Distribution of repetitious DNA in randomly growing and synchronized Chinese hamster cells.

Early spermatogenic cells from the testes of 10-, 13-, 15-, 18-, 20- and 25-day-old rats were purified by sedimentation at unit gravity. Cell dissociation was accomplished in 5 mM EDTA or 0.1% trypsin in Ca-Mg-free phosphate-buffered saline (pH 7.35). Dissociation with trypsin resulted in more viable cells than with EDTA, while EDTA was more efficient for the dissociation of spermatogonia. The differential effects of the two dissociation media were particularly evident in cell preparations from the 10-day-old animal. Maximum purity of different cell types was obtained in different aged animals (spermatogonia, 98%, 10 days; preleptotene spermatocytes, 98%, 10 days; leptotene spermatocytes, 75%, 13 days; zygotene spermatocytes, 68%, 18 days; pachytene spermatocytes, 75%, 25 days). Purity of particular types was correlated with the age of the animal. Earlier stages were purified to a greater extent in younger animals and later stages to a greater extent in older animals. Later stages exhibited increasing sedimentation at unit gravity in correlation with the increase in cell size as differentiation proceeded to pachytene spermatocyte. Two early germinal cell types, spermatogonia and preleptotene spermatocytes, were greatly purified with this technique.     

Comparative cytogenetic study after treatment of mouse spermatogonia with mitomycin C

Male (101 × C₃H)F₁ hybrid mice, 10–12 weeks old, were injected i.p. with single doses of 2.5, 3.75 or 5.0 mg/kg of mitomycin C (MC). Spermatogonia were sample for mitotic chromosome analyses 6, 18 or 24 h after treatment. Spermatocytes were sample for meiotic chromosome analyses 50 or 60 days after treatment.The maximal yield of chromatid-type aberrations induced in spermatogonia was found 24 h after treatment with 5.0 mg/kg of MC. More than 50% of the cells carried at least one chromatid exchange. The majority (90%) of these were whole-arm exchanges derived from breaks in the centromeric heterochromatin.No translocation multivalents were found in spermatocytes analysed 50 or 60 days after treatment. The discrepancy between the presence of many symmetrical exchanges in spermatogonia and the absence of translocation multivalents in primary spermatocytes may be result of insensitivity of the stem cell spermatogonia against exchange induction by MC or of complete germinal selection against induced translocations before and/or during early meiosis. However, the possibility of missing translocations due to whole-arm exchanges in acrocentric chromosomes during the analysis of diakineses-metaphases I is also discussed.It is emphasized that comparisons of chromatid exchange frequencies in spermatogonia with the yield of translocation multivalents in spermatocytes descended from these spermatogonia as opposed to those from stem cells might provide an estimate of pre-diakinesis germinal selection against chromatid exchanges or the resulting translocations. This estimate is important for the quantitative evaluation of the genetic risk from environmental mutagens.     

Cultivation of boar spermatogonia on Sertoli cells

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

The origin of the synchronization of the seminiferous epithelium in vitamin A-deficient rats after vitamin A replacement

In seminiferous tubules of vitamin A-deficient rats, the remaining spermatogonia were A spermatogonia. These cells were topographically arranged as single and paired cells and clones of 4, 8, or more cells. The bromodeoxy-uridine-labeling index and the mitotic index of these cells were found to be 9% and 1%, respectively, indicating that these cells were slowly proliferating. Administration of vitamin A (retinol-acetate) resulted in a reinitiation of spermatogenesis in such a way that the epithelium became stage-synchronized. The rate of development of the spermatogenic cells between 7 and 21 days after vitamin A replacement was found to be similar to that in normal rats. At 24-30 h after administration of vitamin A, a 4- to 6-fold increase in the labeling index was found. In contrast, after 2 days, the labeling index was low, while the mitotic index was elevated (10%). A high labeling index was found again after 3 days. Assuming that during the first 7 days after vitamin A replacement the rate of development of the spermatogenic cells also was normal, it could be deduced that the spermatogonia labeled 24-30 h after vitamin A administration were A1 spermatogonia. These cells would then divide into A2 spermatogonia after about 2 days, which in turn would traverse their S phase after about 3 days. Hence, spermatogenesis in vitamin A-deficient rats would be arrested shortly before the S phase of the A1 spermatogonia. After administration of vitamin A, the spermatogonia synchronously start the series of six divisions leading to the formation of spermatocytes and, ultimately, they develop into mature spermatids.(ABSTRACT TRUNCATED AT 250 WORDS)     

