Developmental fates of the mouse germ cell line

The specification of mouse germ cell lineage takes place after a population of pluripotential cells is established, and cell communication among the pluripotential cells may be important for this process. Primordial germ cells (PGCs) first appear around the allantois at 7 dpc which are distinct from pluripotential cells in the early embryo because they can not colonize blastocysts. However, a portion of PGCs are transformed into pluripotential cells in the ectopic environment or in culture, suggesting that the developmental fate of PGCs may still be somewhat plastic. PGCs may be destined only for gametes after they enter into the mitotic arrest phase or the meiotic prophase in embryonic gonads, which may be regulated by intrinsic and/or environmental molecules. After fetal germ cells are mitotically arrested, a large number of germ cells undergo programmed cell death. Bcl-2 and its related molecules are involved in the determination of death or survival of fetal germ cells, as well as of spermatogonia in adult testis. The cell death of spermatogonia may be necessary either for eliminating impaired germ cells or for arranging optimal interactions between germ cells and their supporting cells. Although maturating germ cells seem to differentiate only to sperm cells, oocytes that complete the first meiotic division can give rise to pluripotential cells, suggesting that maternal molecules accumulated in oocyte may play a role in the restoration of pluripotency.     

RNA-binding protein TIAR is essential for primordial germ cell development

Primordial germ cells (PGCs) give rise to both eggs and sperm via complex maturational processes that require both cell migration and proliferation. However, little is known about the genes controlling gamete formation during the early stages of PGC development. Although several mutations are known to severely reduce the number of PGCs reaching and populating the genital ridges, the molecular identity of only two of these genes is known: the c-kit receptor protein tyrosine kinase and the c-kit ligand (the steel factor). Herein, we report that mutant mice lacking TIAR, an RNA recognition motif/ribonucleoprotein-type RNA-binding protein highly expressed in PGCs, fail to develop spermatogonia or oogonia. This developmental defect is a consequence of reduced survival of PGCs that migrate to the genital ridge around embryonic day 11.5 (E11.5). The numbers of PGCs populating the genital ridge in TIAR-deficient embryos are severely reduced compared to wild-type embryos by E11.5 and in the mutants PGCs are completely absent at E13.5. Furthermore, TIAR-deficient embryonic stem cells do not proliferate in the absence of exogenous leukemia inhibitory factor in an in vitro methylcellulose culture assay, supporting a role for TIAR in regulating cell proliferation. Because the development of PGCs relies on the action of several growth factors, these results are consistent with a role for TIAR in the expression of a survival factor or survival factor receptor that is essential for PGC development. TIAR-deficient mice thus provide a model system to study molecular mechanisms of PGC development and possibly the basis for some forms of idiopathic infertility.     

Ablation of bcl-2 gene expression decreases the numbers of oocytes and primordial follicles established in the post-natal female mouse gonad

Oocyte loss, either directly through attrition (germ cell death) or indirectly through follicular atresia (somatic or granulosa cell death), is a fundamental event associated with defining the time of normal or premature reproductive senescence in females. Although apoptosis has been reported to function as the underlying mechanism responsible for death of both germ cells and somatic cells in the ovary, the final molecular steps which commit ovarian cells to death have not been fully elucidated. To examine if death repressor activity of the bcl-2 gene product is important for germ cell survival, we conducted studies using a Bcl-2 loss-of-function (bcl-2 -/-) transgenic mouse model. Histological analyses revealed that ovaries collected from bcl-2 -/- mice possessed numerous aberrantly formed primordial follicle-like structures containing a single layer of granulosa cells without an oocyte. Additionally, the total number of primordial follicles present which contained a healthy oocyte was markedly reduced in bcl-2 -/- mice as compared to heterozygote (bcl-2 -/+) or wild-type (bcl-2 +/+) mice, suggesting that expression of the bcl-2 death repressor gene is critical for endowment of a normal complement of germ cells and primordial follicles in the mammalian ovary.     

