Seasonal differences in equine spermatocytogenesis

Spermatocytogenesis plays a pivotal role in regulation of spermatogenesis; however, its details remain relatively obscure in nonrodent species. The equine testis contains approximately 100% more spermatogonia in summer than in winter and appears to be a good model to identify the flexible components of spermatocytogenesis that cause seasonal changes in daily sperm production. Testes were taken from horses in the winter (n = 47) and in summer (n = 43). Tissues were fixed by glutaraldehyde-perfusion and submission in osmium, embedded in Epon or methacrylate, sectioned at 0.5 micron or 5 microns, stained with toluidine blue, and observed using bright-field microscopy. The combined total number of A1, A2, A3, and B1 (A plus B1) spermatogonia/testis and the numbers of B2 spermatogonia or early primary spermatocytes were determined by stereology of Epon sections involving testicular volume density and volume of spermatogonial nuclei. In a subset of horses, different spermatogonial subtypes (A1, A2, A3, and B1) were counted per 100 Sertoli cells in each of the 8 spermatogenic stages and expressed as percentage of all A plus B1 spermatogonia. The number of each spermatogonial subtype/testis for the large series of horses was calculated by multiplying the number of A plus B1 spermatogonia/testis (determined for each horse) by the percentage of that given spermatogonial subtype. Season did not significantly affect the number of any given subtype per 100 Sertoli cells in any stage or percentages of different subtypes of spermatogonia. Numbers of A1 (p less than 0.05), A2, A3, B1, or B2 spermatogonia (p less than 0.01) were greater in the breeding season.(ABSTRACT TRUNCATED AT 250 WORDS)     

High-resolution light microscopic characterization of mouse spermatogonia

Characteristics of spermatogonia were determined in the C57BL/6J strain mouse using high-resolution light microscopy of plastic-embedded tissues and identifying cells during stages of the spermatogenic cycle. The frequency of expecting each spermatogonial cell type was a major factor in identifying and categorizing various cell types. Although numerous characteristics were described, several major differences were noted in spermatogonial cell types. The group comprising A(s), A(pr), and A(al) spermatogonia could be differentiated based primarily on mottling of heterochromatin throughout the nucleus in the absence of heterochromatin lining the nuclear envelope. The A(1) cells displayed finely granular chromatin throughout the nucleus and virtually no flakes of heterochromatin along the nuclear membrane. The A(2) through A(4) spermatogonia contained progressively more heterochromatin rimming the nucleus. Intermediate-type spermatogonia displayed flaky or shallow heterochromatin that completely rimmed the nucleus. Type B spermatogonia showed rounded heterochromatin periodically along the nuclear envelope. Use of gray-scale histograms allowed objective quantification of nuclear characteristics and showed a logical shift in the gray scale to a narrower and darker profile, from four cell types leading to A(1) cells. The ability to differentiate spermatogonial types is a prerequisite to studying the behavior and kinetics of the earliest of the germ cell types in both normal and abnormal spermatogenesis.     

Immunohistochemical study of nuclear changes associated with male germ cell death and spermiogenesis

In a previous study on the effects of gestational and lactational exposure of para-nonylphenol on male rats, we noted in both induced and uninduced rats, that variations in cleaved caspase-3 immunostaining patterns were associated with distinct nuclear alterations in mainly basally located germ cells (spermatogonia and preleptotene spermatocytes). These were re-analysed and compared with cleaved caspase-3-labeled germ cells in the aging human and the spermatogenically active catfish testis. In the rat testes, cytoplasmic immunostaining was progressively associated with lateral compression of the nucleus, its break up into large pieces which can contain immunostained marginated chromatin masses. The pale remnants of the nucleus continued to shrink in size concomitant with the appearance of blue-purplish stained regions in the cytoplasm similar in color to the condensed chromatin in spermatids, a condition which was TUNEL-negative. These large clumps of chromatin also eventually disappeared, giving rise to cells resembling cytoplasmic ghosts, a condition which was TUNEL-positive. By contrast, the immunolabeled nuclei of human and catfish germ cells condensed into a single mass, after which they lost immunoreactivity. To exclude the possibility that these observations could reflect alterations in Sertoli nuclei, rat testicular sections were probed with a mouse anti-human GATA-4 monoclonal (MHM) antibody. The MHM was, however, the second of two GATA-4 antibodies tested, with a goat anti-mouse polyclonal (GMP) initially used to label the rat Sertoli nuclei. GMP unexpectedly, but distinctly labeled the complete development of the acrosome in the rat testis, a fortuitous finding with utility for staging of the seminiferous epithelium.     