Selective partitioning of plasma membrane antigens during mouse spermatogenesis

The selective partitioning of cell membrane components during mouse spermatogenesis has been examined using a heterologous antibody raised against isolated type B spermatogonia. The anti-type B spermatogonia rabbit IgG (ATBS) binds to isolated populations of mouse primitive type A spermatogonia, type A spermatogonia, type B spermatogonia, preleptotene spermatocytes, leptotene/zygotene spermatocytes, pachytene spermatocytes, round spermatids, residual bodies, and mature spermatozoa. Although immunofluorescent labeling is uniformly distributed on the cell surface of early spermatogenic cells, a discrete topographical localization of IgG is observed on testicular, epididymal, and vas deferens spermatozoa. The convex surface of the acrosome, postacrosomal region, and tail are labeled. Antibody does not bind to a broad area corresponding to the concave region of the acrosome. The antibody also binds to mouse somatic cells including Sertoli cells, Leydig cells, thymocytes, and splenocytes, but not to mature spermatozoa of the vole, rat, hamster, guinea pig, rabbit, or human. ATBS, after absorption with mouse splenocytes or thymocytes, does not react with any somatic cells examined by fluorescence except with Sertoli cells. In addition, all reactivity with testicular, epididymal, and was deferens spermatozoa is abolished. However, spermatogenic cells at earlier stages of differentiation, including residual bodies, still react strongly with the absorbed antibody. The number of surface receptor sites per cell for absorbed ATBS ranges from approximately 3 million on primitive type A spermatogonia to 1 million on round spermatids and on residual bodies. Spermatozoa, however, have only 0.003 million binding sites for absorbed ATBS, in contrast to 10 million sites for the unabsorbed antibody. It appears that receptor sites for absorbed ATBS are not masked by components of epididymal secretions. These data imply, therefore, that specific mechanisms operate at the level of the cell membrane during spermiogenesis to insure that some surface components, not required in the mature spermatozoon, are removed selectively by partitioning to that portion of the spermatid membrane destined for the residual body.     

Identification, isolation, and in vitro culture of porcine gonocytes

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

Prepubertal expansion of dark and pale type A spermatogonia in the rhesus monkey (Macaca mulatta) results from proliferation during infantile and juvenile development in a relatively gonadotropin independent manner

The purpose of the present study was to determine whether dark and pale type A spermatogonia (Ad and Ap, respectively) are mitotically active during prepubertal development and whether proliferation of these germ cells during this protracted phase of primate development occurs predominantly during infancy before gonadotropin secretion is arrested. Four neonate (1-2 days of age), four infant (4-5 mo of age), and four juvenile (14-17 mo of age) rhesus monkeys (Macaca mulatta) were castrated 2 h after receiving an i.v. bolus of 5-bromo2'-deoxy-uridine (BrdU, 33 mg/kg body weight). Tissue was fixed in Bouin solution, and 5-microm paraffin sections were cut. Using periodic acid-Schiff reagent/Gill hematoxylin staining, the number per testis of Ad and Ap spermatogonia were determined. BrdU S-phase-labeled nuclei were identified using immunofluorescence. Conservative criteria were employed for classifying cell types, and this resulted in a fraction of A spermatogonia remaining unclassified. Ad, Ap, and the unclassified A spermatogonia each showed an approximately 4-fold increase over the 5-mo period from birth to infancy, and a similar increase was observed over the 10-mo period between infancy and the juvenile stage of development. Both Ad and Ap (and unclassified A spermatogonia) exhibited robust and similar S-phase labeling at the three stages of development. We conclude that the prepubertal expansion of Ad and Ap spermatogonia is achieved by mitotic proliferation that is relatively gonadotropin independent. This conclusion raises the question of the nature of the signal that arrests the cell cycle of Ad in adult testis.     

