Xenopus Heterochronic Presumptive Primordial Germ Cells (pPGCs) Implanted in the Correct Position in Host Neurula Embryos can Differentiate into PGCs

Presumptive primordial germ cells (pPGCs) in explants, derived from single germ plasm-bearing cells of Xenopus 32-cell embryos, at the equivalent of neurula stage (stage 20) in control embryos (designated as 'stage-20' explants) were demonstrated to be able to differentiate into PGCs, when implanted into a prospective place of pPGCs in host embryos (stage 20) (Ikenishi & Tsuzaki, 1988). According to a recent proposal that individual early embryonic cells in Xenopus , at both in vivo and in vitro , are able to measure elapsed time since fertilization (Cooke and Smith, 1990), the result means that the implanted pPGCs having the same elapsed time as the host embryos (isochronic pPGCs) could differentiate into PGCs. In the present study, in order to know whether the compatibility in elapsed times of implanted pPGCs and host embryos is necessary for the differentiation of PGCs, labelled, heterochronic pPGCs in 'stages 12–33/34' explants were implanted into unlabelled, host neurulae (stage 19).
Those heterochronic pPGCs could differentiate into PGCs like isochronic pPGCs in 'stage-19' explants as the control. By comparing the average diameters and yolk contents of labelled PGCs with those of unlabelled, host ones in experimental tadpoles, the possibility that a certain mechanism modulating the elapsed time of heterochronic pPGCs to that of host pPGCs is present in host embryos was also suggested.     

Differentiation of presumptive primordial germ cell (pPGC)-like cells in explants into PGCs in experimental tadpoles

A single blastomere containing the "germ plasm" of 32-cell stage Xenopus embryos was cultured with [3H]thymidine until the control embryos developed to the neurula stage. The explants, showing a spherical mass in which the nuclei of all cells were labeled, were implanted into the prospective place of presumptive primordial germ cells (pPGCs) in the endodermal cell mass of unlabeled host embryos of the neurula stage. Labeled PGCs as well as unlabeled, host PGCs were found in the genital ridges of experimental tadpoles. This indicates that the precursor of germ cells, corresponding to pPGCs in normal embryos of the neurula stage, in the explants migrated to genital ridges just at the right moment to become PGCs, and suggests that the developmental process progressed normally, even in the explants, as far as the differentiation of pPGCs is concerned.     

ULTRASTRUCTURE OF THE 'GERMINAL PLASM' IN XENOPUS EMBRYOS AFTER CLEAVAGE

The endodermal location of 'germinal plasm'-bearing cells (GPBCs) and the ultrastructure of the 'germinal plasm' were studied in Xenopus laevis embryos at gastrula, neurula, tailbud and younger tadpole stages. Primordial germ cells (PGCs) of feeding tadpoles were also observed ultrastructurally.
GPBCs were found in the inner endoderm and in the yolk plug region at the late gastrula stage, in the middle and in the dorsal part of the endoderm cell mass at the late neurula and late tailbud stages, respectively. At the younger tadpole stage they were observed in the uppermost dorsal part of the endoderm. Germinal granules were always present in GPBCs at all stages examined but were not found in PGCs of feeding tadpoles. Irregularly shaped-stringlike bodies (ISBs) which seemed to have changed from germinal granules were first noticed in GPBCs at the late neurula stage, and were still present in PGCs of tadpoles, while 'granular materials' were not seen in GPBCs until the feeding tadpole stages. These facts and ultrastructural similarities shared by these organelles lead us to conclude that the change of the germinal granule through ISB, to the 'granular material' takes place during the differentiation of GPBCs into PGCs.     

