Spermatogonial multiplication in the Chinese hamster. IV. Search for long cycling stem cells

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 (As). These labelled As spermatogonia 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 As will be self-renewing and the other half will give rise to Apr 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 Apr 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 As, Apr and Aal 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 As that give rise to new As for the next epithelial cycle are similar to those of the As that will divide into Apr spermatogonia during the same epithelial cycle. Grain counts revealed that more [3H]TdR is incorporated into As, Apr and Aal spermatogonia that are in S phase during epithelial stages X-IV than in stages V-IX.     

The heterogeneity of spermatogonia is revealed by their topology and expression of marker proteins including the germ cell-specific proteins Nanos2 and Nanos3

Spermatogonial stem cells (SSCs) reside in undifferentiated type-A spermatogonia and contribute to continuous spermatogenesis by maintaining the balance between self-renewal and differentiation, thereby meeting the biological demand in the testis. Spermatogonia have to date been characterized principally through their morphology, but we herein report the detailed characterization of undifferentiated spermatogonia in mouse testes based on their gene expression profiles in combination with topological features. The detection of the germ cell-specific proteins Nanos2 and Nanos3 as markers of spermatogonia has enabled the clear dissection of complex populations of these cells as Nanos2 was recently shown to be involved in the maintenance of stem cells. Nanos2 is found to be almost exclusively expressed in A_s to A_pr cells, whereas Nanos3 is detectable in most undifferentiated spermatogonia (A_s to A_al) and differentiating A₁ spermatogonia. In our present study, we find that A_s and A_pr can be basically classified into three categories: (1) GFRα1⁺Nanos2⁺Nanos3⁻Ngn3⁻, (2) GFRα1⁺Nanos2⁺Nanos3⁺Ngn3⁻, and (3) GFRα1⁻Nanos2 ^± Nanos3⁺Ngn3⁺. We propose that the first of these groups is most likely to include the stem cell population and that Nanos3 may function in transit amplifying cells.     

The pluripotency factor LIN28 marks undifferentiated spermatogonia in mouse

Background  

Life-long production of spermatozoa depends on spermatogonial stem cells. Spermatogonial stem cells exist among the most primitive population of germ cells – undifferentiated spermatogonia. Transplantation experiments have demonstrated the functional heterogeneity of undifferentiated spermatogonia. Although the undifferentiated spermatogonia can be topographically divided into A_s (single), A_pr (paired), and A_al (aligned) spermatogonia, subdivision of this primitive cell population using cytological markers would greatly facilitate characterization of their functions.     

FAILURE TO IDENTIFY A SPERMATOGONIAL CHALONE IN ADULT IRRADIATED TESTES

The adult irradiated rat testis was used as a model system to confirm the existence of a spermatogonial chalone. Rats were given 330 rad whole body ⁶⁰Co irradiation, a dose which selectively destroys most of the spermatogonial population except for the radioresistant A_s stem cells. 11 days after irradiation, when spermatogonial numbers were minimal, the rats were injected with a testicular or liver extract prepared from normal adult rats, or with saline. Each group received a total of four injections given at 4 hr intervals. 2 hr before death, the animals were injected with [³H]TdR. Testicular DNA was isolated and the incorporation of [³H]TdR was determined. The mean ± s.e. ct/min per μg DNA in rats given testicular extract (9·38 ± 0·94) was no different than in those receiving liver extract (10·43 ± 2·01) or saline (7·23 ± 0·69). Autoradiographic studies indicated that variability in counts within or between groups could be attributed to variations in the number of pre-leptotene spermatocytes which incorporated [³H]TdR for the meiotic divisions. Quantitatively, there were no differences between groups in terms of the numbers of A spermatogonia, their labelling indices, or mitotic activity. Therefore, the presence of a spermatogonial chalone could not be demonstrated using crude extracts from normal testes in this irradiated model.     