Fiber DNA studies of premeiotic mouse spermatogenesis

The technique of fiber DNA measurement was used to study the possibility that the lengthening of the DNA “S” phase previously reported for mouse premeiotic spermatogonia was due to a reduced number of initiation sites. The mean replicon size of neonatal mouse preleptotene cells was similar to sizes reported for adult mouse somatic cells. A slow rate of DNA chain growth was observed in all cells from day 1 through days 10–12 of age. It was felt that the meiotic entry in male mouse germ cells may involve a slower replication fork rate and other factors which increased the time between activation and replication of replicon families.     

Culture conditions for maintaining the survival and mitotic activity of rainbow trout transplantable type A spermatogonia

Germ-cell transplantation is a powerful tool for studying gametogenesis in many species. We previously showed that spermatogonia transplanted into the peritoneal cavity of trout hatchlings were able to colonize recipient gonads, and produced fully functional sperm and eggs in synchrony with the germ cells of the recipient. An in vitro-culture system enabling spermatogonia to expand, when combined with transplantation, would be valuable in both basic and applied biology. To this end, we optimized culture conditions for type A spermatogonia in the present study using immature rainbow trout at 8-10 month of age. Spermatogonial survival and mitotic activity were improved during culture in Leibovitz's L-15 medium (pH 7.8) supplemented with 10% fetal bovine serum at 10 degrees C compared with culture under standard conditions for salmonids (Hank's MEM (pH 7.3) supplemented with 25 mM HEPES and 5% FBS, and culture at 20 degrees C). Elimination of testicular somatic cells promoted spermatogonial mitotic activity. In addition, insulin, trout embryonic extract, and basic fibroblast growth factor promoted the mitosis of purified spermatogonia in an additive manner. Mitotic activity increased nearly sevenfold over 19 days of culture compared with growth factor-free conditions and was maintained for >1 month. Furthermore, the cultured spermatogonia could colonize and proliferate in recipient gonads following transplantation. This study represents the first step towards establishing a cell line that can be transplanted for use in surrogate broodstock technology and cell-mediated gene-transfer systems.     

性成熟前食蟹猴生精细胞的发育进程

目的阐明性成熟前食蟹猴生精细胞的发育进程。方法分别采集性成熟前不同年龄（0岁、0.5岁、1岁、1.5岁、2岁、2.5岁、3岁、3.5岁、4岁）食蟹猴睾丸,制作石蜡切片,进行HE染色和PAS/H染色。根据生精细胞的染色特性,分析性成熟前食蟹猴生精细胞的发育进程,并对食蟹猴精原干细胞进行初步鉴定。结果 HE染色结果显示,1岁及以下食蟹猴生精上皮上生精细胞仅有精原干细胞（包括Ad、At及Ap型精原细胞）,1.5岁食蟹猴生精上皮上开始出现B型精原细胞,3岁食蟹猴生精上皮上出现精母细胞,4岁食蟹猴生精上皮上出现从精原干细胞到精子的所有生殖细胞。PAS/H染色结果显示,1～2.5岁食蟹猴Ad型精原细胞胞质呈PAS阳性,At型精原细胞胞质呈PAS弱阳性,Ap型精原细胞胞质呈PAS阴性;其他生精细胞及支持细胞胞质呈阴性;0.5岁及以下,3岁及以上食蟹猴生精细胞的胞质PAS/H染色特性与前者存在差异。结论本文详细阐述了性成熟前食蟹猴生精细胞随年龄增长的渐次性发育模式,并建立了性成熟前食蟹猴精原干细胞原位鉴定的一种新方法,这些研究结果为食蟹猴精原干细胞的其他相关研究奠定了基础。     

Culture of porcine spermatogonia: effects of purification of the germ cells, extracellular matrix and fetal calf serum on their survival and multiplication

