THE SPERMATOGONIAL STEM CELL POPULATION IN ADULT RATS

Radioautographed whole mounted seminiferous tubules from adult rat testes were used to analyse undifferentiated type A spermatogonia at various intervals up to 81 hr following a single injection of ³H-TdR. the data obtained led to the identification of the spermatogonial stem cell and to the formulation of a new model for spermatogonial renewal and differentiation. Undifferentiated type A cells were morphologically alike, but were topographically classified as (1) isolated or (2) paired and aligned. Although labeled isolated A cells were scattered over most stages of the seminiferous epithelium, their proliferative activity varied with the stage; their labeling index was 20-30% in stages I and II, but less than 1% in stages VII and VIII. By tracing the labeled divisions of isolated A spermatogonia in time, it was seen that some daughter cells became separated from one another to form two new isolated cells, while others remained together as paired A spermatogonia. Analysis of two successive waves of labeled mitoses revealed that most paired A spermatogonia continued to proliferate forming four aligned A cells, many of which divided again to produce a chain of eight and so on. the greatest incidence of labeling among paired and aligned A spermatogonia occurred in stages XIII-III. In stage I, where the labeling index was 50%, the calculated proliferative fraction was 1 for these spermatogonia. Between stages II and V, they began to leave mitotic cycle, and during stage V this entire cohort morphologically transformed into A₁ spermatogonia. Labeled metaphase curves for undifferentiated A spermatogonia were distinct from any of the curves previously constructed for the six classes of differentiating spermatogonia, especially because of particularly long S and G₂ phases in the former. the cell cycle time of paired and aligned A cells was 55 hr, compared to an average of 42 hr for differentiating types A₂ to B.     

SPERMATOGENETIC CLONES DEVELOPING FROM REPOPULATING STEM CELLS SURVIVING A HIGH DOSE OF AN ALKYLATING AGENT

We investigated stem cell renewal and differentiation in 10- and 15-days-old spermatogonial clones developing in mouse seminiferous epithelium after an extremely large cell loss, inflicted by high doses of the alkylating agent Myleran. The spermatogonial clones arise from cells that resemble the A_is spermatogonia but have a larger nuclear diameter. In spite of their mitotic activity these ‘re-populating stem cells’ lie mainly isolated or in pairs. This is explained by migration and differentiation. Migration appeared to occur at random in all directions along the basement membrane of the seminiferous tubule. After one or more divisions of the stem cells, a second type of cell appears, which is called the ‘differentiating spermatogonium’. The time elapsing before this type of cell appears, depends on the dose of Myleran: the larger the dose the later differentiation starts. A relation could be demonstrated between the stage of the cycle of the seminiferous epithelium and the start of differentiation. Differentiating cells were found isolated or in groups of two, four, eight or sixteen cells. Hence we concluded that at least up to their fourth division differentiating cells divide synchronously without degenerations. Three types of division of repopulating stem cells were distinguished, producing (1) two repopulating stem cells, (2) one repopulating stem cell and one cell starting spermatogonial differentiation, or (3) two differentiating cells. Type 1 divisions were found most frequently.     

Morphological characterization of the testicular cells and seminiferous epithelium cycle in six species of Neotropical bats

We know little about the process of spermatogenesis in bats, a great and diverse clade of mammals that presents different reproductive strategies. In the present study, spermatogenesis in six species of Neotropical bats was investigated by light microscopy. On the basis of chromatin condensation, nuclear morphology, relative position to the basal membrane and formation of the flagellum, three types of spermatogonia were recognized: dark type A (A_d), pale type A (A_p), and type B; the development of spermatids was divided into seven steps. With the exception of Myotis nigricans, the seminiferous epithelium cycle of the other five species studied was similar to those of other mammals, showing gradual stages by the tubular morphology method. Asynchrony was observed in the seminiferous epithelium cycle of M. nigricans, shown by overlapping stages and undefined cycles. The frequencies found in the three phases of the cycle were variable with the greatest frequency occurring in the postmeiotic phase (>50%) and the least in the meiotic phase (<10%). The similarities observed in the five species of Phyllostomidae appeared to be related to their phylogenetic relationship and shorter divergence times, whereas the differences in M. nigricans appeared to be related to its greater phylogenetic distance because the Vespertilionidae family diverged earlier. J. Morphol., 2009. © 2009 Wiley‐Liss, Inc.     