Quantitative differences between variants of A spermatogonia in man

The area of cytoplasm, nucleus, nucleolus and mitochondria, as well as the elongation and irregular outline of the nucleus were determined, on electron micrographs by using an image analyser, for Ap (pale), Ad (dark with intranuclear vacuole), Ad-like (dark without intranuclear vacuole), Ac (cloudy) and Al (long) human spermatogonia. Ap and Ac spermatogonia had larger nucleus, larger nucleolus, and more cytoplasm than did Ad, Ad-like, and Al spermatogonia. In addition, the nuclei of Ap and Ac spermatogonia were more spherical and had a more distinct outline.     

Nature of the spermatogenic arrest in Dazl -/- mice

Dazl encodes an RNA-binding protein essential for spermatogenesis. Mice that are deficient for Dazl are infertile, lacking any formation of spermatozoa, and the only germ cells present are spermatogonia and a few spermatocytes. To gain more insight regarding the timing of the spermatogenic arrest in Dazl -/- mice, we studied the spermatogonial cell types present in testis sections and in seminiferous tubular whole mounts. Most of the seminiferous tubular cross-sections contained A spermatogonia as the most advanced cell type, with only very few containing cells up to pachytene spermatocytes. Both 5-bromodeoxy-uridine incorporation and mitotic index indicated that the remaining A spermatogonia were actively proliferating. C-kit immunohistochemical studies showed that most of the A spermatogonia were positively stained for the c-Kit protein ( approximately 80%). The clonal composition of the A spermatogonia in tubular whole mounts indicated these cells to be A(single) (A(s)), A(paired) (A(pr)), and A(aligned) (A(al)) spermatogonia. It is concluded that the prime spermatogenic defect in the Dazl -/- mice is a failure of the great majority of the A(al) spermatogonia to differentiate into A(1) spermatogonia. As a result, most seminiferous tubules of Dazl -/- mice only contain actively proliferating A(s), A(pr), and A(al) spermatogonia, with cell production being equaled by apoptosis of these cells.     

c-Flip(L) is expressed in undifferentiated mouse male germ cells

Apoptosis represents a fundamental process during fetal/post-natal testis development. Therefore pro- and anti-apoptotic proteins are essential to regulate testis physiology. c-Flip(L) is a known inhibitor of caspase 8/10 activity; in this study its perinatal expression in mouse male germ cells was investigated. In testis sections and seminiferous tubule whole mount c-Flip(L) was found to be expressed in undifferentiated spermatogonia and to co-localize with germ stem cells markers. In vivo investigations in the vitamin-A deficient mouse, lacking differentiated germ cells, confirmed c-Flip(L) expression in undifferentiated spermatogonia. Further analyses showed Fas expression but no significant caspase 8/10 activity when c-Flip(L) was highly expressed. Altogether these data suggest that c-Flip may control the survival rate of undifferentiated spermatogonia.     

A study on the different types of spermatogonia in buffalo (Bubalus bubalis).

