Involvement of the protein of Xenopus vasa homolog (Xenopus vasa-like gene 1, XVLG1) in the differentiation of primordial germ cells

In order to understand the role of the protein of Xenopus vasa homolog ( Xenopus vasa -like gene 1, XVLG1 ) in germ line cells, an attempt was made to perturb the function of the protein with the anti-vasa antibody 2L-13. The 2L-13 or the control antibody was microinjected with a lineage tracer (FITC-dextran-lysine, FDL) into single vegetal blastomeres containing the germ plasm of Xenopus 32-cell embryos, the descendants of which were destined to differentiate into a small number of primordial germ cells (PGC) and a large number of somatic cells, mostly of endodermal tissues at the tadpole stage. No significant effect of the injection of the antibodies on FDL-labeled, presumptive PGC (pPGC) was observed in embryos until stage 37/38. However, FDL-labeled PGC were not observed in almost all the 2L-13 antibody-injected tadpoles, although a similar number of labeled somatic cells were always present. As 2L-13 antibody specifically reacts with XVLG1 protein in the embryos by immunoblotting, the present results suggest that the antibody perturbed the function of XVLG1 protein in the pPGC, resulting in failure of PGC differentiation at the tadpole stage.     

Spatio-temporal distribution of the protein of Xenopus vasa homologue (Xenopus vasa-like gene 1, XVLG1) in embryos

In order to know when the protein of Xenopus vasa homolog ( Xenopus vasa -like gene 1, XVLG1 ) first appears in germ line cells and whether the protein is also present in somatic cells as is vasa protein in Drosophila , the spatio-temporal distribution of the protein in Xenopus embryos was carefully investigated by fluorescent microscopy. Part of the observation was performed by whole-mount immunocytochemistry and immunoblotting. A distinct fluorescence of XVLG1 protein was first recognized in a juxta-nuclear location of germ line cells or presumptive primordial germ cells (pPGC) at stage 12 (late gastrula) and remained associated with the pPGC or primordial germ cells (PGC) throughout the following stages until stage 46 (feeding tadpole). In contrast, weak fluorescence was seen in the animal hemisphere rather than in the vegetal hemisphere of cleaving embryos and in the perinuclear region of somatic cells at stages 10–42 (early gastrula to young tadpole), respectively. Nearly the same pattern as revealed by fluorescence was seen by whole-mount immunocytochemistry, except that a small amount of XVLG1 protein seemed to be present in the germ plasm and pPGC of embryos earlier than stage 12. The presence of the protein in the somatic cells and the PGC was also shown by immunoblotting.     

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.     

The cause of the decreased number of primordial germ cells in albino Xenopus resides not in the micro-environment but in the presumptive PGC

The number of primordial germ cells (PGC) in albino tadpoles of Xenopus is significantly decreased as compared with that of the wild-type. Whether the decreased number of PGC is caused by the presumptive PGC (pPGC) themselves or the micro-environment surrounding those cells in the albino, or both was investigated in the present study. [³H]thymidine-labeled pPGC of wild-type and albino were implanted into unlabeled, host neurulae of wild-type br albino and wild-type, respectively. Labeled PGC in the genital ridges of experimental tadpoles were examined by autoradiography. There were no significant differences in the proportion of tadpoles with labeled PGC and in the average number of those PGC between the albino and wild-type tadpoles, into which wild-type pPGC had been implanted. The proportion in wild-type tadpoles with albino pPGC was much lower than that in wild-type tadpoles with wild-type pPGC. These results suggest that the pPGC of the albino and not the micro-environment are responsible for the decreased number of PGC.     

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.     

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.     

Delayed fertilization of anuran amphibian (Xenopus) eggs leads to reduced numbers of primordial germ cells

Several media were tested for the extent to which they promoted high fertilization efficiencies in ovulated, stripped Xenopus eggs. One medium was selected for maintaining eggs in a ‘delayed fertilization’ (DelF) condition. DelF eggs displayed several unusual characteristics, including shift of the center of gravity, prominent sperm entrance site, and occasional polyspermy. The frequency of normal pattern formation varied according to the length of time eggs were maintained in the DelF condition. Various developmental abnormalities were observed during gastrulation, neurulation, and organogenesis. Most abnormalities appeared, however, to be related to morphogenesis of the endoderm. Primordial germ cell (PGC) development was examined in DelF eggs which displayed normal external morphological features at the swimming tadpole stage. PGC counts were usually normal in short-duration (eg, 5 hr) DelF eggs, but frequently substantially reduced or completely diminished in longer-duration (eg, 25hr) tadpoles. Six spawnings were compared and shown to exhibit considerable variability in fertility, morphogenesis, and PGC development. Yolk platelet shifts and developmental parameters were examined in two additional spawnings. The subcortical cytoplasm in which the germ plasm is normally localized appeared to be disrupted in longer duration DelF eggs. That observation may account for low PGC counts in DelF tadpoles.     