REGENERATIVE PROLIFERATION OF MOUSE EPIDERMAL CELLS FOLLOWING APPLICATION OF A SKIN IRRITANT (CANTHARIDIN)

The strong skin irritant cantharidin dissolved in benzene was applied to the back of hairless mice. Single cell suspensions of epidermal basal cells were obtained and flow microfluorometric measurements of cellular DNA content were made. Smears were made for autoradiography, and the [³H]TdR labelling index (LI) and mean grain count (MGC) were assessed up to 3 days after cantharidin application. Three successive peaks of cells with S phase DNA content accompanied by three LI peaks were observed. The first two peaks were follwed by peaks of cells in G₂ phase, indicating that after the acute cell injury caused by cantharidin the cells traversed the cell cycle in partial synchrony through two subsequent cell cycles, each of 10–12 hr duration. During this phase of rapid proliferation the LI reached the proportion of cells in S phase, contrary to what is observed in untreated mouse epidermis, where the labelled cells contribute to about half the proportion of cells with S phase DNA content. The first two peaks of cells in S phase and LI coincided with an increased MGC, whereas the third peak was accompanied by a MGC significantly below control values. This indicates that this latter peak is due to a longer DNA synthesis time rather than to a partially synchronized and increased cell proliferation. The duration of the G₁, S and G₂ phases seems to be reduced initially in rapidly proliferating epidermis.     

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.     

REGENERATION OF UTERINE EPITHELIUM AFTER EXPERIMENTAL ABLATION IN THE RAT

Regeneration of the uterine luminal epithelium was studied after its mechanical removal in progesterone-primed rats, leaving one control horn intact. Pulse labelling with [³H]TdR during regeneration, showed a rapid peak of labelling index in remaining glands. A differentiated and highly labelled luminal epithelium reappeared at 34 hr, thereafter showing a rapidly declining LI. After initial depletion, the glandular cell population size was restored within 64 hr, whereas luminal epithelium cell numbers became stabilized at about half normal level. Grain counts after prelabelling showed more rapid dilution in gland cells of stripped uterine horns, indicating accelerated cycling of previously dividing cells. Thymidine labelling indices also showed that, after removal of the epithelium, almost all gland cells became rapidly committed to divide. On average, less than two cell cycles were necessary to restore stable glandular and epithelial population sizes. Numbers of labelled cells were also drastically increased in myometrium and serosa of treated horns. This suggests a non-specific mechanism for stimulation of mitotic activity after ablation of epithelium.     

Effects of Pulse Labelling With Tritiated Thymidine On the Circadian Rhythmicity In Epidermal Cell-Cycle Distribution In Mice

The influence of pulse labelling with 50 °Ci tritiated thymidine ([³H]TdR) (2 μCi/g) on epidermal cell-cycle distribution in mice was investigated. Animals were injected intraperitoneally with the radioactive tracer or with saline at 08.00 hours, and groups of animals were sacrificed at intervals during the following 32 hr. Epidermal basal cells were isolated from the back skin of the animals and prepared for DNA flow cytometry, and the proportions of cells in the S and G₂ phases of the cell cycle were estimated from the obtained DNA frequency distributions. the proportions of mitoses among basal cells were determined in histological sections from the same animals, as were the numbers of [³H]TdR-labelled cells per microscopic field by means of autoradiography. The results showed that the [³H]TdR activity did not affect the pattern of circadian rhythms in the proportions of cells in S, G₂ and M phase during the first 32 hr after the injection. the number of labelled cells per vision field was approximately doubled between 8 and 12 hr after tracer injection, indicating an unperturbed cell-cycle progression of the labelled cohort. In agreement with previous reports, an increase in the mitotic index was seen during the first 2 hr. These data are in agreement with the assumption that 50 °Ci [³H]TdR given as a pulse does not perturb cell-cycle progression in mouse epidermis in a way that invalidates percentage labelled mitosis (PLM) and double-labelling experiments.     

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.     