Evaluation of the seminiferous epithelial cycle, spermatogonial kinetics and niche in donkeys (Equus asinus)

Kinetics of spermatogonia as well as localization in niches have been described in rodents, but rarely in large animals or in species of economical interest. In this regard, and envisioning the possibility of spermatogonial transplantation from donkeys (Equus asinus) to mules (Equus mulus mulus), many variables that may contribute for an enhanced understanding of the spermatogonial biology in donkeys were investigated. Testes from five adult donkeys were routinely processed for high-resolution light microscopy. Donkey seminiferous epithelium can be divided in XII stages based on the development of the acrosomal system. In addition, spermatogonial morphology and morphometric analysis were performed allowing the characterization of two groups of spermatogonia: undifferentiated (A_und) and differentiating (A₁, A₂, A₃, B₁ and B₂). A_und spermatogonia were present along all XII stages of the seminiferous epithelium cycle of this species, whereas differentiating spermatogonia were only at specific stages. Number of differentiating spermatogonia gradually increased as the cycle progressed, despite the apparent rigid regulation of the balance between mitosis and apoptosis throughout the spermatogenic process. Understanding of spermatogonial biology and kinetics in donkeys, revealed that type A_und spermatogonia are located in specific microenvironments, the spermatogonial niches. The present results enhance understanding of spermatogonial biology in donkeys providing information about subtypes, morphology, number and mitosis/apoptosis along the seminiferous epithelium cycle.     

Observation on the cycle of the seminiferous epithelium in the Japanese macaque (Macaca fuscata) using semithin sections

The stages of the cycle of the seminiferous epithelium in the Japanese macaque are investigated using testes fixed by a mixture of formaldehyde and glutaraldehyde containing picric acid and embedded in a methacrylate resin, Quetol 523M. Sections, 1.0–2.0 μm in thickness, were cut with glass knives and stained with periodic acid-Schiff (PAS) and hematoxylin. Sections from such resin blocks illustrated cellular detail without structural distortion during the polymerization process. Furthermore, staining affinity with PAS and hematoxylin was excellent. In stained sections, typical germ cell associations were described, based on the nuclear morphology of type A (dark and pale) spermatogonium, type B spermatogonium, various developmental stages of primary spermatocytes during meiosis, and the development of the acrosomic system. In the Japanese macaque, two different steps of spermatids (steps 3 and 4) were constantly seen in the same area of the tubular epithelium during stage III. Therefore, a classification into ten stages is proposed for the cycle in this species. Additional characteristics are described based on the observation of the seminiferous epithelium using semithin sections.     

Spermatogonia and the cycle of the seminiferous epithelium in the nine-banded armadillo

Summary The cycle of the seminiferous epithelium of the nine-banded armadillo can be divided into ten stages. As in most mammals, only one stage is observed per tubular cross-section. The process of spermiogenesis can be divided into thirteen steps according to the development of the acrosomal system and the flagellum. Four generations of spermatogonia are observed in the germinal epithelium: 1) stem cells, 2) type A, 3) intermediate, and 4) type B spermatogonia. The stem cell is characterized by a highly irregular nucleus and the presence of glycogen in its cytoplasm. The type A spermatogonium contains an oblong nucleus with one or two shallow infoldings of the nuclear membrane. The intermediate spermatogonium contains an ovoid nucleus characterized by one or two nuclei and heterochromatin scattered in the nucleoplasm. The nucleus of the type B spermatogonium is more spherically shaped with a centrally placed nucleolus and heterochromatin associated with the nuclear envelope.The author wishes to acknowledge the technical assistance of Teri Lane     

X-irradiation--induced changes in the progression of type B spermatogonia and preleptotene spermatocytes