As a first step to understanding spermatogenesis in the buffalo bull the cytological details of different types of spermatogonia were determined in adult buffalo bulls. Morphological changes in the nuclear details were used as a basis for classifying the different types of spermatogonia. The type A spermatogonia had a spherical to ovoid nucleus with finely granulated chromatin, homogeneously dispersed in the nucleoplasm and having one to two nucleoli adhering to the nuclear membrane. The type A0 spermatogonia were characterized by nuclei containing moderately stained, finely granulated chromatin and a nucleolus attached to the nuclear envelope. The A1 type spermatogonia, on the other hand, have pale stained, finely granulated chromatin with the nucleolus adhering to the nuclear membrane. The nuclei of A2 type spermatogonia resembled those of type A1, but contained coarse granular chromatin dispersed in the pale nucleoplasm. The intermediate type of spermatogonia acquired a central position of the nucleolus, but the chromatin remained coarsely granulated and non-clumped. Three classes of type B (B1-B3) spermatogonia were determined on the degree of clumping of the chromatin and the central position of the nucleolus. The type B1 cells were characterized by nuclei containing a few flakes of lightly stained chromatin and a centrally located nucleolus. The type B2 cells showed comparatively more clumping of chromatin than type B1 spermatogonia, which was dispersed at random in the pale nucleoplasm and along the nuclear envelope. The type B3 spermatogonia demonstrated chromophilic chromatin dispersed in the slightly grey nucleoplasm and adhering along the nuclear membrane. Since there seems to be a succession of events following differentiation of type A1 spermatogonia till the last type B cell differentiates into resting primary spermatocytes, may intermediate stages between the presently described classes of type A (A0-A2) and type B (B1-B3) could also be located in sections of the seminiferous tubules.     

Morphological characteristics of the spermatogonial stem cells in man

The present investigation is concerned with establishing morphological criteria of spermatogonial stem cells in man. Testicular biopsies from patients having undergone semicastration for malignant tumors and radio- and chemotherapy for one year following the operation were studied light and electron microscopically. Those spermatogonial types that survived the treatment were regarded as stem cells in view of the fact that the stem cells, in contrast to the more differentiated spermatogonia, are radiation resistant and less sensitive to various noxious agents. In 7 out of 28 cases examined, a small number of spermatogonia was found adjacent to the basement membrane. The majority of these cells show the characteristic features of pale type A spermatogonia, while a few cells may represent variants of this cell type. The dark type A spermatogonia are almost completely eliminated from the seminiferous tubules. A concept is proposed that the stem cells of the human testis may be derived from the pale type A spermatogonia or the variants of this cell type.     

Involvement of the D-type cyclins in germ cell proliferation and differentiation in the mouse

Using immunohistochemistry, the expression of the D-type cyclin proteins was studied in the developing and adult mouse testis. Both during testicular development and in adult testis, cyclin D(1) is expressed only in proliferating gonocytes and spermatogonia, indicating a role for cyclin D(1) in spermatogonial proliferation, in particular during the G(1)/S phase transition. Cyclin D(2) is first expressed at the start of spermatogenesis when gonocytes produce A(1) spermatogonia. In the adult testis, cyclin D(2) is expressed in spermatogonia around stage VIII of the seminiferous epithelium when A(al) spermatogonia differentiate into A(1) spermatogonia and also in spermatocytes and spermatids. To further elucidate the role of cyclin D(2) during spermatogenesis, cyclin D(2) expression was studied in vitamin A-deficient testis. Cyclin D(2) was not expressed in the undifferentiated A spermatogonia in vitamin A-deficient testis but was strongly induced in these cells after the induction of differentiation of most of these cells into A(1) spermatogonia by administration of retinoic acid. Overall, cyclin D(2) seems to play a role at the crucial differentiation step of undifferentiated spermatogonia into A(1) spermatogonia. Cyclin D(3) is expressed in both proliferating and quiescent gonocytes during testis development. Cyclin D(3) expression was found in terminally differentiated Sertoli cells, in Leydig cells, and in spermatogonia in adult testis. Hence, although cyclin D(3) may control G(1)/S transition in spermatogonia, it probably has a different role in Sertoli and Leydig cells. In conclusion, the three D-type cyclins are differentially expressed during spermatogenesis. In spermatogonia, cyclins D(1) and D(3) seem to be involved in cell cycle regulation, whereas cyclin D(2) likely has a role in spermatogonial differentiation.     