Initial studies to establish an in vitro system allowing survival and multiplication of porcine spermatogonia are described. Purified spermatogonia from 3-week-old pigs were cultured for 9 days alone or in the presence of Sertoli cells in either control medium or in medium supplemented with 5%, fetal calf serum (FCS). Under either condition the number and the viability of the cells decreased with time. but both parameters were positively influenced by the presence of FCS. However, very few, if any, spermatogonia were able to take up BrdU under either condition. In another series of experiments, small fragments of seminiferous tubules from 3-week-old pigs were cultured in the presence of FCS, or seeded on an extracellular matrix. Under these conditions the number of cells decreased between day 0 and day 2 or day 5, then it remained roughly constant until the end of the culture. The number of spermatogonia decreased 2.5 fold during the two-week culture period. Spermatogonia were able to incorporate BrdU until the end of the experiment. The number of BrdU-labeled spermatogonia was higher when tubule-segments were seeded on an extracellular matrix. Then, the effects of the association of FCS and extracellular matrix were tested. The number of spermatogonia, during the whole culture period, was higher in serum-containing cultures than in serum-free cultures. As for the number of spermatogonia able to incorporate BrdU at -different days, is decreased 3 fold between day 2 and 14 irrespective of the culture conditions. By contrast, the number of spermatogonia, labeled with BrdU between day 1 and 2, measured on days 5 to 14 of culture, was higher in serum-containing cultures. Finally, the number of spermatogonia labeled between day 1 and 2 was higher from day 5 onward than the number of spermatogonia able to take up BrdU between days 4 and 13. Taken together, these results indicate that intercellular communication and extracellular matrix are important for spermatogonia multiplication and that FCS promotes the survival of spermatogonia under in vitro conditions.     

Phenotypic changes in germ cells during gonadal development of the common carp (Cyprinus carpio)

A procedure is described in which large early spermatogonia were isolated from carp testes and purified from an initial 4–5% recovery up to 60–70% using equilibrium density centrifugation on a continuous Percoll gradient. Mice were immunized with the spermatogonia via the intrasplenic route. Six hybridoma cultures, producing monoclonal antibodies (MAbs) reacting selectively with germ cells, were selected and further analysed. Reactivity with five of these MAbs was observed on primordial germ cells (PGCs) in the developing indifferent gonads at the onset of proliferation, i.e. the age of 7 weeks. One MAb, encoded WCG 6, appeared to define a new surface marker on PGCs being gradually expressed on the surface membrane between the age of 2 and 4 weeks, concomitantly with an increase in size of these mitotically silent cells. The reactivity of germ cells with five of the MAbs disappeared completely (WCG 7, 12, 15, 21) or nearly completely (WCG 6) during spermatogenesis, providing a striking difference from patterns obtained with MAbs raised previously against carp spermatozoa. Differences between male and female germ cells were not observed with the WCG-MAbs during gonad development, indicating that a common set of surface antigens is shared between germ cells of both sexes up to and including spermatogonia and oogonia.Abbreviation WCG Wageningen carp spermatogonia antibody     

Phenotypic changes in germ cells during gonadal development of the common carp (Cyprinus carpio). An immunohistochemical study with anti-carp spermatogonia monoclonal antibodies.

A procedure is described in which large early spermatogonia were isolated from carp testes and purified from an initial 4-5% recovery up to 60-70% using equilibrium density centrifugation on a continuous Percoll gradient. Mice were immunized with the spermatogonia via the intrasplenic route. Six hybridoma cultures, producing monoclonal antibodies (MAbs) reacting selectively with germ cells, were selected and further analysed. Reactivity with five of these MAbs was observed on primordial germ cells (PGCs) in the developing indifferent gonads at the onset of proliferation, i.e. the age of 7 weeks. One MAb, encoded WCG6, appeared to define a new surface marker on PGCs being gradually expressed on the surface membrane between the age of 2 and 4 weeks, concomitantly with an increase in size of these mitotically silent cells. The reactivity of germ cells with five of the MAbs disappeared completely (WCG 7, 12, 15, 21) or nearly completely (WCG 6) during spermatogenesis, providing a striking difference from patterns obtained with MAbs raised previously against carp spermatozoa. Differences between male and female germ cells were not observed with the WCG-MAbs during gonad development, indicating that a common set of surface antigens is shared between germ cells of both sexes up to and including spermatogonia and oogonia.     

Magnetic cell sorting is a fast and effective method of enriching viable spermatogonia from Djungarian hamster, mouse, and marmoset monkey testes.