Role of fibroblast growth factors and their receptors in mouse primordial germ cell growth

Primordial germ cells (PGCs) are the embryonic progenitors of mature germ cells. During their proliferative stage, murine PGCs may be transiently cultured on mitotically inactive feeder layers. This culture system has permitted identification of several growth factors active toward PGCs. We and others have previously identified basic fibroblast growth factor (bFGF) as a powerful mitogen in this system. Here we characterize some of the functions of bFGF in PGC culture. Our data demonstrate that fibroblast growth factor (FGF) receptors I and II are present in the developing gonad and are consistent with expression of these receptors by PGCs. Moreover, PGCs can bind radiolabeled bFGF in vitro, demonstrating that the factor can act directly on these cells. While mitotic PGCs of either sex are shown to bind radiolabeled bFGF, oogonia that are undergoing meiotic arrest exhibit reduced bFGF binding, indicating potential developmental regulation of an FGF receptor.     

Requirement for phosphatidylinositol-3'-kinase in cytokine-mediated germ cell survival during fetal oogenesis in the mouse

Apoptosis is responsible for primordial germ cell (PGC) attrition in the developing fetal ovary. In monolayer cultures of murine PGC, stem cell factor (SCF) and leukemia inhibitory factor (LIF) independently promote survival in vitro; however, the relevance of these data to fetal ovarian oogonium and oocyte survival, as well as the intracellular events involved in transducing the antiapoptotic actions of these cytokines in germ cells, remain to be elucidated. In this report, we investigated the effects of SCF and LIF, alone and in combination, on the survival of oogonia and oocytes, and elaborated on components of the signal transduction pathway used by these molecules, after validating a method of culturing fetal mouse ovaries. We further employed this system to also test the hypothesis that insulin-like growth factor-I (IGF-I), a classic antiapoptotic molecule, and transforming growth factor-beta (TGF-beta), a classic pro-apoptotic molecule, interact with the SCF/LIF pathway and function in a reciprocal fashion to precisely regulate germ cell numbers during fetal oogenesis. Freshly isolated embryonic day 13.5 ovaries contained nonapoptotic germ cells, as determined by histologic analysis of cellular morphology and in situ 3'-end-labeling of DNA integrity. In vitro culture of fetal ovaries without tropic support for 24, 48, and 72 h resulted in a time-dependent induction of germ cell apoptosis, such that most oogonia and oocytes present after 72 h were apoptotic. Morphometric analysis of serially sectioned ovaries indicated that the numbers of nonapoptotic germ cells remaining after 24, 48, and 72 h of culture were 78%, 38%, and 10%, respectively, of the number present before culture (P < 0.05 for all time points vs. 0 h). Inclusion of SCF (100 ng/ml) together with LIF (100 ng/ml) in the culture medium significantly attenuated germ cell apoptosis, with the SCF/LIF-treated ovaries retaining 5.5-fold more oogonia and oocytes after 72 h of culture as compared with control ovaries deprived of tropic support (P < 0.05). However, SCF or LIF, when added separately, had no (SCF) or little (LIF) inhibitory effect on germ cell apoptosis. Provision of 50 ng/ml IGF-I maintained survival of approximately two-thirds of the germ cells in cultured ovaries (P < 0.05), whereas a combination of all three growth factors (SCF, LIF, IGF-I) completely preserved the fetal ovary in culture to that resembling a freshly-isolated gonad. Cotreatment with 25 ng/ml TGF-beta partially reversed the survival actions of IGF-I or SCF/LIF, such that only one-third of the starting number of oogonia/oocytes remained after 72 h of culture (P < 0.05). Lastly, the antiapoptotic effects of SCF/LIF or IGF-I were almost entirely eliminated by cotreatment of fetal ovaries with either one of two inhibitors of phosphatidylinositol-3'-kinase (PI3K), LY294002 (5 microM) or wortmannin (50 nM), whereas cotreatment with an inhibitor of p70 S6 kinase (rapamycin, 25 ng/ml) was without effect. These data indicate that the combined actions of SCF, LIF, and IGF-I are required for maximal inhibition of apoptosis in germ cells of fetal mouse ovaries, and that the PI3K signaling pathway is an essential component of cytokine-mediated female germ cell survival. Moreover, TGF-beta can partially override the antiapoptotic actions of SCF/LIF or IGF-I in oogonia and oocytes, suggesting the existence of a complex signaling network that ultimately determines fetal ovarian germ cell fate.     