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.     

Identification of 5-Bromo-2’-Deoxyuridine-Labeled Cells during Mouse Spermatogenesis by Heat-Induced Antigen Retrieval in Lectin Staining and Immunohistochemistry

DNA replication occurs during S-phase in spermatogonia and preleptotene spermatocytes during spermatogenesis. 5-Bromo-2’-deoxyuridine (BrdU) is incorporated into synthesized DNA and is detectable in the nucleus by immunohistochemistry (IHC). To identify BrdU-labeled spermatogenic cells, the spermatogenic stages must be determined by visualizing acrosomes and detecting cell type-specific marker molecules in the seminiferous tubules. However, the antibody reaction with BrdU routinely requires denaturation of the DNA, which is achieved by pretreating tissue sections with hydrochloric acid; however, this commonly interferes with further histochemical approaches. Therefore, we examined optimal methods for pretreating paraffin sections of the mouse testis to detect incorporated BrdU by an antibody and, at the same time, visualize acrosomes with peanut agglutinin (PNA) or detect several marker molecules with antibodies. We found that the use of heat-induced antigen retrieval (HIAR), which consisted of heating at 95C in 20 mM Tris-HCl buffer (pH 9.0) for 15 min, was superior to the use of 2 N hydrochloric acid for 90 min at room temperature in terms of the quality of subsequent PNA-lectin histochemistry with double IHC for BrdU and an appropriate stage marker protein. With this method, we identified BrdU-labeled spermatogenic cells during mouse spermatogenesis as A1 spermatogonia through to preleptotene spermatocytes.     

CDH1 is a specific marker for undifferentiated spermatogonia in mouse testes

In the mammalian testis, spermatogenesis is initiated from a subset of stem cells belonging to undifferentiated type A spermatogonia. In spite of the biologic significance of undifferentiated type A spermatogonia, little is known about their behavior and properties because of a lack of specific cell surface markers. Here we show that CDH1 (previously known as E-cadherin) is expressed specifically in undifferentiated type A spermatogonia in the mouse testis. Histologic analysis showed that CDH1-positive cells had all the characteristics of undifferentiated type A spermatogonia. Whole-mount immunohistochemistry showed that CDH1-positive cells made clusters mainly comprising one, two, four, or eight cells. They survived after administration of the cytotoxic agent busulfan to mice, and then regenerated seminiferous epithelia. Transplantation experiments showed that only CDH1-positive cells had colonizing activity in the recipient testis. Our data clearly demonstrated that spermatogenic stem cells reside among undifferentiated type A spermatogonia, which express CDH1.     

The ultrastructure of the nuclei and the behaviour of the sex chromosomes of human spermatogonia

Summary The nuclear structure of human spermatogonia has been studied with electron microscopical and histochemical methods. Type B spermatogonia have chromatin clumps without any special ultrastructure and several nucleoli. Five different types of nuclear bodies, and besides, a nuclear vacuole, have been observed in type A spermatogonia. Type I bodies are typical nucleoli consisting of three regions: amorphous, fibrillar and granular. Type II, III and V are considered to be atypical nucleoli. Type IV bodies are small chromatin condensations. Type I bodies are the only ones in which RNA was demonstrated by light histochemical techniques and no PAS positive material was found inside the nuclei. The absence of any special ultrastructure in the chromatin from spermatogonia, and the small mass of the chromatin condensations, show that the human X chromosome and perhaps the Y chromosome are not heteropycnotic in the interphasic nuclei of human spermatogonia.Abbreviations Used RNA ribonucleic acid - gonia spermatogonia This work has been supported by a grant (No. 2623) of the Consejo Nacional de Investigaciones Cientificas y Tecnicas, and partially by a grant (C.M. 6522) from the Population Council.We wish to thank Professor R. E. Mancini for his suggestions during this investigation and his support for its achievement, and to Dr. J. C. Lavieri for providing the biopsies.     

