The effects of temperature and glucose on protein biosynthesis by immature (round) spermatids from rat testes

A method is described for the preparation of highly purified fractions (greater than 80% pure) of immature spermatids (round, steps 1--8) from rat testes by centrifugal elutriation in sufficient yields for biochemical studies when four rat testes are used. Electron microscopy established the identity of the cells and demonstrated that the cell membrane is intact. Some cells develop nuclear and cytoplasmic vacuoles during the 2 h required for preparation. Immature spermatids prepared by this method use glucose with an increase in oxygen consumption, lactate production, and protein synthesis over control levels (no glucose). The testicular cell suspension from which spermatids are separated, like whole testis and spermatids themselves, show higher incorporation of amino acids into TCA-precipitable material at 34 degrees C than at 38 degrees C and in the presence of glucose. A subcellular system prepared from immature spermatids with excess ATP shows greater incorporation of amino acids into TCA-precipitable material at 34 degrees C than at 38 degrees C. This difference does not result from increased breakdown of protein. It is concluded that body temperature (38 degrees C) inhibits some aspect(s) of protein synthesis in addition to previously reported effects on amino acid transport and production of ATP (Means and Hall. 1969. Endocrinology. 84:285--297.).     

DNA polymerases in mouse spermatogenic cells separated by sedimentation velocity.

Activity levels of DNA polymerase alpha and DNA polymerase beta have been measured in mouse spermatogenic cells separated by sedimentation velocity. Testes from prepuberal (17 day old) and sexually mature mice were dissociated and separated by unit gravity sedimentation into 6 populations of cells. Phase contrast microscopy and [3H]thymidine labeling kinetics revealed that at least 85% of the cells in fraction A were pachytene-stage primary spermatocytes, fraction B was enriched for primary spermatocytes and round spermatids, fraction C contained spermatogonia and/or pre-leptotene primary spermatocytes and later stages of spermatids (no spermatids were present in fraction C from the testes of 17 day old mice) and fractions D to F contained mixed populations of cells, many in later stages of spermiogenesis. When expressed as activity in 10(6) cells or as a specific activity, fractions A, B, and C from mature animals population initially loaded onto the gradient while fractions D, E and F had activity levels similar to or below the population of dissociated cells. The ratio of activity between the DNA polymerases was constant in fractions A, B, and C, but in fractions D, E, and F, the ratio decreased due to a more rapid decline of activity of polymerase alpha. A comparison of activity levels in fraction C from prepuberal and sexually mature mice revealed an increase in DNA polymerase alpha activity and a decrease in the activity of DNA polymerase beta in the cells from the 17 day old animals.     

Developmental program of PGK-1 and PGK-2 isozymes in spermatogenic cells of the mouse: Specific activities and rates of synthesis

The specific activities and synthesis of the ubiquitous isozyme, PGK-1, and the testis-specific isozyme, PGK-2, have been quantitated and localized in spermatogenic cells of the mouse. There is a fivefold increase in total PGK specific activity between immature and adult testes which begins at approximately 30 days of age, coincident with the appearance of late-middle stage spermatids. The increase in total PGK is entirely due to the appearance and increase of the PGK-2 isozyme. Rates of PGK synthesis were measured by labeling testicular cells in vitro with [³H]leucine and purifying the PGK isozymes. When total testicular cells were examined, PGK-2 synthesis was detectable after 22 days of age at very low levels and increased in older testes to a level of 0.5% of total protein synthesis. PGK-1 synthesis remained relatively constant at all ages at a level 100-fold lower (0.005%). Testicular cells were separated into highly enriched fractions of particular spermatogenic stages by centrifugal elutriation. The PGK-1 synthesis rates were, again, very low and not significantly different between the various spermatogenic stages. PGK-2 synthesis was low to nondetectable in pachytene spermatocytes, increased to 0.07% in early spermatids and represented 0.7% of total protein synthesis in late spermatids. This increased rate of PGK-2 synthesis appears to require an increase in the amount of PGK-2 mRNA in late spermatids, cells in which no active RNA synthesis is detectable.     