Stereological evaluation of human spermatogenesis after suppression by testosterone treatment: heterogeneous pattern of spermatogenic impairment

Testosterone (T) treatment suppresses gonadotropin levels in normal men and is a promising reversible contraceptive that induces azoospermia in approximately 70% of subjects and oligospermia in the remainder; however, the basis of this variable response is unclear. This study aimed to investigate this reported variable response by examining the spermatogenic process and quantitating germ cell number in men after T-induced gonadotropin withdrawal. Ten normal fertile men (31-46 yr), already planning to undergo vasectomy, either received T enanthate (200 mg, i.m., weekly) for 19-24 weeks (n = 5; TE group) or proceeded directly to surgery (n = 5; controls), at which time a unilateral testicular biopsy was taken, and germ cell numbers were estimated using the optical disector stereological method. In response to TE treatment, serum T levels rose 2-fold, and FSH/LH levels became undetectable. Sperm counts fell to azoospermia in 4 men and to 21 million/mL in the fifth man. The mean number of type A spermatogonia per 100 Sertoli cells was unchanged, but type B spermatogonia fell markedly to 10% of the control values, and later germ cell types decreased to 11-18% of the control values. The pattern of germ cell suppression varied widely and showed no relationship with sperm count or the time to azoospermia. Despite the presence of elongated spermatids (1.4-20% of the control), four men remained azoospermic. Two TE subjects with similar early germ cell complements and elongated spermatid numbers had sperm counts of zero and 21 million/mL; the latter man demonstrated marked variability in germ cell numbers between adjacent tubules. We conclude that 1) the principal spermatogenic lesion in TE-treated men is the marked (90%) inhibition of type A-->B spermatogonial maturation. Other sites are also affected, particularly the release and/or survival of elongated spermatids during transit; and 2) a steady state in germ cell number may not be established even after 4-5 months of TE treatment. The findings suggest that TE treatment does not adequately or consistently withdraw hormonal support for spermatogenesis, leading to variable between- and within-individual patterns of germ cell suppression.     

Germ cell control of testin production is inverse to that of other Sertoli cell products

Recent studies have shown that germ cells can regulate testins, two newly identified Sertoli cell proteins that are associated with junctional complexes. To investigate this possibility, several parameters of Sertoli cell function were investigated over 2-120 days post exposure of the rat testes to x-rays (3 Grays). The irradiation-induced loss of spermatogonia resulted in a maturation-depletion process progressively affecting all germ cell classes. Testis weight began to decrease when the most numerous germ cell type (spermatids) began to decline. A complete or near complete recovery of spermatogenesis and of the testis weight had occurred by day 120 post irradiation. There was no significant change in FSH, epididymal androgen-binding protein, and tubule fluid levels during the first weeks after irradiation, when the seminiferious epithelium was depleted of spermatogonia and germ cells up to early spermatids. In contrast, when the number of the more mature forms of spermatids declined (between day 21 and 54), FSH rose and androgen-binding protein as well as fluid production declined. The subsequent recovery of these parameters was also highly correlated with the number of late spermatids. By contrast, testicular testin contents reacted to the depletion of germ cells with a biphasic increase; a doubling occurred when spermatogonia, spermatocytes, and early spermatids were absent (days 4-28), and a 7-fold rise occurred by day 37 when the number of late spermatids had decreased by 50%. By day 54, when the sperm counts had reached a nadir, testin contents had returned to levels corresponding to about four times the control levels; they progressively recovered thereafter. These observations support the postulate that germ cells negatively regulate testins. This possibility was investigated with in vitro experiments showing that addition of germ cell-conditioned medium to Sertoli cell monolayers inhibited testin secretion in a dose-dependent manner. In conclusion this study; 1) highlights the complex interplay between the various germ cell classes in the control of the Sertoli cell function in the adult testis; 2) establishes that germ cell effects may be opposite on different Sertoli cell products; 3) demonstrates that several classes of germ cells negatively control testicular testin contents; and 4) emphasizes the particular role of late spermatids in Sertoli cell regulation.     