In response to induced DNA damage, proliferating cells arrest in their cell cycle or go into apoptosis. Ionizing radiation is known to induce degeneration of mammalian male germ cells. The effects on cell-cycle progression, however, have not been thoroughly studied due to lack of methods for identifying effects on a particular cell-cycle phase of a specific germ cell type. In this study, we have utilized the technique for isolation of defined segments of seminiferous tubules to examine the cell-cycle progression of irradiated rat mitotic (type B spermatogonia) and meiotic (preleptotene spermatocytes) G1/S cells. Cells irradiated as type B spermatogonia in mitotic S phase showed a small delay in progression through meiosis. Thus, it seems that transient arrest in the progression can occur in the otherwise strictly regulated progression of germ cells in the seminiferous epithelium. Contrary to the arrest observed in type B spermatogonia and in previous studies on somatic cells, X-irradiation did not result in a G1 delay in meiotic cells. This lack of arrest occurred despite the presence of unrepaired DNA damage that was measured when the cells had progressed through the two meiotic divisions.     

Spermatogonial Multiplication In the Chinese Hamster. Iv. Search For Long Cycling Stem Cells

ABSTRACT In the Chinese hamster, 17 days, i. e. one cycle of the seminiferous epithelium, after two injections of [³H]TdR given 24 hr apart, labelled cells were found among all types of spermatogonia, including stem cells (A_s). These labelled A_s spermato-gonia derive from one or more self-renewing divisions of the stem cells that originally incorporated [³H]TdR. In the steady state, half of the divisions of the A_s will be self-renewing and the other half will give rise to A_pr spermatogonia that will ultimately become spermatozoa. Theoretically, the labelling index (LI) after 17 days will be similar to that after 1 hr, and in this study twice as high as for the 1-hr interval since only one injection was given. However, experimental values only half that of the theoretical LI were found after 17 days. the following causes for the loss of labelled stem cells are discussed: (1) dilution of label because of division; (2) influx of unlabelled components of false pairs (i. e. newborn stem cells that still have to migrate away. mostly during G₁, from their sister cells and are scored as A_pr spermatogonia) between 1 hr and 17 days; (3) the existence of long- and short-cycling stem cells, probably combined with preferential differentiation of the short-cycling elements; (4) selective segregation of DNA at stem cell mitosis; and (5) irradiation death of radiosensitive labelled stem cells. As it is not impossible that factors 1, 2, 4 and 5 together account for the total loss of labelled stem cells, LI results do not provide evidence for the existence of separate classes of short- and long-cycling stem cells. The distributions of the LIs of the A_s, A_pr and A_al spermatogonia over the stages of the epithelial cycle at 17 days are similar to those at 1 hr after injection. Hence the regulatory mechanisms that govern the stimulation and inhibition of proliferation of A_s that give rise to new A_s for the next epithelial cycle are similar to those of the A_s that will divide into A_pr spermatogonia during the same epithelial cycle. Grain counts revealed that more [³H]TdR is incorporated into A_s, A_pr and A_al spermatogonia that are in S phase during epithelial stages X-IV than in stages V-IX.     

Renewal of spermatogonia in the monkey (Macaca fascicularis)

Populations of different types of spermatogonia and their mitotic activity were analyzed in the monkey Macaca fascicularis: 3 adults aged 5-6 yr and 3 young aged 2-3 mo. Two young and two adult monkeys received injections of 3H-thymidine for radioautographic study of the relationships between Type A spermatogonia: dark Type A (Ad), pale Type A (Ap) and transition Type A (At). In the adult the number of Ad and At spermatogonia did not change significantly throughout the seminiferous epithelium cycle. The number of Ap spermatogonia doubled at Stage VII, and half divided at Stage IX to give rise to B1 spermatogonia. The durations of the seminiferous epithelium cycle and spermatogenesis were estimated as 10.5 days and 42 days respectively. In the young and adult monkeys, some Ap spermatogonia and a lesser number of At spermatogonia were labeled one h after injection of precursor. At longer intervals after injection, the number of labeled At spermatogonia increased significantly, and some Ad as well as Ap spermatogonia were also labeled. These results indicate that Ap spermatogonia are renewal stem cells, and Ad spermatogonia are reserve stem cells. The differences in labeling after isotope exposure suggest that Ap cells may give rise successively to At and Ad cells.     