Functional gametes derived from explants of single blastomeres containing the "germ plasm" in Xenopus laevis: a genetic marker study

Single blastomeres containing the "germ plasm" were isolated from 32-cell embryos of Xenopus albino (ap/ap) or wild type and cultured in vitro until the corresponding normal control embryos reached the neurula stage. The resulting explants from albinos were implanted into wild-type host neurulae and vice versa. The formation of functional gametes, eggs or sperm, of donor type was tested when the operated host embryos had reached sexual maturity. The color of the eggs laid by the experimental females and the presence or absence of melanophores in the epidermis and of pigment granules in the eyes of hatched larvae from matings of the experimental males with albino females made possible the identification of donor-type gametes. Twelve males and 12 females of the wild-type hosts, and 16 males and 14 females of the albino hosts survived. Six animals produced donor-type eggs or sperm, most of them being germ line chimeras. This shows that functional gametes can develop from explants derived from single blastomeres containing the "germ plasm."     

Direct Evidence for the Presence of Germ Cell Determinant in Vegetal Pole Cytoplasm of Xenopus laevis and in a Subcellular Fraction of It

To test for the presence of germ cell determinant in Xenopus embryos, vegetal pole cytoplasm containing the "germ plasm", or a subcellular fraction of it, was microinjected into single somatic blastomeres isolated from 32-cell embryos. Injected or non-injected (control) blastomeres were cultured in ³H-thymidine until normal control embryos reached the neurula stage. The labeled explants were then implanted into unlabeled host neurulae, which were allowed to develop to the tadpole stage. Labeled PGCs of explant origin in the genital ridges of the experimental tadpoles were examined by autoradiography.
Isolated blastomeres were injected with vegetal pole cytoplasm of 32-cell embryos or with a 20,000 g pellet made from vegetal pole cytoplasm of 2-cell embryos. Labeled PGCs were found in 7.6% and 2.3% of the experimental tadpoles, respectively. No labeled PGCs were found in the control tadpoles, except for one tadpole in the first experiment. These results strongly suggest that the vegetal pole cytoplasm and its subcellular fractions act as germ cell determinant.     

Ectopic germline cells in embryos of Xenopus laevis

Whether all descendants of germline founder cells inheriting the germ plasm can migrate correctly to the genital ridges and differentiate into primordial germ cells (PGCs) at tadpole stage has not been elucidated in Xenopus. We investigated precisely the location of descendant cells, presumptive primordial germ cells (pPGCs) and PGCs, in embryos at stages 23-48 by whole-mount in situ hybridization with the antisense probe for Xpat RNA specific to pPGCs and whole-mount immunostaining with the 2L-13 antibody specific to Xenopus Vasa protein in PGCs. Small numbers of pPGCs and PGCs, which were positively stained with the probe and the antibody, respectively, were observed in ectopic locations in a significant number of embryos at those stages. A few of the ectopic PGCs in tadpoles at stages 44-47 were positive in TdT-mediated dUTP digoxigenin nick end labeling (TUNEL) staining. By contrast, pPGCs in the embryos until stage 40, irrespective of their location and PGCs in the genital ridges of the tadpoles at stages 43-48 were negative in TUNEL staining. Therefore, it is evident that a portion of the descendants of germline founder cells cannot migrate correctly to the genital ridges, and that a few ectopic PGCs are eliminated by apoptosis or necrosis at tadpole stages.     

Presumptive Primordial Germ Cells (pPGCs) and PGCs in Tadpoles from UV-irradiated embryos of Xenopus

In order to determine whether or not tadpoles that once lacked primordial germ cells (PGCs) in the genital ridges and dorsal mesentery as a result of ultraviolet (UV) irradiation subsequently contained germ cells at more advanced stages of larval development, the numbers of presumptive PGCs or PGCs were carefully examined in Xenopus tadpoles at Nieuwkoop and Faber's stage 35/36–52 that developed normally from UV-irradiated eggs.
No late-appearing germ cells were observed in almost all the UV-irradiated tadpoles examined at stages 49–52. This same population had completely lacked PGCs at about stage 46. Moreover, presumptive PGCs (pPGCs) or cells with granular cytoplasm that reacted with a monoclonal antibody specific for the germ plasm of cleaving Xenopus eggs stayed in the central part of the endoderm cell mass in the irradiated tadpoles at stage 35/36, when the majority of those cells were located in the dorsal part of the endoderm in unirradiated controls. Furthermore, in the irradiated embryos pPGCs were demonstrated to decrease in number with development and eventually to disappear in tadpoles at about stage 40. The results strongly suggest that UV irradiation under the conditions used here totally eliminated germline cells from the irradiated animals.     