Histones of spermatogenous cells in the house cricket

Histones were isolated from testis of the house cricket and analyzed by electrophoresis on polyacrylamide gels containing urea and acetic acid. Testes of two different nymphal instars and of adults were examined. The testes contained gonial and meiotic stages in the younger nymphs analyzed, and these same stages plus early spermatids in the older nymphs. At both nymphal instars, testis histone displayed the same five major fractions that are found in somatic nuclei of the cricket; the only unusual feature noted in nymph testis was a high abundance of phosphorylated F1. Adult testis has the same histone fractions as nymph testis and has two new fractions in addition. SDS electrophoresis also shows the presence of two more histones in adult testis than in nymph testis. — The unusual testis histones appear to accumulate during the nuclear elongation stages of spermiogenesis. The occurrence of these stages in adult testis is correlated with the presence of the extra histones. Nuclei of adult testis were separated into fractions enriched for early, mid, and late stages by velocity sedimentation at unit gravity. The unusual histones predominate in the fractions enriched for late spermiogenic stages. Both of the new histones appear to occur in the same stages of spermiogenesis, and display linked accumulation. Eventually they make up at least seventy percent of the histone complement.     

Isolation and biochemical studies of enriched populations of spermatogonia and early primary spermatocytes from rat testes

A method to obtain several highly enriched populations of testis cell types from rats of a single age is described. Single cell suspensions from immature rat testes were prepared after enzymatic removal of interstitial cells. Cells were separated on the basis of size into four fractions (bulk preparations) or eight fractions (analytical preparations) by centrifugal elutriation. These elutriator fractions were further separated by equilibrium density centrifugation in Percoll gradients. In this manner, populations of 2 X 10(7) type A spermatogonia (51% purity), 3 X 10(7) type B spermatogonia (76% purity), 5 X 10(7) zygotene/early pachytene spermatocytes (56% purity), 3 X 10(7) midpachytene spermatocytes (70% purity), and 4 X 10(7) Sertoli cells (89% purity) could be obtained from 50 immature rats within 6 h after killing. Purities, determined by examination of cytologic smears, were verified by Coulter volume and flow cytometric DNA determinations. These separation methods were used to obtain cell populations for characterization of levels and synthesis of high mobility group proteins in the early stages of spermatogenesis.     

Regulation of the synthesis of lactate dehydrogenase-X during spermatogenesis in the mouse

Total mouse testis RNA directs the synthesis of the sperm-specific C subunit of lactate dehydrogenase-X (LDH-X) when translated in a cell- free system derived from rabbit reticulocytes. The newly synthesized C subunits were isolated by immunoprecipitation with antibody specific for this isozyme, and quantitated by electrophoresis on SDS polyacrylamide gels. The amount of radioactivity incorporated into the enzyme subunit was directly proportional to the amount of testis RNA added to the translational system, thereby providing a sensitive and reliable method for assessing relative LDH-X mRNA activity. A combination of sucrose gradient centrifugation and oligo(dT)-cellulose chromatography resulted in a 23-fold purification of LDH-X mRNA over total cytoplasmic testis RNA. Analysis of LDH-X mRNA activity in the developing testis indicated that the appearance of functional LDH-X mRNA activity coincides with the appearance of LDH-X catalytic activity at 14 d postpartum. Measurement of LDH-X mRNA levels in separated testis cell populations prepared by centrifugal elutriation demonstrated that LDH-X mRNA represents 0.17-0.18% of the total functional mRNA activity in fractions enriched in pachytene spermatocytes and round spermatids, but only 0.09-0.10% of the translation products of elongated spermatids.     