The origin and biology of CIS cells: general discussion

Participants at the 4th Copenhagen Workshop on Carcinoma in situ and Cancer of the Testis, representing cell biologists and tumour biologists, met together to discuss the similarities and differences between primordial germ cells (PGCs) of the embryo, and the carcinoma in situ (CIS) stem cell of human testicular germ cell tumours (GCTs). Much has been discovered about PGCs in the last 10 years and we still do not know the exact nature of CIS cells. Knowledge of PGCs comes mainly from mouse experiments and knowledge of CIS comes from the study of human tumours. A mouse model of human GCT would help to investigate the nature of CIS cells. Grafting mouse male genital ridges into mouse fetal testes results in the development of testicular tissue and the formation of teratomatous tumour components. Amplification of PGCs in culture is possible but this results in their transformation into embryonic germ (EG) cells. CIS cells die by apoptosis if they are isolated, and short-term culture is only possible if the CIS cells are cultured in their normal environment within seminiferous tubules. It may be possible for CIS cells to differentiate in culture although they cannot be maintained in culture as isolated cells. Human CIS cells are likely to be formed as a result of in utero factors rather than agents acting on normal adult testicular germ cells. EG cells stimulate feeder cells by paracrine factors but it is not known if these cells produce autocrine factors.     

Number and function of Sertoli cells, number and yield of spermatogonia, and daily sperm production in three breeds of boar

The objective of this study was to determine the number of Sertoli cells per boar, daily sperm production, and germ cell yield per type A spermatogonium in mature Whitecross, Meishan, and West African boars. The paired parenchymal mass was greatest in the Whitecross boars and greater in Meishan than in West African boars. Daily sperm production per boar (x 10(9)) differed significantly (P < 0.05) among breeds (Whitecross: 12.5 +/- 1.5; Meishan: 6.0 +/- 0.5; West African: 2.9 +/- 0.3). Daily sperm production per boar was positively (P < 0.01) correlated with parenchymal mass (r = 0.97), number of A spermatogonia per testis (r = 0.88), and Sertoli cells per testis (r = 0.87). Daily sperm production per gram of testis was similar among breeds. Number of Sertoli cells and number of type A spermatogonia per boar were greater for the Whitecross but similar in the Meishan and West African boars. The number of Stage VII germ cells per Sertoli cell was greater (P < 0.05) in the Meishan (39.08 +/- 5.07), but similar in the Whitecross (19.91 +/- 1.62) and West African boars (15.81 +/- 2.43). The number of type A spermatogonia per testis was highly and positively (P < 0.01) correlated with number of Sertoli cells per testis (r = 0.95), and parenchymal mass (r = 0.88). There was a trend for the spermatid yield per type A spermatogonium to be greater in the Meishan boars, and this ratio was positively correlated with spermatid:Sertoli cell ratio (r = 0.62) but not with daily sperm production per boar or Sertoli cells per testis. No significant germ cell degeneration occurred during the long meiotic prophase, but the loss of progeny during postprophase of meiosis averaged 32.62% across all breeds. Germ cell degeneration was similar (P > 0.05) across breeds during spermiogenesis, and on average amounted to 8.6%. The increased number of type A spermatogonia and of Sertoli cells associated with larger testes for the Whitecross over West African or Meishan boars is sufficient to explain the higher sperm production in the Whitecross. However, the lower index of degeneration and more efficient Sertoli cell function in Meishan boars results in the daily sperm production being intermediate between that of the Whitecross and West African boars.     

Modulating excitatory synaptic neurotransmission: potential treatment for neurological disease?