LOCATION AND ULTRASTRUCTURE OF PRIMORDIAL GERM CELLS (PGCs) IN AMBYSTOMA MEXICANUM

The location and ultrastructure of the primordial germ cells (PGCs) were studied in Ambystoma mexicanum larvae of stages 23 to 47.
PGCs were found in the spaces between the endodermal cell mass and the lateral plate mesoderm at stages 23 to 35. Some of the PGCs at stage 35, and most of them at stages 40 and 42, were located near the Wolffian duct. At stages 46 and 47 all the PGCs were situated in the genital ridges. Cilia, which have hitherto never been reported in PGCs, were occasionally seen in PGCs of Ambystoma from stage 23 till stage 46.
No "germinal plasm" was found in the PGCs prior to stage 40. Specific structures or "nuage material", corresponding to the germinal granules or their derivatives in Xenopus , were first recognized in the vicinity of the nucleus at stage 40. Between stages 40 and 46, the amount of "nuage material" markedly increased. It was finally localized mainly in "intermitochondrial spaces". A possible transfer of material from the nucleus to the cytoplasm or vice versa through nuclear pores was first noticed at stage 40, the material concerned being quite similar in ultrastructure to the "nuage material".     

On the Origin of Primordial Germ Cells in the Chick Embryo

An attempt was made to re-examine the location of the primordial germ cells (PGCs) in very young chick embryos. Freshly laid blastoderms, prior to hypoblast formation, of a known anterio-posterior axis, were transversely bisected and each half was separately grown in vitro. Both anterior and posterior halves were shown to be fertile and each was shown to contain roughly the same amount of PGCs as a normal control embryo. It has been concluded that in the chick as well as in the duck there is no concentration of cells containing germinal plasm in the posterior part of the blastoderm.
Two other possibilities should be investigated:
1. A concentric arrangement of cells containing germinal plasm. 2. The absence of a germinal plasm and a relatively late appearance of PGCs as a result of induction.     

Mitochondrial trafficking through Rhot1 is involved in the aggregation of germinal granule components during primordial germ cell formation in Xenopus embryos

In many animals, the germ plasm is sufficient and necessary for primordial germ cell (PGC) formation. It contains germinal granules and abundant mitochondria (germline‐Mt). However, the role of germline‐Mt in germ cell formation remains poorly understood. In Xenopus, the germ plasm is distributed as many small islands at the vegetal pole, which gradually aggregates to form a single large mass in each of the four vegetal pole cells at the early blastula stage. Polymerized microtubules and the adapter protein kinesin are required for the aggregation of germ plasm. However, it remains unknown whether germline‐Mt trafficking is important for the cytoplasmic transport of germinal granules during germ plasm aggregation. In this study, we focused on the mitochondrial small GTPase protein Rhot1 to inhibit mitochondrial trafficking during the germ plasm aggregation. Expression of Rhot1ΔC, which lacks the C‐terminal mitochondrial transmembrane domain, inhibited the aggregation of germline‐Mt during early development. In Rhot1‐inhibited embryos, germinal granule components did not aggregate during cleavage stages, which reduced the number of PGCs on the genital ridge at tail‐bud stage. These results suggest that mitochondrial trafficking is involved in the aggregation of germinal granule components, which are essential for the formation of PGCs.     