CYTOKINETICS OF TUMOUR AND ENDOTHELIAL CELLS AND VASCULARIZATION OF LUNG METASTASES IN C3H/HE MICE

A model of lung metastases was developed using intravenous injection of tumour cell aggregates of spontaneous C3H/He mammary tumours in syngeneic mice. the growth rate of lung tumours decreased with increasing tumour volume, with mean host survival of 46 days. the cytokinetics of individual tumours ranging between 0.004 and 4.2 mm³ in volume were studied. the labelling index (LI) ranged between 12 and 17%, the DNA synthesis time (T_s) being 9–10 hr. the growth fraction (GF) ranged between 26 and 38%. the cell cycle time (T_c) was found to be 18–19 hr. the LI and the GF decreased with increasing tumour volume doubling time (T_d). No correlation was found between the tumour volume and T_c. the LI of endothelial cells within these tumours, ranging between 0.004 and 4.2 mm³ in volume was 14–15% and endothelial cell proliferation was not affected by tumour growth. Vascular parameters were also determined for these tumours as a function of tumour volume. Vascular volume increased with increasing tumour size while the percentage of capillary vessels decreased. the cellular volume to capillary volume ratio increased with increasing tumour volume. Necrosis was observed in 0.27 mm³ tumours and increased with increasing tumour size. The results from these studies suggested that the age-dependent decrease in proliferative activity of tumour cells growing in the lung is related to change in effective vascularity.     

Combined flow and absorption DNA measurements of [3H]TdR-labelled tumour cells. I. Studies of MCa-11 cells grown as tumours in vivo and as exponential cultures in vitro*

Abstract. Flow cytometry of cellular DNA content provides rapid estimates of DNA distributions, i.e. the proportions of cells in the different phases of the cell cycle. Measurements of DNA alone, however, yield no kinetic information and can make it difficult to resolve the cell cycle distributions of normal and transformed cells present in tumour biopsy specimens. The use of absorption cytophotometry of the Feulgen DNA content and [³H]TdR labelling of the same nuclei provides objective criteria to distinguish the ranges of DNA content for G₀/G₁, S, and G₂/M cells. We now report on a study in which we combined flow and absorption cytometry to resolve the cell cycle distributions of host and tumour cells present in biopsy specimens of MCa-11 mouse mammary tumours labelled in vivo for 0.5 hr with [³H]TdR. A similar analysis of exponential monolayer cultures, labelled for 5 min with [³H]TdR under pulse-chase conditions, revealed a highly synchronous traversal of almost all cells through the different phases of the cell cycle. Combination of the flow and absorption methods also allowed us to detect G₂ tumour cells in vivo and a minor tumour stem-line in vitro, to show that these two techniques are complementary and yield new information when they are combined.     

Further evidence for the proposed way of spermatogonial stem cell renewal in the rat and the mouse

Summary By means of ³H-thymidine and autoradiography it could be established that in rats and mice the A₁, A₂ and A₃ spermatogonia do not give rise to a significant number of stem cells.The number of A₀ spermatogonia was found to be circa 20% of the number of A₀+A₁ spermatogonia in the rat and circa 10% in the mouse.The author wishes to thank Prof. Dr. M. T. Jansen and Dr. M. F. Kramer for helpful discussions and Mr. J. G. van Essen for technical assistance.     

Characterization of the interaction of reticuloendotheliosis virus with the avian lymphoid system.

Splenic lymphocytes from chickens infected with reticuloendotheliosis virus (REV) are cytostatically impaired in their ability to undergo mitogen-induced blastogenesis ([³H]TdR uptake and proliferation), but are fully capable of eliciting cytotoxic reactions against allogeneic, ⁵¹Chromium-labeled chicken erythrocytes. Spleen cells from birds with reticuloendotheliosis (RE_s) are able to suppress DNA synthesis of normal splenic lymphocytes (N_s), but are unable to inhibit ¹[³H]TdR uptake by chick embryo fibroblasts. The suppression of the N_s mitogenic response is not restricted by major histocompatibility (B-locus) differences between populations of RE_s suppressor and N_s target cells. Moreover, infection of birds with an attenuated form of REV, which replicates in the host but does not cause tumorigenesis, also leads to suppression of phytohemagglutinin-induced, [³H]TdR uptake by host lymphocytes. These results are discussed in terms of the interaction between viral-infected/transformed cells and host defense mechanisms.     