The origin and development of the spermatogenic cell lineage is reviewed, as well as spermatogonial kinetics in adult nonprimate mammals in relation to the cycle of the seminiferous epithelium, the emphasis being on spermatogonial stem cells. A hypothesis is presented for the transition from foetal germ cells, gonocytes, to adult type spermatogonia at the start of spermatogenesis. An overview is given of the present knowledge on the proliferation and differentiation of undifferentiated spermatogonia (spermatogonial stem cells and their direct descendants) and the regulation of these processes. It is concluded that the differentiation of the undifferentiated into differentiating type spermatogonia is a rather vulnerable moment during spermatogenesis and the models for studying this are described. Research into the molecular basis of the regulation of spermatogonial proliferation, differentiation and apoptosis is at its infancy and the first results are reviewed. An exciting new research tool is the spermatogonial stem cell transplantation technique which is described. Finally, reviewing the nature of human germ cell tumours it is concluded that at present there are no animal or in vitro models to study these tumours experimentally.     

Ontogeny of estrogen receptor-beta expression in rat testis

The recently discovered estrogen receptor-beta (ERbeta) is expressed in rodent and human testes. To obtain insight in the physiological role of ERbeta we have investigated the cell type-specific expression pattern of ERbeta messenger RNA (mRNA) and protein in the testis of rats of various ages by in situ hybridization and immunohistochemistry. In fetal testes of rats 16 days postcoitum and testes of 4-day-old animals, fetal germ cells (gonocytes) reveal the ERbeta mRNA in their cytoplasm and the ERbeta protein in their nucleus. In testes of 11- and 15-day-old rats, ERbeta mRNA and protein were detected in Sertoli cells and type A spermatogonia. No signal was found in other types of germ cells. In the adult testes, expression of ERbeta mRNA as well as ERbeta protein was found in pachytene spermatocytes from epithelial stages VII-XIV and in round spermatids from stages I-VIII. Low ERbeta expression was observed in all type A spermatogonia, including undifferentiated A spermatogonia, whereas no expression was found in In and type B spermatogonia and early spermatocytes. At all ages, Sertoli cells showed a weak hybridization signal as well as weak immunoreactivity for ERbeta. In adult testes, no ERbeta mRNA or protein was detected in the interstitial tissue, indicating that Leydig cells and peritubular myoid cells do not express ERbeta. The expression of ERbeta in fetal and late male germ cells as well as in Sertoli cells suggests that estrogens directly affect germ cells during testicular development and spermatogenesis.     

A systematic molecular genetic approach to study mammalian germline development

It is difficult to study gene expression in mammalian embryonic germ cells as PGCs constitute only a minor proportion of the mouse embryo. We have overcome this problem by using a novel combination of established molecular and transgenic approaches. A line of mice has been generated in which the cells of the germ lineage express the beta-galactosidase reporter gene during embryogenesis. Using this line, germ cells have been purified to near homogeneity from embryos at discrete stages during germline development by use of a stain for beta-gal activity and a fluorescence activated cell sorter. Subsequently, cDNA libraries have been constructed from each germ cell population using a modified lone-linker PCR strategy. These combined cDNA libraries represent genes expressed in PGCs during mammalian germline development. To facilitate a molecular genetic approach to studying mammalian germline development, these cDNA libraries will be pooled to form an arrayed, addressed reference embryonic germ cell cDNA library. In parallel with large-scale cDNA sequencing efforts; genes that are differentially expressed in germ cells will be identified by screening the reference library with probes generated by subtractive hybridization. Complementary DNAs identified using this approach will be analyzed by sequencing, database comparison, genomic mapping and in situ hybridization to ascertain the potential functional importance of each gene to germline development. In addition to providing a wealth of novel information regarding patterns of gene expression during mammalian germline development, these results will form the basis for future experiments to determine the function of these genes in this process.     