Transition of basic protein during spermatogenesis of <Emphasis Type="Italic">Fenneropenaeus chinensis</Emphasis> (Osbeck, 1765)

According to the ultrastructural characteristic observation of the developing male germ cells, spermatogenesis of the crustacean shrimp, Fenneropenaeus chinensis, is classified into spermatogonia, primary spermatocytes, secondary spermatocyte, four stages of spermatids, and mature sperm. The basic protein transition during its spermatogenesis is studied by transmission electron microscopy of ammoniacal silver reaction and immunoelectron microscopical distribution of acetylated histone H4. The results show that basic protein synthesized in cytoplasm of spermatogonia is transferred into the nucleus with deposition on new duplicated DNA. In the spermatocyte stage, some nuclear basic protein combined with RNP is transferred into the cytoplasm and is involved in forming the cytoplasmic vesicle clumps. In the early spermatid, most of the basic protein synthesized in the new spermatid cytoplasm is transferred into the nucleus, and the chromatin condensed gradually, and the rest is shifted into the pre-acrosomal vacuole. In the middle spermatid, the nuclear basic protein linked with DNA is acetylated and transferred into the proacrosomal vacuole and assembled into the acrosomal blastema. At the late spermatid, almost all of the basic protein in the nucleus has been removed into the acrosome. During the stage from late spermatid to mature sperm, some de novo basic proteins synthesized in the cytoplasm belt transfer into the nucleus without a membrane and almost all deposit in the periphery to form a supercoating. The remnant histone H4 accompanied by chromatin fibers is acetylated in the center of the nucleus, leading to relaxed DNA and activated genes making the nucleus non-condensed.     

Spermatogenic cells of the prepuberal mouse: isolation and morphological characterization

A procedure is described which permits the isolation from the prepuberal mouse testis of highly purified populations of primitive type A spermatogonia, type A spermatogonia, type B spermatogonia, preleptotene primary spermatocytes, leptotene and zygotene primary spermatocytes, pachytene primary spermatocytes and Sertoli cells. The successful isolation of these prepuberal cell types was accomplished by: (a) defining distinctive morphological characteristics of the cells, (b) determining the temporal appearance of spermatogenic cells during prepuberal development, (c) isolating purified seminiferous cords, after dissociation of the testis with collagenase, (d) separating the trypsin-dispersed seminiferous cells by sedimentation velocity at unit gravity, and (e) assessing the identity and purity of the isolated cell types by microscopy. The seminiferous epithelium from day 6 animals contains only primitive type A spermatogonia and Sertoli cells. Type A and type B spermatogonia are present by day 8. At day 10, meiotic prophase is initiated, with the germ cells reaching the early and late pachytene stages by 14 and 18, respectively. Secondary spermatocytes and haploid spermatids appear throughout this developmental period. The purity and optimum day for the recovery of specific cell types are as follows: day 6, Sertoli cells (purity>99 percent) and primitive type A spermatogonia (90 percent); day 8, type A spermatogonia (91 percent) and type B spermatogonia (76 percent); day 18, preleptotene spermatocytes (93 percent), leptotene/zygotene spermatocytes (52 percent), and pachytene spermatocytes (89 percent), leptotene/zygotene spermatocytes (52 percent), and pachytene spermatocytes (89 percent).     