Separation of Spermatogenic Cell Types Using STA-PUT Velocity Sedimentation

Mammalian spermatogenesis is a complex differentiation process that occurs in several stages in the seminiferous tubules of the testes. Currently, there is no reliable cell culture system allowing for spermatogenic differentiation in vitro, and most biological studies of spermatogenic cells require tissue harvest from animal models like the mouse and rat. Because the testis contains numerous cell types - both non-spermatogenic (Leydig, Sertoli, myeloid, and epithelial cells) and spermatogenic (spermatogonia, spermatocytes, round spermatids, condensing spermatids and spermatozoa) - studies of the biological mechanisms involved in spermatogenesis require the isolation and enrichment of these different cell types. The STA-PUT method allows for the separation of a heterogeneous population of cells - in this case, from the testes - through a linear BSA gradient. Individual cell types sediment with different sedimentation velocity according to cell size, and fractions enriched for different cell types can be collected and utilized in further analyses. While the STA-PUT method does not result in highly pure fractions of cell types, e.g. as can be obtained with certain cell sorting methods, it does provide a much higher yield of total cells in each fraction (~1 x 10⁸ cells/spermatogenic cell type from a starting population of 7-8 x 10⁸ cells). This high yield method requires only specialized glassware and can be performed in any cold room or large refrigerator, making it an ideal method for labs that have limited access to specialized equipment like a fluorescence activated cell sorter (FACS) or elutriator.     

Cellular composition of fractions of mouse testis cells following velocity sedimentation separation

Identification of cells has been made in stained smears of cell suspensions prepared from mouse testes and separated by velocity sedimentation at unit gravity. Comparison of various methods of producing suspensions demonstrated that the best cell separations were achieved using suspensions prepared with trypsin. Various fractions obtained following separation contained 29% Sertoli cells sedimenting at about 14 mm/h, 17% Leydig cells at 11 mm/h, 73% pachytene spermatocytes at 9.5 mm/h, 54% binucleate spermatids and 14% secondary spermatocytes at 6.7 mm/h, 77% round spermatids at 4.5 mm/h, 21% elongating spermatids and 74% cytoplasmic fragments detached from these spermatids at 2.1 mm/h and 37% late spermatids at 0.75 mm/h. The resolution of different size classes of cells was essentially complete, but separation of different types of cells was limited by the occurrence of multinucleate forms of the cells and by fragments of damaged elongated spermatids. Most cells, however, appeared to be intact on light microscopical examination.     

Preparation of spermatogenic cell populations at specific stages of differentiation in the human.

Studying biochemical events in human spermatogenesis requires separated populations of spermatogenic cells. Dissociation of these cells was performed by a Trypsin-DNAse method adapted from the technique used for rodents. Cell separation was performed by centrifugal elutriation. Seven populations were collected, one further purified by Percoll gradient centrifugation, giving nine different cell populations. The efficiency of the cell separation was evaluated by phase contrast microscopy, flow cytometric DNA analysis, and electron microscopy. Five populations were enriched in spermatids: two in round spermatids (87% and 73%), another in round (52%) and elongating (44%) spermatids, another constituted by 80% elongating spermatids, and the last by 90% elongated spermatids. Two of the four remaining populations were enriched in primary spermatocytes (74% and 54%); another population was the upper part of the Percoll gradient and constituted cytoplasmic lobes and residual bodies (89%); the last population was made up of various cells, with no specific enrichment. Electron microscopic observations revealed good preservation of the separated cells; only the flagella from elongated spermatids were lost. Furthermore, an unusual pattern of nucleoplasm distribution during stages 2-4 of spermatid differentiation was observed and its signification is discussed with regard to the shape of the human spermatozoon.     

Separation of ram spermatids by sedimentation at unit gravity

Suspensions of 1 × 10⁸ ram testis cells were prepared with trypsin and separated by velocity sedimentation at unit gravity in a non-linear Ficoll gradient. An improvement was made in the technique of cell suspension preparation to increase the viability of heat-sensitive germ cells. Six bands of cells numbered from I–VI were characterized by their sedimentation velocity and modal cell volume. The distribution of various classes of germ cells in these bands, and especially spermatids at different maturation stages, was determined using histological techniques and confirmed by kinetic profiles and autoradiographic analyses of ³H-thymidine incorporation. A homogenous population of round spermatids (93–96%) was obtained in the high sedimentation velocity part of band IV. Although elongated spermatid separation does not rigorously follow the maturation stage, it gives populations which can be used for the investigation of biochemical changes during spermiogenesis. Taking into account the viability and the ultrastructure of germ cells after separation, it was shown that the use of Ficoll as a gradient material instead of bovine serum albumin causes cellular damage. We successfully applied the technique of velocity sedimentation to testis cell separation in the bull, boar, billy-goat and stallion.     