鸟类原生殖细胞的研究 Ⅰ.鸡胚生殖新月区原生殖细胞超微结构的观察

作者观察了鸡胚生殖新月区的原生殖细胞(PGC)的超微结构。PGC为圆形或椭圆形,13—16μm,有丰富的伪足和微绒毛,尚可见到相邻PGC存在桥粒样结构。细胞核为圆形、椭圆形及分叶状,并呈多处凹陷。与同期胚的其它细胞相比,胞质内细胞器相当丰富且较成熟。观察到有大量微丝。上述PGC的形态,除了细胞桥粒样结构及微丝很少见到报道外,其它特征与鸟类PGC的超微记载相一致。 作者首次观察到PGC中有一种特殊颗粒(即电子致密小体),它自核内产生,进入核周池,并借核膜破裂的方式进入胞质。这种颗粒可能就是生殖颗粒,而由该颗粒在胞质中聚集所构成的特殊高电子致密区可能就是生殖质。从而从形态学上提供了鸟类具有生殖质的证据。     

A natural marker for blastomeres of the germ line in cleavage stage Xenopus embryos

A distinct dark area of vegetal pole region, against a light color of other areas in vegetal hemisphere, was investigated in cleavage stage Xenopus embryos with special reference to the “germ plasm.” Light and electron microscopic observations showed that many pigment granules were concentrated around the “germ plasm,” resulting in the formation of the dark area. In 32-cell stage embryos, it was determined that the number of the blastomeres with the dark area in an embryo was in agreement with that of those containing the plasm, and that the plasm was always present in the isolated blastomeres within the area while never seen in those without it. Therefore, from this macroscopic feature, the presence or absence of the dark area, it is possible to distinguish, with certainty, the blastomeres of the germ line from those of the somatic.     

Ultraviolet effects on presumptive primordial germ cells (pPGCs) in Xenopus laevis after the cleavage stage

The presumptive primordial germ cell (pPGC) number with development after the cleavage stage and the fate of pPGCs damaged by uv irradiation were studied in successive Epon sections (0.5 μm thick) with the light microscope in both uv-irradiated and unirradiated Xenopus embryos. taking survival rate and sterility into consideration. The pPGCs of the uv-irradiated embryos occupy nearly the same location in the embryos as those of the unirradiated embryos at stages 12, 17, 23, and 28 [see Ikenishi, K., and Kotani, M. (1975). Develop. Growth Different. 17, 101–110]. At stage $\text{33}\text{34}$ they are found in the central part of the endoderm cell mass in the uv-irradiated embryos, while they are situated in the lateral or dorsal part of the endoderm cell mass in the unirradiated. In the uv-irradiated embryos, a cavity which was never found in the unirradiated embryos was observed in the endoderm cell mass beneath the archenteron cavity and in the almost-median part of the posterior endoderm cell mass at stages 17 and 23, respectively, and some vacuoles in pPGCs as well as in somatic cells around those pPGCs were noticed at stages $\text{17–}\text{33}\text{34}$. The number of pPGCs of the unirradiated enbryos increases about three- or fourfold during stages 12–46, while the pPGCs of the uv-irradiated embryos slowly increase in number from stage 17 to stage 28, indicating that the division occurs in pPGCs, then decrease with development and finally disappear from the tadpole.     

A demonstration of cellular interactions during the formation of mesoderm and primordial germ cells in Pleurodeles waltlii

Animal, vegetal, dorsal and ventral blastomeres of eight-cell embryos of the urodele Pleurodeles waltlii were isolated and cultured for 15 days. The four animal blastomeres produced vesicles delimited by an irregularly shaped epidermis. In all other explants, the formation of mesodermal structures occurred, which can be interpreted as the result of inductive interaction, occurring during segmentation, between the ectodermal animal cap and vegetal yolk mass. Primordial germ cells (PGCs), which formed in 78% of cases when the presumptive ventral half to the embryo was cultured, occurred in only 48% of cases when the two ventral vegetal blastomeres were cultured alone. The absence of PGCs in the explants emanating from the four vegetal blastomeres is thought to have been due to inhibition of differentiation by notochord. This hypothesis has been confirmed by culture experiments in which the addition of presumptive chordomesoderm of young gastrulae prevented the differentiation of PGCs under conditions in which they are normally formed. These observations suggest that, in urodeles, PGCs do not arise from cells segregated as early as the eight-cell stage, but are the product of later inductive interaction between ectoderm and endoderm.     