Variation in the stock of testicular stem cells and in the yield of spermatogonial divisions in ram and bull testes

Two types of stem spermatogonia- type A0 and A1 spermatogonia- have been observed in ram and bull testes. Type A0 spermatogonia are present in the impuberal testis. Their total number/testis does not vary greatly during life of bull. Type A0 spermatogonia give rise to type A1 spermatogonia which appear at the onset of spermatogenesis; their total number/testis increases during and after puberty. Total numbers of type A0 and A1 spermatogonia/testis are not correlated in the ram while total numbers of type A1 spermatogonia and Sertoli cells are correlated. Hemicastration performed in impuberal calves induces an increase in numbers of Sertoli cell/type A1 spermatogonia/testis. In adult ram, the total number of A0 and A1 spermatogonia decreases during the non sexual season and increase again in the sexual season. After hypophysectomy performed in adult rams, the number of A0 spermatogonia/testis is not modified while that of A1 spermatogonia decreases. In ram and bull, 6 spermatogonial generations were detected before the germ cells undergo meiosis. In the adult ram and bull, the type A1 spermatogonia originate mostly after divisions of A2 spermatogonia. Few of them arise from A0 spermatogonia. The yield of primary spermatocytes from spermatogonial divisions is very low, one third and one half of the expected number in the bull and ram respectively. In ram, thus yield positively correlated to LH plasma levels (0.5; P = 0.05). In hypophysectomized ram, this yield is nearly equal to zero.     

A randomized, controlled trial of intravenous clodronate in patients with metastatic bone disease and pain

The present study analyses cell loss and proliferation which account for the decrease in the number of germ cell populations in the senile male Octodon degus. This is a good model to study ageing in wild animals, since it has recently been incorporated as a laboratory animal but still has a high degree of genetic heterogeneity, thus representing a situation found in natural systems. The cell loss from pachytene spermatocytes to round spermatids is estimated by cell counts in the cross section of seminiferous tubules. DNA testicular synthesis is measured by scintillation counting and the index of labelling of spermatogonia by radioautography of testes comparing sexually mature young animals and senile animals. Other determinations in both groups are testis weight, thickness of the albuginea and tubular wall, daily sperm production, percentage of depleted seminiferous tubules and nuclear cell diameters of germ cells. The results suggest a decrease in the number of cell population in the senile animals resulting from an increase in physiological cell loss coupled with a decreased proliferative spermatogonial activity. There is also a decreased yield of meiosis in terms of round spermatid production. Lowered testosterone levels both in plasma and testicular parenchymal fluid are found in senile animals. All these senescent changes reflect an altered remodelling activity of the seminiferous epithelium and presumably also of Leydig cells.     

Stage-specific expression of the Kit receptor and its ligand (KL) during male gametogenesis in the mouse: a Kit-KL interaction critical for meiosis

The Kit receptor and its ligand KL, which together constitute an essential effector at various stages of embryonic development, are both present during adult gametogenesis. In the testis, KL is expressed in Sertoli cells, and Kit in germ cells, starting at the premeiotic stages. A series of observations indicated previously a role in spermatogonia survival, without excluding a possible function at later stages. We identified a complex pattern of expression of the two components in the adult murine testis, suggestive of a role in the meiotic progression of spermatocytes. At stages VII-VIII of the cycle of the seminiferous epithelium, the time when spermatocytes enter meiosis, the membrane-associated form of KL extends on the Sertoli cell from the peripheral to the adluminal compartment of the tubule. We also found that the receptor is present on the surface of germ cells up to the pachytene stage. The availability of differentiated Sertoli cell lines, which express the KL protein and support part of the maturation of germ cells in coculture, allowed us to ask whether, in the in vitro reconstructed system, transit of spermatocytes through meiosis requires the Kit-KL interaction. Addition of a blocking monoclonal antibody against the Kit receptor (ACK2) inhibited extensively the appearance of haploid cells and the expression of a haploid-phase-specific gene (Prm1). Recognition of the supporting Sertoli cell by germ cells was not affected, indicating a requirement for the activity of the receptor for either entering or completing meiosis. Involvement of the membrane-associated form of the ligand was suggested by the observation that addition of the soluble form of KL was equally inhibitory.     