Distribution of type A spermatogonia in the mouse is not random

The distribution of type A spermatogonia was studied using drawings of cross-sectioned tubules at various stages of the spermatogenic cycle of perfusion-fixed, epoxy-embedded mouse testis. Spermatogonia were classified as either positioned opposite the interstitium or opposite the region where two tubules make contact or in a defined, intermediate region at which the two tubules diverged. At stage V, the population of type A spermatogonia, comprised of A(s) through A(al) cells, is randomly positioned around the periphery of the seminiferous tubule. The A(s) through A(al) population becomes nonrandomly distributed beginning at stage VI, being located primarily in regions where the tubule opposes the interstitium, and remains nonrandom through stage III of the next cycle. The A(1) spermatogonia of stage VII, derived from most A(pr) and A(al) spermatogonia, and the A(2) spermatogonia of stage IX, derived from the A(1) spermatogonia, are also nonrandomly positioned opposing the interstitium. However, the A(3) population of stage XI becomes randomly distributed around the tubule. To our knowledge, these are the first data to show that the more primitive spermatogonial types (A(s) to A(al)) move to specific sites within the seminiferous tubule. Division of the regularly spaced, more primitive spermatogonia (A(s) to A(al)) leads to the spread of their progeny (A(1) to A(4)) laterally along the base of the seminiferous tubule. The lateral spread from more or less evenly spaced foci ensures that spermatogenesis is conducted uniformly around the entire tubule. The data also suggest that the position of a seminiferous tubule in the mouse is stabilized in relationship to other seminiferous tubules.     

On the Fine Structure of the Nervous System of Tubiluchus philippinensis (Tubiluchidae,Priapulida)

At the mouth tube/introvert border a circumenteric intraepithelial nerve ring occupies a circular ridge protruding into the body cavity. The ring has a centrally located neuropile nearly free of perikarya and two zones of different perikarya above and below the neuropile. Presumably non-neuronal perikarya have an oval nucleus, large heterochromatin clumps and marked filament bundles. Such elements resemble tanycytic glial cells. Two types of presumably neuronal perikarya contain small cytoplasmic granules, similar to those in nerve fibre profiles. One of these neurons has a pale nucleus with a prominent nucleolus, the other a rather inconspicuous nucleus similar to that of the tanycytic cells. The neuronal processes of the fibre ring differ in diameter and contain clear and dense core vesicles, small granules (high or medium electron density) or granules with a dense periphery and a light centre. Sometimes neighbouring processes seem interconnected by electrical synapses. Images suggesting chemical synapses are rare. A large intraepithelial nerve lies in the wall of the introvert and ventral body wall close to the musculature, possibly innervated by this nerve. Frontal of the anus lies an intraepithelial ganglion demonstrating again a central neuropile. two neuronal types and tanycytic elements with filament bundles. Comparative aspects of the characters of the Tubiluchus nervous system are also discussed.     

Change of cyclin D2 mRNA expression during murine testis development detected by fragmented cDNA subtraction method

Using subtractive hybridization and polymerase chain reaction, we developed a differential cloning system, the fragmented cDNA subtraction method, that requires only small amounts of materials. The cloning system was used to isolate several cDNA fragments expressed more abundantly in the premeiotic day 3 post-natal mouse testis than in the adult mouse testis. The isolated cDNA fragments included cDNA encoding the murine cyclin D2. Northern blot and in situ hybridization analyses revealed that, during testis development, cyclin D2 expression was most abundant in the neonatal proliferating Sertoli cells. Those type A spermatogonia that were thought to divide mitotically also expressed cyclin D2 mRNA. Other spermatogenic cells, such as mitotically arrested gonocytes in neonatal testis and meiotically dividing germ cells in adult testis as well as adult Sertoli cells, were negative for the cyclin D2 signal. Adult W/W ^v mutant mice lacking germ cells expressed cyclin D2 mRNA in terminally differentiated Sertoli cells. Elimination of germ cells other than the undifferentiated type A spermatogonia by treating wild-type mice with an anti-c- kit monoclonal antibody did not result in the expression of cyclin D2 in Sertoli cells. These results demonstrate that there are lineage- and developmental-specific expression patterns of cyclin D2 mRNA during mouse testis development. At the same time, it is suggested that primitive type A spermatogonia affect the cyclin D2 expression of Sertoli cells.