Ultrastructural changes associated with UV irradiation in the "germinal plasm" of Xenopus laevis

To detect structural changes following UV irradiation in the “germinal plasm,” ultrastructure of the “germinal plasm” was studied in normal and UV-irradiated eggs of Xenopus laevis at the following stages: prior to fertilization, early 2-cell, 32-cell, and late blastula. It was revealed that ultrastructural features of the “germinal plasm” were essentially common between Xenopus laevis and Rana pipiens. That is, the “germinal plasm” is composed primarily of a large aggregation of mitochondria and distinctive electron dense bodies (germinal granules). Irregularly shaped cylinderlike granules (giant germinal granules), having the same internal characteristics as the germinal granules, were found in the “germinal plasm” of all eggs examined.Comparison between normal and UV-irradiated eggs has demonstrated that UV irradiation causes swelling and vacuolation of mitochondria and fragmentation of germinal granules. The suggestion is that the integrity of certain UV-sensitive factor(s), which is involved in maintaining normal structure of germinal granules, is indispensable for the determination of the primordial germ cells.     

Cause of the decreased number of PGC in albino Xenopus: analysis of the number and position of pPGC in albino embryos during and after cleavage

In order to understand the cause for the decreased number of primordial germ cells (PGC) in Xenopus albino (a(p)/a(p)) tadpoles, the number of presumptive PGC (pPGC) in the albino and wild-type embryos at Nieuwkoop and Faber's stages 6-37/38 were examined using the antibody specific to germ plasm. The positions of pPGC in the endodermal cell mass in embryos of both types at stages 28 and 33/34 were also observed to learn the migratory behavior of pPGC. The number of pPGC in the albino increased up to stage 28 with development, but decreased thereafter. In contrast, the number in the wild-type increased to stage 33/34 as development proceeded, and the number of pPGC in stage 33/34 embryos reached nearly that of PGC of the feeding tadpoles in the same batches. Judging from the positions of pPGC, the migration of pPGC from the median part through the lateral to the dorsal part of the endodermal cell mass in the albino was suspected to be somewhat later than that in the wild-type. These results, together with the results in previous studies, suggest that the decreased number of PGC in the albino would be closely related to the sudden decrease in number of pPGC at stage 33/34, as well as to the ectopic position of pPGC in endodermal cell mass, the latter of which had already been demonstrated to be responsible for the differentiation into PGC.     

Formation and cultivation of medaka primordial germ cells

Primordial germ cell (PGC) formation is pivotal for fertility. Mammalian PGCs are epigenetically induced without the need for maternal factors and can also be derived in culture from pluripotent stem cells. In egg-laying animals such as Drosophila and zebrafish, PGCs are specified by maternal germ plasm factors without the need for inducing factors. In these organisms, PGC formation and cultivation in vitro from indeterminate embryonic cells have not been possible. Here, we report PGC formation and cultivation in vitro from blastomeres dissociated from midblastula embryos (MBEs) of the fish medaka (Oryzias latipes). PGCs were identified by using germ-cell-specific green fluorescent protein (GFP) expression from a transgene under the control of the vasa promoter. Embryo perturbation was exploited to study PGC formation in vivo, and dissociated MBE cells were cultivated under various conditions to study PGC formation in vitro. Perturbation of somatic development did not prevent PGC formation in live embryos. Dissociated MBE blastomeres formed PGCs in the absence of normal somatic structures and of known inducing factors. Most importantly, under culture conditions conducive to stem cell derivation, some dissociated MBE blastomeres produced GFP-positive PGC-like cells. These GFP-positive cells contained genuine PGCs, as they expressed PGC markers and migrated into the embryonic gonad to generate germline chimeras. Our data thus provide evidence for PGC preformation in medaka and demonstrate, for the first time, that PGC formation and derivation can be obtained in culture from early embryos of medaka as a lower vertebrate model.     