The protein encoded by the germ plasm RNA Germes associates with dynein light chains and functions in Xenopus germline development

Germ plasm plays a prominent role in germline formation in a large number of animal taxons. We previously identified a novel maternal RNA named Germes associated with Xenopus germ plasm. In the present work, we addressed possible involvement of Germes protein in germ plasm function. Expression in oocytes followed by confocal microscopy revealed that the EGFP fused to Germes, in contrast to the free EGFP, co-localized with the germ plasm. Overexpression of intact Germes and Germes lacking both leucine zipper motifs (GermesDeltaLZs) resulted in a statistically significant reduction of the number of primordial germ cells (PGCs). Furthermore, the GermesDeltaLZs mutant inhibited PGC migration and produced abnormalities in germ plasm intra-cellular distribution at tailbud stages. To begin unraveling biochemical interactions of Germes during embryogenesis, we searched for Germes partners using yeast two-hybrid (YTH) system. Two closely related sequences were identified, encoding Xenopus dynein light chains dlc8a and dlc8b. Tagged versions of Germes and dlc8s co-localize in VERO cells upon transient expression and can be co-immunoprecipitated after injection of the corresponding RNAs in Xenopus embryos, indicating that their interactions occur in vivo. We conclude that Germes is involved in organization and functioning of germ plasm in Xenopus, probably through interaction with motor complexes.     

The mode and molecular mechanisms of the migration of presumptive PGC in the endoderm cell mass of Xenopus embryos

We investigated the mode of migration of presumptive primordial germ cells (pPGC) in the endoderm cell mass of Xenopus embryos at stages 7-40. The molecules underlying the migration were also studied cytochemically and immunocytologically. By examining the relative positions of pPGC and somatic cells derived from the single, fluorescein-dextran lysine (FDL)-injected, germ plasm-bearing cells of stage 6 embryos, pPGC in embryos at stages 7-23 and those at stages later than 24 were assumed to passively and actively migrate in the endoderm cell mass, respectively. This assumption was supported by the observation that F-actin, essential for active cell migration, was recognized on pPGC of the latter stages, but never on those of the former ones. In addition, the molecule like CXC chemokine receptor 4 (CXCR4) found on directionally migrating PGC in mouse and zebrafish, probably Xenopus CXCR4 (xCXCR4), was detected on pPGC only at latter stages. Accordingly, F-actin and xCXCR4, and probably beta1-integrin and collagen type IV, which are indispensable for the formation of F-actin, are thought to be involved in the active migration of pPGC in the endoderm cell mass.     

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.     

Immuno-Localization of DEAD Family Proteins in Germ Line Cells of Xenopus Embryos.

In order to investigate whether a vasa -like protein is present in germ line cells of Xenopus , antibodies were produced which react specifically with synthetic oligopeptides of sequences from near the N- or C-termini or with one including the DEAD box of the Drosophila vasa protein.
Only the antibody against the oligopeptide including the DEAD box reacted strongly with germ plasm (GP) or with cytoplasm of germ line cells of Xenopus embryos by immunofluorescence microscopy. By immunoelectron microscopy, the antibody was demonstrated to react with the GP-specific structure, germinal granules, in cleaving embryos, and with their derivatives in the germ line cells of embryos at stages extending from gastrula to feeding tadpole. It also reacted with mitochondria not only in the GP and the germ line cells but also in somatic cells, and with myofibrils in muscle cells. By Western blotting, the antibody was shown to react with several bands of Mr 42–69 ± 10³ in protein samples from Xenopus embryos. In samples from Drosophila ovaries, it reacted with a Mr 71 ± 10³ band which was probably the vasa protein. This indicates the possibility that Xenopus embryos contain several DEAD family proteins. One of these is present on germinal granules, resembling the vasa protein on polar granules of Drosophila .     

Germline development in amniotes: A paradigm shift in primordial germ cell specification

In the field of germline development in amniote vertebrates, primordial germ cell (PGC) specification in birds and reptiles remains controversial. Avians are believed to adopt a predetermination or maternal specification mode of PGC formation, contrary to an inductive mode employed by mammals and, supposedly, reptiles. Here, we revisit and review some key aspects of PGC development that channelled the current subdivision, and challenge the position of birds and reptiles as well as the ‘binary’ evolutionary model of PGC development in vertebrates. We propose an alternative view on PGC specification where germ plasm plays a role in laying the foundation for the formation of PGC precursors (pPGC), but not necessarily of PGCs. Moreover, inductive mechanisms may be necessary for the transition from pPGCs to PGCs. Within this framework, the implementation of data from birds and reptiles could provide new insights on the evolution of PGC specification in amniotes.     