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

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

Enrichment of primary pachytene spermatocytes from the human testis

Normal adult human testis has been separated using a combination of mechanical and enzymatic procedures to yield a suspension of viable single cells. The predominant cell types comprising this suspension are as follows: primary pachytene spermatocytes (7% of total cells), round spermatids (17%), residual bodies and condensing spermatids (31%), and Leydig cells (15%). Separated human germ cells viewed by Nomarski differential interference microscopy closely resemble mouse spermatogenic cells in relative size and appearance. Isolation of an enriched population of human pachytene spermatocytes has been achieved using unit gravity sedimentation (STA-PUT) according to protocols originally developed for murine tissue. Pachytene cells are enriched to 75% and are contaminated only with Leydig cells and binucleated spermatid symplasts. Ultrastructural examination of isolated human pachytene spermatocytes indicates that these cells, as well as isolated round spermatids, exhibit a normal in situ morphology. Spermatocytes, for example, show numerous synaptonemal complexes, nuclear pores, annulate lamellae, and dictyosome-like saccules. Round spermatids after isolation exhibit peripheral mitochondria, annulate lamellae, developing acrosomes, and other morphological features characteristic of early spermiogenesis. Therefore, enriched populations of human spermatogenic cells seem suitable for analysis using immunofluorescent, autoradiographic, or serological methods. In particular, isolated human spermatocytes should be useful for the analysis of molecular events involved in meiosis and should facilitate investigations concerning the pathophysiology of certain human infertility conditions.     

Biosynthesis and localization of lactate dehydrogenase X in pachytene spermatocytes and spermatids of mouse testes

The presence and biosynthesis of the testis-specific isozyme of lactate dehydrogenase (LDH-X) in cells at various stages of spermatogenesis have been examined. Enrichment of testicular cells in various stages of spermatogenesis has been achieved by two methods: (1) cell separation by velocity sedimentation in the Elutriator rotor and (2) γ irradiation of testes to eliminate specific classes of testicular cells. Separation of cells from immature mice indicated that cells prior to the midpachytene stage contain no LDH-X. Measurement of LDH-X levels in cells separated from adult mice and in testicular homogenates prepared at various times after irradiation indicated that the highest level of LDH-X per cell (normalized for DNA content) was in spermatids. Synthesis of LDH-X was determined, after in vivo injection of [³H]valine, by measurement of the radioactivity in LDH-X precipitated with specific antiserum. After irradiation, the rate of LDH-X synthesis remained constant, despite the loss of early primary spermatocytes. In separated cells, the rate of LDH-X synthesis was highest in late pachytene spermatocytes, lower in round spermatids, and even lower, but still significant, in elongated spermatids. Therefore, the synthesis of LDH-X begins at a specific point during spermatogenesis, the midpachytene stage of spermatocyte development, and continues throughout spermatid differentiation.     

Cloning,Characterization and Primary Function Study of a Novel Gene,Cymg1,Related to Family 2 Cystatins