Spontaneous germ cell death in the testis of the adult rat takes the form of apoptosis: re-evaluation of cell types that exhibit the ability to die during spermatogenesis

Spontaneous germ cell degeneration occurs in the testis of the adult rat. Accumulating data supports the idea that this degeneration takes place via apoptosis. We have determined that morphology, acridine orange staining and ultrastructural features of these cell deaths clearly take the form of apoptosis. Furthermore, with acridine orange staining it was possible to detect a cell population showing early signs of death. The characterization of the main morphological features of these cells allowed us to identify several steps of maturing germ cells undergoing degeneration that have not previously been described. We have re-evaluated in toluidine blue stained semithin sections the germ cell types that undergo cell death at every stage of the spermatogenic cycle in the adult rat and concluded that, spermatogonia undergo cell death coinciding with their mitotic peaks, spermatocytes during preleptotene, leptotene, zygotene, pachytene and during metaphase I and spermatids during all their maturation steps. The biological significance of these cell deaths, at these steps of germ cell development, in relation to apoptosis, is discussed.     

The avian chB6 (Bu-1) alloantigen can mediate rapid cell death

The control of cell death is critical in the immune system. T and B lymphocytes must be censored during their development to remove nonfunctional or self-reactive lymphocytes. However, the molecules controlling cell deletion during lymphopoiesis have not been defined. B cells removed from the avian bursa of Fabricius rapidly undergo cell death in culture. We screened bursal B cells with a panel of Abs and lectins to identify molecules affecting their viability. Abs to the chB6 alloantigen caused a rapid loss of cell viability as measured by staining with propidium iodide. ChB6 Abs also cause adhesion between B cells. Transfection of cDNA encoding chB6 reconstituted the allele-specific cell death and adhesion effects in avian cell lines. These effects can be separated by binding cells onto Ab-coated plastic dishes. In these experiments, cells were killed in the absence of cell:cell contact. The ability of chB6 cross-linking to evoke cell aggregation and cell death is also observed when chB6 is expressed in growth factor-dependent mammalian cells. In these cells growth factor can almost completely prevent cell death but not cell aggregation. This suggests that known cell survival stimuli can suppress the cell death brought about by chB6 cross-linking. These results show that chB6 may have an important role in controlling cell survival and/or adhesion during avian B cell development.     

Migration of primordial germ cells to the developing gonadal ridges in the tammar wallaby Macropus eugenii

Primordial germ cells (PGCs) of the tammar wallaby Macropus eugenii have a distinctive morphology and stain positively for alkaline phosphatase. PGCs are identifiable in embryos with 12 somites, on about day 17 of the 26.5 day gestation period, when they are located in all three germ layers of the developing embryo and in the endoderm of the bilaminar and vascular (trilaminar) yolk sac membranes. PGCs are positive for alkaline phosphatase (ALP) at least between days 17 and 22 of pregnancy. In whole mounts on day 17, three groups of cells positive for ALP occur: about 40 just caudal to the neural tube, and about 20 distributed on either side of the last three somites. By day 21, there are about 150 PGCs in the newly formed gonadal ridges and 275 in the mesenteries. On days 21-22, there are PGCs in the umbilical mesoderm, the dorsal mesentery and the coelomic angles between the dorsal mesentery and the mesonephroi. On day 22, most ALP-positive PGCs are located in the dorsal mesentery, where they occur in groups. They apparently do not migrate through the hindgut endoderm, but occasional PGCs are seen in sites such as the mesonephros, the adrenals, the blood vessels of the yolk sac and in the vicinity of the dorsal aorta and dorsal nerve cord. Between day 23 and day 25, 1 day before birth, most of the 3200-4000 PGCs complete their migration to the gonadal ridges. Although there are marked differences between embryogenesis of tammars and mice, development and the pattern of migration of PGCs in this marsupial mammal are similar to that of eutherian mammals.