The Xdsg protein in presumptive primordial germ cells (pPGCs) is essential to their differentiation into PGCs in Xenopus

In order to know the role of the Xdsg gene in presumptive PGCs (pPGCs) of Xenopus, we attempted to inhibit the translation of Xdsg mRNA in pPGCs by injecting antisense morpholino oligo (asMO), together with Fluorescein Dextran-Lysine (FDL), into single germ plasm-bearing cells of 32-cell embryos. Among three types of asMOs complementary to different parts of the 5'-untranslated region of Xdsg mRNA tested, only one asMO, designated as Xdsg-3, inhibited the translation of the mRNA in FDL-labeled pPGCs, resulting in the absence of labeled PGCs in experimental tadpoles. On the other hand, two other asMOs, Xdsg-1 and -2, did not inhibit the translation, so that a similar number of labeled PGCs found in FDL-injected but asMO-uninjected control tadpoles were observed in experimental tadpoles derived from asMO-injected embryos. Surprisingly, use of Xdsg-3 asMO resulted in the disappearance of the protein of Xenopus vasa homolog (Xenopus vasa-like gene 1, XVLG1) from FDL-labeled pPGCs by inhibiting the translation of XVLG1 mRNA. However, the effect of Xdsg-3 asMO on the translation of Xdsg and XVLG1 mRNAs and PGC formation could be canceled by the coinjection with Xdsg mRNA. Consequently, the Xdsg protein in pPGCs may play an important role in the formation of PGCs by regulating the production of XVLG1 protein.     

Formation of a large Vasa-positive germ granule and its inheritance by germ cells in the enigmatic Chaetognaths

Chaetognaths (arrow worms) are abundant hermaphrodite marine organisms whose phylogenetic position amongst protostomes and deuterostomes is still debated. Ancient histological observations dating from a century ago described the presence in eggs of a large granule, presumed to be a germ plasm, and its probable inheritance in four primary germ cells (PGCs). Using videomicroscopy, electron microscopy and immunocytochemistry (labelling with anti-Vasa antibodies) we have followed the cycle of aggregation and dispersion of germ plasm and nuage material in eggs, embryos, PGCs and oocytes in several species of benthic (Spadella) and planctonic (Sagitta) chaetognaths. In these animals, germ cells and gametes can be observed in vivo throughout the 1-2 month life cycle. After describing internal fertilization in live animals we show that the single large (15 microm diameter) germ granule forms by a spiralling aggregation movement of small germ islands situated in the vegetal cortex at the time of first mitosis. We also demonstrate that the granule forms autonomously in unfertilized activated eggs or fertilized egg fragments. Once formed, the germ granule first associates with the cleavage furrow and is segregated into one of the first two blastomeres. The germ granule is then translocated from the cortex to the mitotic spindle during 3(rd) cleavage and remains in the single most-vegetal blastomere until the 32-cell stage. At the 64-cell stage the germ granule is partitioned as nuage material into two founder PGCs and further partitioned into four PGCs situated at the tip of the archenteron during gastrulation. These four PGCs migrate without dividing to reach the transverse septum, then proliferate and differentiate into oocytes and spermatocytes of two ovaries and two testes. We noted that germ plasm and nuage material were associated with mitochondria, the nucleus, the spindle and the centrosome during some stages of development and differentiation of the germ line. Finally, we demonstrate that a Vasa-like protein is present in the germ granule, in PGCs and in the electron-dense material associated with the germinal vesicle of oocytes. These features stress the conservation of cellular and molecular mechanisms involved in germ cell determination.     

Direct Evidence for in vitro Binding of a Lectin from Arachis hypogea to Endoblastic Primordial Germ Cells of Amphibian Embryos

Peanut agglutinin was previously shown to have a specific affinity for primordial germ cells (PGCs) from anuran amphibian embryos. For separation of these cells from endoblastic ones, suspensions of dissociated cells from the endoblastic masses of Xenopus laevis and Rana dalmatina embryos were treated with peanut agglutinin. This treatment resulted in agglutination of a small number of cells, and these aggregates were separated from unaggregated single cells by gravity in 50% calf serum medium. Histological and ultrastructural analysis of numerous sections of the aggregated cells showed that they contained the germinal plasm characteristic of PGCs. The specificity of the PGCs agglutination was confirmed by disocciation of the aggregates with 0, 2 M D-galactose solution.
This embryonic cellular population of PGCs should be useful in further in vitro experiments.