Negative effect of iodide on the survival of newly divided epithelial cells in chronically stimulated rat thyroid

The aim of this work was to investigate some aspects of the thyroid epithelial cell kinetics during the iodide-induced involution of a hyperplastic goitre in the rat. Rats were made iodine-deficient for 6 months, and propylthiouracil (PTU) (0.15%) was added to the diet during the last 2 months. Thereafter, rats were refed with iodide and PTU was removed (day 0). Forty-eight hours previously, all the rats were injected with tritiated thymidine ([3H]TdR) (1 microCi/g). Some animals were killed 1 hr or 24 hr after [3H]TdR injection (i.e. on day -2 and -1, day 0 corresponding to the restoration of a normal iodine diet); the other animals were killed after different delay periods and following [3H]TdR injection. Autoradiography of thyroid sections, iodine determination of plasma iodide and protein-bound iodine (PBI), and RIA of plasma thyroid stimulatory hormone (TSH) were performed. Plasma TSH concentration was very high on day 0 of iodide refeeding (3000 +/- 330 ng/ml) and remained at this level until day 8. Plasma PBI was very low on day 0, remained so until day 4 and greatly increased on day 8. Plasma iodide was also very low on day 0, but markedly increased on day 1, then did not vary significantly until day 43 of iodine refeeding. Thyroid weight, elevated on day 0, decreased relatively quickly until day 30, then more slowly until day 73. The [3H]TdR labelling index (LI) of the thyroid epithelial cells (TEC) was high on day 0 (56 +/- 3 labelled cells/10,000 cells), and 24 hr thereafter increased to 104 +/- 3, by division of the labelled cells. On day 1 of iodine refeeding, the LI had abruptly decreased to about half this value and then remained stable for 3 more days. Between day 4 and day 16, a progressive decline in the LI, (by about 3-4 per day), was observed. The LI showed no further modification, up to day 73, the longest period investigated. The decrease in LI occurred without any significant changes in the labelling intensity (grain count) of the remaining labelled cells between day 1 and 16, this indicates that no cell division took place during this period. The data are therefore interpreted as showing a biphasic elimination after iodide refeeding, of cells that were actively proliferating during the goitrous state.(ABSTRACT TRUNCATED AT 400 WORDS)     

CYTOKINETICS OF RAT TRACHEAL EPITHELIUM STIMULATED BY MECHANICAL TRAUMA

Mild abrasion of rat tracheal epithelium results in irreversible damage to the superficial cells and stimulates the viable basal cells to participate in a nearly synchronous wave of DNA synthesis and mitosis. For the growth population as a whole, DNA synthesis started at 14 hr after injury and persisted for 16 hr. The duration of S in individual cells was determined autoradiographically by identifying the time at which a second pulse of DNA precursor (¹⁴C-TdR) was no longer incorporated by cells labelled with ³H-TdR at the onset of S. S was found to be 8–9 hr long. It was also determined that cells entering S at later times synthesized DNA for the same 8–9 hr period. T_G2 was calculated to be 21/2–31/2 hr by subtraction of T_s and 1/2T_M from the period from onset of DNA synthesis to metaphase. By making a second denuding lesion adjacent to the first injury, the cells were stimulated through at least another period of S. At the peak of the second wave of DNA synthesis (50 hr after injury) ¹⁴C-TdR was present in the same cells which had incorporated ³H-TdR administered at the mid-point of the preceding synthetic phase. The 28-hr interval between these two peaks of synthesis is the measure of cell cycle duration for these regenerating tracheal epithelial cells.     

Induction of S-phase entry by a gonadotropin releasing hormone agonist (buserelin) in the frog,Rana esculenta,primary spermatogonia

In the testis of the frog, Rana esculenta, mitotic activity of primary spermatogonia is regulated by gonadotropins and synergistically by testosterone. In addition GnRH-like material directly stimulates gonadal activity. Intact animals were treated with a GnRH agonist (GnRHa, buserelin, Hoechst) and/or a GnRH antagonist giving injections intraperitoneally on alternate days for 15 days. Moreover, testes were treated in vitro for 24 hr with GnRHa. ³H-thymidine and colchicine were used to assess the labelling and the mitotic index (LI and MI) of primary spermatogonia. Both LI and MI were increased by the treatment with GnRHa but the rate of cells measured by LI was significantly higher than that of cells measured by MI. Therefore, our results confirm the role of GnRH-like material as local regulator of the testicular activity in vertebrates and show its involvement in promoting the G1-S transition of spermatogonial cell cycle in the frog, Rana esculenta.     