Cystatins are cysteine proteinase inhibitors,We found two expression sequence tags (ESTs),CA463109 and AV042522,from a mouse testis library using Digital differential display (DDD).By electricalhybridization,a novel gene,Cymgl(GenBank accession No.AY600990),which has a full length of 0.78 kb,and contains four exons and three introns,was cloned from a mouse testis eDNA library.The gene is locatedin the 2G3 area of chromosome 2.The full eDNA encompasses the entire open reading frame,encoding 141amino acid residues.The protein has a cysteine protease inhibitor domain that is related to the family 2cystatins but lacks critical consensus sites important for cysteine protease inhibition.These characteristicsare seen in the CRES subfamily,which are related to the family 2 cystatins and are expressed specifically inthe male reproductive tract.CYMG1 has a 44%(48/108)identity with mouse CRES and 30%(42/140)identity with mouse cystatin C.Northern blot analysis showed that the Cymgl is specifically expressed inadult mouse testes.Cell location studies showed that the GFP-tagged CYMG 1 protein was localized in thecytoplasm of HeLa cells,lmmunohistochemistry revealed that the CYMG1 protein was expressed in mousetestes spermatogonium,spermatocytes,round spermatids,elongating spermatids and spermatozoa.RT-PCRresults also showed that Cymgl was expressed in mouse testes and spermatogonium.The Cymgl expressionlevel varied in different developmental stages:it was low 1 week postpartum,steadily increased 2 to 5 weekspostpartum,and was highest 7 weeks postpartum.The expression level at 5 weeks postpartum was main-tained during 13 to 57 weeks postpartum.The Cymgl expression level in the testes over different develop-mental stages correlates with the mouse spermatogenesis and sexual maturation process.All these indicatethat Cymgl might play an important role in mouse spermatogenesis and sexual maturation. Cystatins are cysteine proteinase inhibitors,We found two expression sequence tags(ESTs),CA463109 and AV042522,from a mouse testis library using Digital differential display (DDD).By electricalhybridization,a novel gene,Cymgl(GenBank accession No.AY600990),which has a full length of 0.78 kb,and contains four exons and three introns,was cloned from a mouse testis eDNA library.The gene is locatedin the 2G3 area of chromosome 2.The full eDNA encompasses the entire open reading frame,encoding 141amino acid residues.The protein has a cysteine protease inhibitor domain that is related to the family 2cystatins but lacks critical consensus sites important for cysteine protease inhibition.These characteristicsare seen in the CRES subfamily,which are related to the family 2 cystatins and are expressed specifically inthe male reproductive tract.CYMG1 has a 44%(48/108)identity with mouse CRES and 30%(42/140)identity with mouse cystatin C.Northern blot analysis showed that the Cymgl is specifically expressed inadult mouse testes.Cell location studies showed that the GFP-tagged CYMG 1 protein was localized in thecytoplasm of HeLa cells,lmmunohistochemistry revealed that the CYMG1 protein was expressed in mousetestes spermatogonium,spermatocytes,round spermatids,elongating spermatids and spermatozoa.RT-PCRresults also showed that Cymgl was expressed in mouse testes and spermatogonium.The Cymgl expressionlevel varied in different developmental stages:it was low 1 week postpartum,steadily increased 2 to 5 weekspostpartum,and was highest 7 weeks postpartum.The expression level at 5 weeks postpartum was main-tained during 13 to 57 weeks postpartum.The Cymgl expression level in the testes over different develop-mental stages correlates with the mouse spermatogenesis and sexual maturation process.All these indicatethat Cymgl might play an important role in mouse spermatogenesis and sexual maturation.     

Separation of mouse testis cells by equilibrium density centrifugation in Renografin gradients

Mouse testis cells have been separated by equilibrium density centrifugation in gradients of Renografin. Intact testis cells were not damaged by the separation procedure provided that, following separation, the osmolarity was reduced gradually. The various cell types were identified microscopically and by ³H-thymidine labelling with similar results. The present technique has demonstrated that significant variations in cell density occur during spermatogenesis. Approximately ten-fold enrichments of nearly all testis cell types were achieved by equilibrium density separation of testis cell suspensions. More homogeneous cell populations were prepared by density gradient centrifugation of cell fractions obtained from velocity sedimentation separations. Overall enrichments of spermatogonia, by 29-fold; pachytene spermatocytes, 45-fold; dividing meiotic cells, 170-fold; round spermatids, 30-fold; step 11–13 elongating spermatids, 12-fold; Leydig cells, 70-fold; and cytoplasmic fragments, 55-fold, were obtained. In this study, a method for preparation of cell suspensions was also developed to produce higher yields of spermatogonia and young primary spermatocytes; however, the density distribution of these cells was altered.     