SPERMATOGONIAL CHALONE(S): EFFECT ON THE PHASES OF THE CELL CYCLE OF TYPE A SPERMATOGONIA IN THE RAT

Adult rats with X-irradiated testes were used to analyze the effect of the spermatogonial chalone(s) on the phases of the cell cycle of type A spermatogonia. Twelve days after irradiation, the animals were used in two experiments designed to test the existence of hypothetical G₂ and S phase chalones. For the G₂ assay, rats injected twice with testicular extract (Group I), liver extract (Group II) or physiological saline (Group III) were killed 10 hr after the initial injection. Mitoses of type A, Intermediate and type B spermatogonia were counted in whole mounts of dissected seminiferous tubules. To test for an S phase inhibitor, two groups of rats were given multiple injections of either testicular extract (Group IV) or saline solution (Group V). Twenty-two hr after the first injection they were injected with [³H]thymidine and killed 2 hr later. Silver grains over labelled type A nuclei were counted in radioautographed sections of testes from these animals. The average grain counts were identical in Groups IV and V, indicating that the testicular extract did not affect type A spermatogonia during the S phase. Counts of type A mitoses in Groups I, II and III revealed that in the animals injected with the testicular extract (Group I) the number of divisions was 50% lower than in the control groups (Groups II and III). In contrast, mitotic activity of differentiating spermatogonia (In + B) was similar in all three groups of animals. This result is attributed to a testicular chalone which specifically inhibits type A spermatogonia during the G₂ phase of the cell cycle. Indirect evidence for a G₁ spermatogonial chalone is also presented, as a result of an analysis of published data (Clermont & Mauger, 1974).     

Testicular structure and spawning cycle in the silvery croaker, <Emphasis Type="Italic">Otolithes ruber</Emphasis> (Perciformes: Sciaenidae) in the Kuwaiti waters of the Arabian Gulf

The structure of the testes and maturity stages in the male silvery croaker, Otolithes ruber were investigated from March 1999 to March 2000. Based on the location of spermatogonia within the germinal epithelium, the testis structure is classified as the unrestricted spermatogonial testicular type. Germ cells proliferate through mitotic divisions of spermatogonia, giving rise to primary and secondary spermatocytes, which through meiotic divisions transform into spermatids. As spermatogenesis progresses, an elongation of the testicular lobules takes place. During final spermiogenesis, spermatids are arranged in clusters, with heads in one direction and tails in the opposite. Spermatozoa are then liberated from these structures into the lobula lumina. The testicular lobules further elongate, and many of them form a continuum within the germinal epithelium, extending toward the periphery. The walls of the other lobules fuse, producing anastomosing sperm-filled lobular compartments. A main sperm duct is formed into which spermatozoa from the lobules are voided. A time lapse between sexual maturity and onset of spawning was observed, thus supporting the existing view that the anastomosing compartments are used for sperm storage during the latter part of the maturation process. Six maturity stages of the testis are delineated during the annual reproductive cycle based on macroscopic and histological characteristics. Results show that male O. ruber spawns from March through April in Kuwaiti waters.     

Duration of the cycle of the seminiferous epithelium and its stages in the rhesus monkey (Macaca mulatta)

Doses of 1 Gy or more of X-irradiation killed all B spermatogonia present in the testis, and during the first 3 weeks after irradiation, virtually no new B spermatogonia were formed. The number of Apale spermatogonia decreased during the first cycle of the seminiferous epithelium while the number of Adark spermatogonia only began to decrease during the second cycle after irradiation. In this study, the duration of the cycle of the seminiferous epithelium in the rhesus monkey was estimated to be 10.5 days (SE = 0.2 days). This was determined following the depletion of germinal cells in the seminiferous epithelium during the first 3 weeks after irradiation. The duration of each of the 12 stages of the cycle was also determined. Our observations of the progress of germinal cell depletion revealed that after a dose of X-irradiation sufficient to kill all B spermatogonia, all spermatocytes disappeared from the testis within about 17 days, and all spermatids within about 31 days.     

