Kohji Ikenishi

Germ plasm in Caenorhabditis elegans, Drosophila and Xenopus

Special cytoplasm, called germ plasm, that is essential for the differentiation of germ cells is localized in a particular region of Caenorhabditis elegans, Drosophila and Xenopus eggs. The mode of founder cell formation of germline, the origin and behavior of the germline granules, and the molecules localized in germline cells are compared in these organisms. The common characteristics of the organisms are mainly as follows. First, the founder cells of germline are established before the intiation of gastrulation. Second, the germline granules or their derivatives are always present in germline cells or germ cells throughout the life cycle in embryos, larvae, and adults. Lastly, among the proteins localized in the germ plasm, only Vasa protein or its homolog is detected in the germline cells or germ cells throughout the life cycle. As the protein of vasa homolog has been reported to be also localized in the germline‐specific structure or nuage in some of the organisms without the germ plasm, the possibility that the mechanism for differentiation of primordial germ cells is basically common in all organisms with or without the germ plasm is discussed.

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 expression of Xenopus vasa homolog, XVLG1, in oocytes and embryos: The presence of XVLG1 RNA in somatic cells as well as germline cells

The expression of Xenopus vasa homolog or XVLG1 was examined in oocytes and embryos by whole‐mount in situ hybridization and reverse transcription–polymerase chain reaction (RT‐PCR). To confirm the results in embryos, both methods were also applied to explants of germ plasm‐bearing cells (GPBC) from 32‐cell embryos and to those of partial embryos deprived of GPBC. By hybridization, XVLG1 ribonucleic acid (RNA) was shown to be present throughout the cytoplasm in oocytes at stages I–III, except for the mitochondrial cloud. It was barely recognizable in a portion of germline cells of embryos at specific stages, notwithstanding that XVLG1 protein was present in those cells almost throughout their life‐span. A weak signal for the RNA was detectable in some of the presumptive primordial germ cells (pPGC, descendants of GPBC from the gastrula stage onward) from the late gastrula (stage 12) to the hatching tadpole stage (stage 33/34), and in some of the PGC at stages 49–50. The results for pPGC were confirmed by the hybridization of explants of GPBC at equivalent stages in control embryos. In contrast, XVLG1 RNA was detected in certain somatic cells of embryos until stage 46. These observations were supported in part by the results of RT‐PCR for embryos and explants. The possible role of the product of XVLG1 was reconsidered given its presence in both germline and somatic cells.

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.

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.

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.

Cortical granules remaining after fertilization in Xenopus laevis

Abstract Eggs of Xenopus laevis were examined in an electron microscope at unfertilized egg, 1-cell, 2-cell, 32-cell, and blastula stages. Granules closely resembling cortical granules were observed within the “germinal plasm” as well as in the peripheral cytoplasm of all the eggs examined. A staining method was developed that makes it easier to count cortical granules in thick Epon sections. Light and electron microscope examinations revealed that granules remaining after fertilization possessed morphological characteristics wholly consistent with those of cortical granules of unfertilized eggs. These granules were confirmed to be true cortical granules.

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 β1‐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.

Analysis of SDF-1/CXCR4 signaling in primordial germ cell migration and survival or differentiation in Xenopus laevis

Directional migration of primordial germ cells (PGCs) toward future gonads is a common feature in many animals. In zebrafish, mouse and chicken, SDF-1/CXCR4 chemokine signaling has been shown to have an important role in PGC migration. In Xenopus, SDF-1 is expressed in several regions in embryos including dorsal mesoderm, the target region that PGCs migrate to. CXCR4 is known to be expressed in PGCs. This relationship is consistent with that of more well-known animals. Here, we present experiments that examine whether chemokine signaling is involved in PGC migration of Xenopus. We investigate: (1) Whether injection of antisense morpholino oligos (MOs) for CXCR4 mRNA into vegetal blastomere containing the germ plasm or the precursor of PGCs disturbs the migration of PGCs? (2) Whether injection of exogenous CXCR4 mRNA together with MOs can restore the knockdown phenotype? (3) Whether the migratory behavior of PGCs is disturbed by the specific expression of mutant CXCR4 mRNA or SDF-1 mRNA in PGCs? We find that the knockdown of CXCR4 or the expression of mutant CXCR4 in PGCs leads to a decrease in the PGC number of the genital ridges, and that the ectopic expression of SDF-1 in PGCs leads to a decrease in the PGC number of the genital ridges and an increase in the ectopic PGC number. These results suggest that SDF-1/CXCR4 chemokine signaling is involved in the migration and survival or in the differentiation of PGCs in Xenopus.

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.