Germ cell transplantation, which offers promising new approaches for research and clinical applications, has focused interest on spermatogonia. This paper describes a procedure that permits the isolation of large quantities of viable spermatogonia. The immunomagnetic isolation procedure was applied to testicular cell suspensions from photoinhibited and photostimulated Djungarian hamsters, mice, and marmoset monkeys. The cells were incubated with a polyclonal rabbit anti-c-kit IgG, binding of which was characterized by immunohistochemical staining. For magnetic labeling, a secondary anti-rabbit IgG conjugated to ferromagnetic microbeads was used. Separation columns allowed the retention of magnetically labeled cells within the matrix. The magnetic fractions were eluted after removal of the column from the magnetic field. All fractions were analyzed for cellular morphology and by flow cytometry. The final enrichment of c-kit-positive cells in the magnetic fraction using fully active testes was in the range of 25-55% with a viability rate of 80-90%. The magnetic fractions of all three species were characterized by high numbers of diploid cells. Cytological analysis revealed a strong enrichment of spermatogonia. No haploid cells were retained in the magnetic fraction. In comparison to conventional procedures, magnetic cell separation is an efficient and fast approach for isolation of spermatogonia.     

棕色田鼠睾丸及附睾胚后发育的形态学变化

通过组织学方法,对产后1 d、10 d、25 d、45 d、60 d及70 d的棕色田鼠Lasiopodomys mandarinus睾丸和附睾发育进行了观察,以探讨其精子发生特点.结果 发现,1 d棕色田鼠的生殖细胞主要是生殖母细胞和前精原细胞;10 d出现大量精原细胞,睾丸间质细胞明显;25 d出现精子细胞;45 d有少量精子出现;60 d和70 d具有各级生精细胞,睾丸生精小管和附睾内出现大量成熟精子.睾丸生精小管管径和生精上皮厚度随日龄增加,于60 d达到最大;附睾管腔直径和附睾上皮厚度也于60 d达到最大.这些结果表明,棕色田鼠在生后45 d左右进入青春期,60 d左右达到性成熟,精子的产生及成熟与附睾的发育同步.     

Expression pattern of acetylated α‐tubulin in porcine spermatogonia

Mammalian spermatogonial stem cells reside on the basement membrane of the seminiferous tubules. The mechanisms responsible for maintenance of spermatogonia at the basement membrane are unclear. Since acetylated α‐tubulin (Ac‐α‐Tu) is a component of long‐lived, stable microtubules and deacetylation of α‐tubulin enhances cell motility, we hypothesized that acetylation of α‐tubulin might be associated with positioning of spermatogonia at the basement membrane. The expression pattern of Ac‐α‐Tu at different stages of testis development was characterized by immunohistochemistry for Ac‐α‐Tu and spermatogonia‐specific proteins (PGP 9.5, DAZL). In immature pig testes, Ac‐α‐Tu was present exclusively in gonocytes at 1 week of age, and in a subset of spermatogonia at 10 weeks of age. At this age, spermatogonia are migrating toward the tubule periphery and Ac‐α‐Tu appeared polarized toward the basement membrane. In adult pig testes, Ac‐α‐Tu was detected in few single or paired spermatogonia at the basement membrane as well as in spermatids and spermatozoa. Only undifferentiated (DAZL?), proliferating (determined by BrdU incorporation) spermatogonia expressed high levels of Ac‐α‐Tu. Comparison with the expression pattern of β‐tubulin and tyrosinated α‐tubulin confirmed that only Ac‐α‐Tu is specific to germ cells. The unique pattern of Ac‐α‐Tu in undifferentiated germ cells during postnatal development suggests that posttranslational modifications of microtubules may play an important role in recruiting and anchoring spermatogonia at the basement membrane. Mol. Reprod. Dev. 77: 348–352, 2010. © 2009 Wiley‐Liss, Inc.     