Immunohistochemical study of calmodulin in developing mouse testis

The purpose of this study was to determine the localization of calmodulin in the developing mouse testis by the indirect immunoperoxidase method. In addition, the amount of calmodulin in pachytene spermatocytes, spermatids, and residual bodies isolated from the mouse testis and epididymal spermatozoa was quantitated by the adenylate cyclase activation assay and by enzyme immunoassay. The relative levels of calmodulin in the developing mouse testis and in the isolated testicular germ cells were confirmed by western transfer staining. The level of immunoreactive calmodulin was very low in the testes from immature animals. In testes from the mature mouse, calmodulin was found to be localized in spermatocytes and spermatids, but was not found in spermatogonia, Sertoli cells, and interstitial cells. By contrast, immunochemical staining of tubulin was extremely intense in Sertoli cells. Biochemical determinations also showed that pachytene spermatocytes, round spermatids, spermatozoa, and residual bodies contained 14.9 micrograms, 15.8 micrograms, 2.3 micrograms and 5.2 micrograms of calmodulin per mg of protein, respectively. Both the immunochemical and the biochemical studies revealed that levels of calmodulin were high in the spermatocytes and in the round spermatids, as compared to the level in spermatozoa. This fact strongly suggests that the large amount of calmodulin in mammalian testes may be associated primarily with meiotic divisions and/or spermatogenesis.     

Histone synthesis and replacement during spermatogenesis in the mouse.

Separation of labelled nuclei by sedimentation velocity at unit gravity (Staput method) was used to study the timing of histone synthesis and replacement by testis-specific basic nuclear protein (TSP) during spermatogenesis in the mouse. Animals were injected (intratesticularly) with 1.25 micronCi per testis 3H-arginine or 2.5 micronCi per testis 3H-lysine, testis nuclei were separated, and the acid extract of each nuclear fraction was analyzed by acrylamide gel electrophoresis. The distribution of labelled histones and TSP in separated nuclei was assessed 2 h after incorporation. Changes in the labelled histone and TSP content of nuclei during subsequent differentiation (1--34 days post-label) was followed in fractions of separated testis cell nuclei and in nuclei of cauda epididymal spermatozoa. Analysis of total histone and (TSP) content indicated quantitative changes during development. Nuclei from primary spermatocytes had relatively larger amounts of histones H1 and H4. Spermatid nuclei showed a relative reduction in histones H1 and H4, coincident with the appearance of TSP in these nuclei. These results suggested that synthesis and/or removal of certain histones must occur in late primary spermatocyte and early spermatid stages of spermatogenesis. Results of labelling experiments indicated several periods of histone synthesis during spermatogenesis: (1) closely associated with the last DNA synthesis(i.e., in early primary spermatocytes), (2) late in meiotic prophase (i.e., in pachytene primary spermatocytes) and (3) simultaneous with TSP synthesis (i.e., in late spermatids). Histone H1 was more heavily labelled toward the end of the primary spermatocyte period. Histone H4 was more heavily labelled in the early primary spermatocyte period, and again at the time of TSP synthesis in spermatids. Histones synthesized before the pachytene primary spermatocyte stage appeared to be replace, but histones synthesized later in spermatogenesis appeared to be at least partially retained in epididymal spermatozoa. These results suggested that repeated specific alterations in the protein complement of the nucleus are an integral part of spermatogenic differentiation in the mouse.     

A strategy for an improved separation of mammalian spermatids

A collection procedure has been developed to improve the homogeneity of mammalian spermatid populations separated by elutriation. Trypsinizied ram testis cells were elutriated at 18C. Every cell population was eluted by progressive changes in the flow rate and/or rotor speed, instead of by abrupt changes, to reduce the contamination by cells from the next population. Pure populations were collected alternating with mixed populations corresponding to the overlap between two adjacent pure populations. Furthermore, each pure population was collected into two subfractions, the second of which, contamined by cells from the following population, was pooled with the following fraction. In less than 2 hr after castration, three populations of at least 1 × 10⁸ viable round or elongated or elongating spermatids were obtained with respective purities of 95%, 82%, and 99% of the nucleated cells. In addition, two mixed populations containing only two adjacent spermatid types (round plus elongating spermatids: 98%; elongated plus elongating spermatids: 98%) were obtained, as well as a population containing around 60% pachytene spermatocytes.