NuMA in rat testis--evidence for roles in proliferative activity and meiotic cell division

NuMA is a well-characterized organizer of the mitotic spindle, which is believed to play a structural role in interphase nucleus. We studied the expression of NuMA in rat seminiferous epithelium in detail. Different stages of the cycle of the seminiferous epithelium were identified using transillumination. Corresponding areas were microdissected and analysed using immunofluorescence, immunohistochemistry, or immunoblotting. NuMA was expressed in Sertoli cells, proliferating type A and B spermatogonia, and early spermatids but it was absent in late spermatids and mature spermatozoa. Interestingly, NuMA-positive primary spermatocytes lost their nuclear NuMA at the beginning of long-lasting prophase of the first meiotic division. A strong expression was again observed at the end of the prophase and finally, a redistribution of NuMA into pole regions of the meiotic spindle was observed in first and second meiotic divisions. In immunoblotting, a single 250-kDa protein present in all stages of the rat seminiferous epithelial cycle was detected. Our results show that NuMA is not essential for the organization of nuclear structure in all cell types and suggest that its presence is more likely connected to the proliferation phase of the cells. They also suggest that NuMA may play an important role in meiotic cell division.     

Stem cell renewal and duration of spermatogonial cycle in the goldhamster

Summary The duration of the cycle of the seminiferous epithelium of the hamster is estimated to be 9.0 days. The duration of the stages was also determined.The stem cells were found to be daughter cells of the A₃ spermatogonia. This confirms the hypothesis that in general stem cells for the next spermatogonial cycle arise on the moment of morphological differentiation of the A spermatogonia.The author wishes to thank Prof. Dr. M. T. Jansen and Dr. M. F. Kramer for helpfull discussions and Mr. J. G. van Essen for technical assistance.     

The seminiferous epithelial cycle and spermat ogenesis in rams (ovis aries )

The efficiency of spermatogenesis and degenerations of different spermatogenic cells under normal conditions of the environment have been investigated in rams. The meiotic divisions and the position of first-generation spermatids in haematoxylin-eosin stained testicular preparations were used to identify eight stages of the seminiferous epithelial cycle (SEC). The stages of relatively long duration (i.e., 1,2,3,4,8) were sub-divided. The percent-ages of frequency for the 14 stages reported were also studied. Three generations of type A (A(1), A(2), A(3)), one generation of type intermediate (In) and two generations of type B (B(1), B(2)) spermatogonia were recognized. A(2) and B(2) spermatogonia as well as primary and secondary spermatocytes did not degenerate. Contrarily, A(1), A(2), A(3), In and B(1) spermatogonia showed 25, 13.7, 27.3 and 21.2% degenerations respectively. We concluded that compared with the previously used eight-stage classification, subdividing stages with long durations as done in this study facilitates investigating the degenerations of spermatogenic cells. The efficiency of spermatogenesis in rams was 47.58% since one A(3) spermatogonium produces 30.45 spermatids/spermatozoa against the expected number of 64.     

Asymmetric Distribution of UCH‐L1 in Spermatogonia Is Associated With Maintenance and Differentiation of Spermatogonial Stem Cells

Asymmetric division of germline stem cells in vertebrates was proposed a century ago; however, direct evidence for asymmetric division of mammalian spermatogonial stem cells (SSCs) has been scarce. Here, we report that ubiquitin carboxy‐terminal hydrolase 1 (UCH‐L1) is expressed in type A (A_s, A_pr, and A_al) spermatogonia located at the basement membrane (BM) of seminiferous tubules at high and low levels, but not in differentiated germ cells distant from the BM. Asymmetric segregation of UCH‐L1 was associated with self‐renewal versus differentiation divisions of SSCs as defined by co‐localization of UCH‐L1^high and PLZF, a known determinant of undifferentiated SSCs, versus co‐localization of UCH‐L1^low/? with proteins expressed during SSC differentiation (DAZL, DDX4, c‐KIT). In vitro, gonocytes/spermatogonia frequently underwent asymmetric divisions characterized by unequal segregation of UCH‐L1 and PLZF. Importantly, we could also demonstrate asymmetric segregation of UCH‐L1 and PLZF in situ in seminiferous tubules. Expression level of UCH‐L1 in the immature testis where spermatogenesis was not complete was not affected by the location of germ cells relative to the BM, whereas UCH‐L1‐positive spermatogonia were exclusively located at the BM in the adult testis. Asymmetric division of SSCs appeared to be affected by interaction with supporting somatic cells and extracelluar matrix. These findings for the first time provide direct evidence for existence of asymmetric division during SSCs self‐renewal and differentiation in mammalian spermatogenesis. J. Cell. Physiol. 220: 460–468, 2009. © 2009 Wiley‐Liss, Inc.     