A critical role for Xdazl, a germ plasm-localized RNA, in the differentiation of primordial germ cells in Xenopus

Xdazl is an RNA component of Xenopus germ plasm and encodes an RNA-binding protein that can act as a functional homologue of Drosophila boule. boule is required for entry into meiotic cell division during fly spermatogenesis. Both Xdazl and boule are related to the human DAZ and DAZL, and murine Dazl genes, which are also involved in gamete differentiation. As suggested from its germ plasm localization, we show here that Xdazl is critically involved in PGC development in Xenopus. Xdazl protein is expressed in the cytoplasm, specifically in the germ plasm, from blastula to early tailbud stages. Specific depletion of maternal Xdazl RNA results in tadpoles lacking, or severely deficient in, primordial germ cells (PGCs). In the absence of Xdazl, PGCs do not successfully migrate from the ventral to the dorsal endoderm and do not reach the dorsal mesentery. Germ plasm aggregation and intracellular movements are normal indicating that the defect occurs after PGC formation. We propose that Xdazl is required for early PGC differentiation and is indirectly necessary for the migration of PGCs through the endoderm. As an RNA-binding protein, Xdazl may regulate translation or expression of factors that mediate migration of PGCs.     

Topology of the germ plasm and development of primordial germ cells in inverted amphibian eggs

Abstract. Inverted Xenopus eggs have reduced numbers of primordial germ cells (PGCs). The extent of the reduction varies from spawning to spawning. Histologic examination revealed that PGC counts were lowest in inverted eggs which displayed the greatest amount of shift in the vegetal mass of large yolk platelets, although the germ plasm itself always remained localized in the egg's original vegetal hemi-sphere. Even at blastulation the germ plasm continued to be localized in the egg's original vegetal hemisphere. In many cases, however, it was confined to the periphery of the embryo, which probably accounts for the reduced PGC number in some tadpoles. In other cases it may have been dispersed and therefore not detectable in histologic analyses.
Although the altered site of involution in inverted embryos did not influence PGC development, subsequent cell movement patterns apparently did. Those embryos which displayed the largest degree of pattern reversal at the tail-bud stage also exhibited the most extreme reduction in PGC numbers. A brief cold shock (4° C, 10 min) prior to first cleavage leads to a further reduction in PGC numbers in inverted embryos, probably as a result of the displace-ment of the germ plasm away from its original vegetal pole location.     

Topology of the germ plasm and development of primordial germ cells in inverted amphibian eggs

Inverted Xenopus eggs have reduced numbers of primordial germ cells (PGCs). The extent of the reduction varies from spawning to spawning. Histologic examination revealed that PGC counts were lowest in inverted eggs which displayed the greatest amount of shift in the vegetal mass of large yolk platelets, although the germ plasm itself always remained localized in the egg's original vegetal hemisphere. Even at blastulation the germ plasm continued to be localized in the egg's original vegetal hemisphere. In many cases, however, it was confined to the periphery of the embryo, which probably accounts for the reduced PGC number in some tadpoles. In other cases it may have been dispersed and therefore not detectable in histologic analyses. Although the altered site of involution in inverted embryos did not influence PGC development, subsequent cell movement patterns apparently did. Those embryos which displayed the largest degree of pattern reversal at the tail-bud stage also exhibited the most extreme reduction in PGC numbers. A brief cold shock (4 degrees C, 10 min) prior to first cleavage leads to a further reduction in PGC numbers in inverted embryos, probably as a result of the displacement of the germ plasm away from its original vegetal pole location.     

A combination of Buffalo rat liver cell-conditioned medium, forskolin and membrane-bound stem cell factor stimulates rapid proliferation of mouse primordial germ cells in vitro similar to that in vivo

Recent studies have shown that stem cell factor (SCF), leukemia inhibitory factor (LIF), basic fibroblast growth factor (bFGF) and the enhancement of cAMP levels increase proliferation and survival of mouse primordial germ cells (PGC) in vitro . Even after the addition of these factors, however, it is still not possible to obtain proliferation of PGC at a rapid rate similar to that in vivo , suggesting the presenge of other growth factor(s) in vivo . We previously reported that tumor necrosis factor-α stimulates proliferation of PGC at earlier migration stages. We now show that the use of SI/SI4-m220 feeder cells and the addition of a medium conditioned with Buffalo rat liver cells and forskolin to the culture medium stimulate PGC obtained from 8.5 days post coitum embryos to proliferate in culture at a rate comparable to that in vivo . Under such conditions, proliferation of PGC continued several days past the timing of growth arrest in vivo ; however, it did stop afterwards. Such proliferating PGC continue to express c-kit and Oct-3 proteins. The characteristics of the culture medium and the requirement of feeder cells were different from those for embryonic stem (ES) cells, suggesting that these rapidly proliferated PGC are not transformed into ES-like EG cells.