CELL KINETICS IN THE SEBACEOUS GLANDS OF THE MOUSE. I. THE GLANDS IN RESTING SKIN

Cell proliferation, differentiation and migration have been studied in the sebaceous glands of DBA-2 mice in the resting (telogen) phase of hair growth. Cells labelled by a single injection of tritiated thymidine start to leave the glands of adult male mice 5 days later. About 80% of the proliferative cells in the basal layer have a cell cycle time of 40 hr or less. In 18% of the proliferative cells G₁ is at least 4 days long and 16% have a G₂ phase longer than 17 hr. The S phase is about 7.5 hr long and cells spend at least 21 hr in the basal layer before migrating into the differentiating cell region. The glands of mature female and immature mice are smaller than those of the mature male. They have fewer, smaller cells and a much lower labelling index.     

Cell proliferation kinetics of six xenografted human cervix carcinomas: comparison of autoradiography and bromodeoxyuridine labelling methods

Abstract. Cell kinetic and histologic parameters of six xenografted tumours with volume doubling times ranging from 6 to 43 d were investigated in order to obtain kinetic information on a panel of tumours to be used in radiobiological studies. The six tumours covered a range of histologies and their DNA indices varied from 2–7 to 1–4. The length of the cell cycle (T_c), potential doubling time (T_pot) and labelling index (LI) were determined by continuous labelling with [³H]TdR and autoradiography in three tumours. T_c varied from 30 to 40 h. Determinations of the length of the S phase (T_s) were found to be less reliable by this method. Data on T_s and LI were also determined in all six tumours using bromodeoxyuridine (BrdU) labelling and the single sample method; values of T_pot were slightly longer than those obtained via the autoradiographic method. In addition, multiple samples were taken after BrdU labelling. T_c was determined by fitting the data obtained from mid-S, mid-G₂ and mid-G₁ windows to curves described by a damped oscillator. Data obtained via the mid-S window were found to be most reliable. Generally, cell cycle times obtained by the BrdU method were longer than those observed with the autoradiographic method. Differences between the two methods could be explained by inaccuracies in the determination of T_s, LI and T_c and differences in the experimental approach. We consider the BrdU labelling method to be a suitable alternative for the time-consuming autoradiography, if data on T_s or T_pot are sufficient. Due to difficulties in the reproducibility of the immunofluorescence staining and asynchronization of cells approximately 10 h after labelling, the method of windows analysis was affected by similar problems to those observed in interpretation of percentage labelled mitosis (PLM) curves. However, the method may serve as an alternative to determine cell cycle times in vitro and, if improved technically, in vivo. Careful comparison of the data obtained from mid-S, mid-G₁ and mid-G₂ windows may increase the reliability of the determination of cell kinetic parameters.     

Renewal and proliferation of spermatogonia during spermatogenesis in the Japanese quail,Coturnix coturnix japonica

Summary Four different types of spermatogonia were identified in the seminiferous tubules of the Japanese quail: a dark type A (A_d), 2 pale A type (A_p1 and A_p2), and a type B. A model is proposed describing the process of spermatogonial development in the quail. The A_d spermatogonia are considered to be the stem cells. Each divides to produce a new A_d spermatogonium and a A_p1 spermatogonium during Stage IX of the cycle of the seminiferous epithelium. An A_p1 spermatogonium produces two A_p2 spermatogonia during Stage II of the cycle, A_p2 spermatogonia produce four type B spermatogonia during Stage VI of the cycle, and type B spermatogonia produce eight primary spermatocytes during Stage III of the cycle. Consequently, 32 spermatids can result from each division of an A_d spermatogonium. Spermatogonial development in the quail differs from the process described in mammals in that there are fewer mitotic divisions and they are all synchronized with the cycle of the seminiferous epithelium. It is suggested that the fewer mitotic divisions explain why a smaller area of the seminiferous tubule is occupied by a cellular association in the quail than in mammals like the rat, ram and bull. The duration of spermatogenesis from the division of the A_d spermatogonia to sperm release from the seminiferous epithelium was estimated to be 12.77 days.