Do spermatogonial stem cells have a circadian rhythm?

Mitotic index was determined in whole mounts of segments of seminiferous tubules of (101 X C3Hf)F1 male mice at 3 hr intervals from 18.00 to 06.00 hours, and at hourly intervals from 08.00 to 16.00 hours. The highest frequency of metaphase-anaphase figures occurred at 10.00 and 11.00 hours, but was not significantly higher than for other times. Injection of 25 mu Ci 3H-TdR per mouse, followed 24 hr later by exposure to 300 rad X-rays and killing 207 hr after labelling was used to test for circadian rhythm in DNA synthetic activity of the long-cycling As spermatogonia. No significant effect of time of day was observed. Likewise, the number of undifferentiated spermatogonia scored 183 hr after 300 rad showed no effect of time of day. The testis therefore appears to have no circadian rhythm in mitotic activity. Stage of the cycle of the seminiferous epithelium, however, showed a significant effect on mitotic index of As spermatogonia and on DNA synthetic activity of undifferentiated spermatogonia. These data are compared with those for other organisms and tissues in respect to which properties of stem cells are general for all organisms and tissues and which are specific for spermatogonia.     

Relative volume of Sertoli cells in monkey seminiferous epithelium: a stereological analysis.

Techniques of quantitative stereology have been utilized to determine the relative volume occupied by the Sertoli cells and germ cells in two particular stages (I and VII) of the cycle of the seminiferous epithelium. Sertoli cell volume ranged from 24% in stage I of the cycle to 32% in stage VII. Early germ cells occupied 3.4% in stage I (spermatogonia) and 8.7% in stage VII (spermatogonia and preleptotene spermatocytes). Pachytene spermatocytes occupied 15% (Stage I) and 24% (stage VII) of the total volume of the seminiferous epithelium. In stage I the two generations of spermatids comprised 58% of the total epithelium by volume, whereas in stage VII, after spermiation, the acrosome phase spermatids occupied 35% of the total seminiferous epithelial volume.     

Germ cell apoptosis in the testes of normal stallions

Apoptosis in testicular germ cells has been demonstrated in many mammalian species. However, little is known about the stallion (Equus caballus) and rates of apoptosis during spermatogenesis. Morphological and biochemical features of apoptosis reported in other species were used to confirm that the TdT-mediated dUTP Nick end labeling (TUNEL) assay is an acceptable method for identification and quantification of apoptotic germ cells in histological tissue sections from stallion testis. Seminiferous tubules from eight stallions with normal testis size and semen quality were evaluated according to stage of seminiferous epithelium to determine the germ cell types and stages where apoptosis most commonly occurs. Spermatogonia and spermatocytes were the most common germ cell types labeled by the TUNEL assay. A low rate of round and elongated spermatids were labeled by the TUNEL assay. Mean numbers of TUNEL-positive germ cells per 100 Sertoli cell nuclei were highest in stages IV (15.5 +/- 1.0) and V (13.5 +/- 1.1) of the seminiferous epithelial cycle (P < 0.001). An intermediate level of apoptosis was detected in stage VI (P < 0.02). These stages (IV-VI) correspond to meiotic divisions of primary spermatocytes and mitotic proliferation of B1 and B2 spermatogonia. Establishing basal levels of germ cell apoptosis is a critical step towards understanding fertility and the role of apoptosis in regulating germ cell numbers during spermatogenesis.