor–ligand networks involving SSCs and the developing niche. Taken together, neonates/juveniles contain heterogeneous epithelial-like or mesenchymal-like spermatogonial populations, with the latter displaying extensive DNA methylation/chromatin dynamics. We speculate that this plasticity helps SSCs proliferate and migrate within the developing seminiferous tubule, with proper niche interaction and membrane attachment reverting mesenchymal-like spermatogonial subtype cells back to an epithelial-like state with normal imprinting profiles.     

The ziwi promoter drives germline‐specific gene expression in zebrafish

We describe here the characterization of the promoter activity of a 4.8‐kb sequence isolated from the 5′ end of the zebrafish germ cell‐specific ziwi gene. We show that this fragment is sufficient to drive heterologous gene expression specifically in germ cell starting as early as 7 days post‐fertilization, a time point when only mitotic germ cells are present in the gonad. In adult animals, we find that this fragment is sufficient to drive gene expression in all germ cells with stage‐specific differences in expression levels. In females, EGFP expression is highest in stage IB oocytes, but appreciable expression is detected in both pre‐meiotic germ cells, as well stage II–IV oocytes and mature eggs. In males, EGFP expression is highest in spermatogonial stem cells, but low levels are detected in all stages, including spermatozoa. Developmental Dynamics 239:2714–2721, 2010. © 2010 Wiley‐Liss, Inc.     

Use of confocal microscopy for the study of spermatogenesis

Spermatogenesis consists of spermatogonial proliferation, meiosis and spermatid differentiation. Laser scanning confocal microscopy (LSCM) may be used as an advanced analytical tool to follow spermatogenesis inside the seminiferous tubules without performing histological sections. For this purpose, separated seminiferous tubules are fixed in 0.5% paraformaldehyde, stained for DNA with propidium iodide and analyzed by LSCM. By producing longitudinal optical sections in the layer of spermatogonia, spermatocytes and spermatids, stage-specific changes in their structure may be followed within the tubules by LSCM. Longitudinal z-sections may be obtained to produce three-dimensional images of the seminiferous tubules. In addition, different proteins may be followed during spermatogenesis in a stage specific manner within the tubule by incubation of the fixed seminiferous tubules with appropriate antibodies.As an example of the spermatogenesis studies using described LSCM techniques, detailed examination of spermatogonia, spermatocytes and spermatids during golden hamster spermatogenesis is presented. LSCM analysis of c-kit and SC3 protein expression at different stages of hamster spermatogenesis is demonstrated.