X-ray-induced specific-locus mutation rates in young male mice

The specific-locus mutation frequency resulting from 300 R of acute X-irradiation has been determined for the germ cells present in male mice at 2, 4, 6, 8, 10, 14, 21, 28, and 35 days of age. The sample size was large enough for each of these nine age groups to ensure that a high mutation rate would be noticed. The testis of the mouse undergoes many developmental changes between birth, when most or all germ cells are gonocytes, and 35 days, when the cell population has come to resemble that of the adult. It was important to know if the germ cells present in these developmental stages of immature male mice yield the same mutation frequency as that found earlier for spermatogonia in the adult by W. L. Russell.None of the nine age groups has a mutation rate statistically significantly higher than that of the adult. Taken together, the nine groups of males have an average mutation frequency quite to that of the adult. This does not rule out the possibility that individual age groups may have a mutation frequency somewhat different from that of the adult.The distribution of mutations among the loci seems to be similar to that found for mutations induced in spermatogonia of the adult. Clusters of specific-locus mutations were found only on day 21.This paper and that presented earlier on the newborn report the first specific-locus mutation-rate studies on male mice irradiated between birth and adulthood. If the results can be carried over to man, it can be concluded that irradiation of the immature testis, from birth to puberty, will not present any greatly increased genetic hazard over that from irradiation of the adult testis. In fact, as the data stand in the mouse, they indicate a mutation rate similar to the adult for all but the earlier stages tested and, for these stages, a probably lower rate, representing a transition from the significantly lower rate reported earlier for newborns.     

In vivo genotoxicity of nitrates and nitrites in germ cells of male mice. I. Evidence for gonadal exposure and lack of heritable effects

Effects of nitrate (doses of 600 and 1200 mg/kg/day during 14 days) and sodium nitrite (60 and 120 mg/kg/day during 14 days) on germ cells of male mice were investigated. The mode of application was stomach intubation. The germ cell stages analysed were spermatids (for the heritable effects) and differentiating and stem-cell spermatogonia (for direct effects).A lack of heritable translocations, sperm abnormalities, as well as morphological changes, such as changes in eyes, coat colour, testes and body weight, was demonstrated in F₁ males originating from treated P males. Significant effects in treated males were found with respect to: (1) sex-chromosomal univalency in the diakinesis-methaphase I stage after the treatment of stem spermatogonia (both doses of sodium nitrate and the higher dose of sodium nitrite), (2) sperm-head abnormalities after treatment of differentiating spermatogonia (the higher dose of sodium nitrate and both doses of sodium nitrite), and (3) fertility after treatment of spermatids (the higher dose of sodium nitrite). Nonmutagenic effects and possible carcinogenic potential of the tested doses are discussed.     

GABA neurones in retinas of different species and their postnatal development in situ and in culture in the rabbit retina

Summary The localisation of GABA immunoreactive neurones in retinas of a variety of animals was examined. Immunoreactivity was associated with specific populations of amacrine neurones in all species examined, viz. rat, rabbit, goldfish, frog, pigeon and guinea-pig. All species, with the exception of the frog, possessed immunoreactive perikarya in their retinal ganglion cell layers. These perikarya are probably displaced amacrine cells because GABA immunoreactivity was absent from the optic nerves and destruction of the rat optic nerve did not result in degeneration of these cells. GABA immunoreactivity was also associated with the outer plexiform layers of all the retinas studied; these processes are derived from GABA-positive horizontal cells in rat, rabbit, frog, pigeon and goldfish retinas, from bipolar-like cells in the frog, and probably from interplexiform cells in the guinea-pig retina.The development of GABA-positive neurones in the rabbit retina was also analysed. Immunoreactivity was clearly associated with subpopulations of amacrine and horizontal cells on the second postnatal day. The immunoreactivity at this stage is strong, and fairly well developed processes are apparent. The intensity of the immunoreactivity increases with development in the case of the amacrine cells. The immunoreactive neurones appear fully developed at about the 8th postnatal day, although the immunoreactivity in the inner plexiform layer becomes more dispersed as development proceeds. The immunoreactive horizontal cells become less apparent as development proceeds, but they can still be seen in the adult retina.The GABA immunoreactive cells in rabbit retinas can be maintained in culture. Cultures of retinal cells derived from 2-day-old animals can be maintained for up to 20 days and show the presence of GABA-positive cells at all stages. In one-day-old cultures the GABA immunoreactive cells lacked processes but within three days had clearly defined processes. After maintenance for 10 days a meshwork of GABA-positive fibres could also be seen in the cultures.