Galactosides and sialylgalactosides in O-linked oligosaccharides of the primordial germ cells in Xenopus embryos

The primordial germ cells (PGCs) are covered by surface glycoconjugates; some of them, like galactose residues recognized by peanut agglutinin (PNA), have been reported to be implicated in the PGC migration process. The aim of this work was the characterization of galactosides and sialylgalactosides in N- and O-linked oligosaccharides of Xenopus PGCs. Galactose(Gal)- and sialic acid(Neu5Ac)-binding lectin cytochemistry, in combination with chemical and enzymatic deglycosylation methods, were used. PGCs were slightly labeled with PNA, RCA-I and BSI-B₄, which suggests the presence of the sequences Gal(1,4)GlcNAc and Gal(1,3)Gal. Moreover, there was no labeling when -elimination pre-treatment was performed, suggesting that galactosides were in O-linked oligosaccharides. The strong staining with DSA was probably due to GlcNAc. Furthermore, sialylgalactosides with the sequence Neu5Ac(2,3)Gal(1,4)GlcNAc in O-linked oligosaccharides have been shown by means of MAA, PNA and RCA-I.     

Lectin histochemistry shows fucosylated glycoconjugates in the primordial germ cells of Xenopus embryos.

Previous works have shown that glycoconjugates with terminal fucose (Fuc) are located in the primordial germ cells (PGCs) of some mammals and might play a role in the migration and adhesion processes during development. The aim of this work was to identify the terminal Fuc moieties of Xenopus PGCs by means of three Fuc-binding lectins: from asparagus pea (LTA), gorse seed (UEA-I), and orange peel fungus (AAA). The histochemical procedures were also carried out after deglycosylation pretreatments: beta-elimination with NaOH to remove O-linked oligosaccharides; incubation with PNGase F to remove N-linked carbohydrate chains; and incubation with alpha(1,2)- and alpha(1,6)-fucosidase. The PGCs were always negative for LTA and UEA-I, two lectins that have the highest affinity for Fuc alpha(1,2)-linked. However, the PGCs were strongly labeled with AAA, which preferentially binds to Fuc with alpha(1,3) or alpha(1,4) linkages and to Fuc alpha(1,6)-linked to the proximal N-acetylglucosamine. There was fainter labeling with AAA when the sections were preincubated with alpha(1,6)-fucosidase, but the labeling remained strong when the sections were pretreated with alpha(1,2)fucosidase. When the beta-elimination procedure was carried out, the PGC labeling with AAA was slight. If the PNGase F incubation was performed, the PGCs remained moderately positive for AAA. These data suggest that the Xenopus PGCs have Fuc moieties in O- and N-linked oligosaccharides, including Fuc alpha(1,6) linked to the innermost GlcNAc, and that the Fuc was not in alpha(1,2)-linkage.     

Developmental regulation of locomotive activity in Xenopus primordial germ cells

Primordial germ cells (PGCs) arise in the early embryo and migrate toward the future gonad through species‐specific pathways. They are assumed to change their migration properties dependent on their own genetic program and/or environmental cues, though information concerning the developmental change in PGC motility is limited. First, we re‐examined the distribution of PGCs in the endodermal region of Xenopus embryos at various stages by using an antibody against Xenopus Daz‐like protein, and found four stages of migration, namely clustering, dispersing, directionally migrating and re‐aggregating. Next, we isolated living PGCs at each stage and directly examined their morphology and locomotive activity in cell cultures. PGCs at the clustering stage were round in shape with small blebs and showed little motility. PGCs in both the dispersing and the directionally migrating stages alternated between the locomotive phase with an elongated morphology and the pausing phase with a rugged morphology. The locomotive activity of the elongated PGCs was accompanied by the persistent formation of a large bleb at the leading front. The duration of the locomotive phase was shortened gradually with the transition from the dispersing stage to the directionally migrating stage. At the re‐aggregating stage, PGCs became round in shape and showed no motility. Thus, we directly showed that the locomotive activity of PGCs changes dynamically depending upon the migrating stage. We also showed that the locomotion and blebbing of the PGCs required F‐actin, myosin II activity and RhoA/Rho‐associated protein kinase (ROCK) signaling.     

Contact relations and guidance of primordial germ cells on their migratory route in embryos of Xenopus laevis

This paper describes the relationship between primordial germ cells (p.g.cs) and the substrate over which they migrate in early embryos of the anuran amphibian Xenopus laevis. P.g.cs migrate from the embryonic gut to the dorsal body wall along the dorsal mesentery at the earliest swimming stage. Our earlier papers have described the way in which p.g.cs move in vitro. In this work we have studied the shape and cytoarchitecture of both p.g.cs and the coelomic epithelial cells (c.e.cs) over which they migrate. We have concentrated on three aspects of the morphology of these cells: first the shapes of the c.e.cs and the way that they affect the shapes of the p.g.cs; secondly the presence of adhesion plaques between the two types of cell; and thirdly the arrangement of cytoskeleton elements. The results show that c.e.cs in the dorsal mesentery are orientated cranio-caudally while those on the dorsal body wall and at the junction with the mesentery are arranged transversely, at 90 degrees to the cranio-caudal plane. P.g.cs are found in both elongated and rounded state. Where elongated, they are always in the same plane as the c.e.cs with which they are associated. The implications of this are discussed. Adhesion plaques between p.g.cs and c.e.cs are shown both by disaggregation studies and transmission electron microscope studies. Plaques are associated with the well defined microfilamentous cytoskeleton of c.e.cs, but only with a sparse array of filaments in p.g.cs. The only parts of p.g.cs where filaments are regularly found are their filopodia, which are generally seen on elongated p.g.cs in longitudinal section. We suggest on the basis of this work that p.g.cs have a dispersed cytoskeleton except during filopod extension, that they move by forming direct adhesion plaques with c.e.cs, and that c.e.cs provide a firm orientated support and possible guide to p.g.c. movement.     

On the fate of primordial germ cells injected into early mouse embryos

Primordial germ cells (PGCs) are the founder cells of the germline. Via gametogenesis and fertilisation this lineage generates a new embryo in the next generation. PGCs are also the cell of origin of multilineage teratocarcinomas. In vitro, mouse PGCs can give rise to embryonic germ (EG) cells – pluripotent stem cells that can contribute to primary chimaeras when introduced into pre-implantation embryos. Thus, PGCs can give rise to pluripotent cells in the course of the developmental cycle, during teratocarcinogenesis and by in vitro culture. However, there is no evidence that PGCs can differentiate directly into somatic cell types. Furthermore, it is generally assumed that PGCs do not contribute to chimaeras following injection into the early mouse embryo. However, these data have never been formally published. Here, we present the primary data from the original PGC-injection experiments performed 40 years ago, alongside results from more recent studies in three separate laboratories. These results have informed and influenced current models of the relationship between pluripotency and the germline cycle. Current technologies allow further experiments to confirm and expand upon these findings and allow definitive conclusions as to the developmental potency of PGCs.     

A trial for induction of supernumerary primordial germ cells in Xenopus tadpoles by injecting RNA of Xenopus vasa homologue into germline cells of 32-cell embryos

Whether overexpression of Xenopus vasa homologue or Xenopus vasa-like gene 1 (XVLG1) in germline cells of Xenopus embryos can induce supernumerary primordial germ cells (PGC) at tadpole stage was investigated. XVLG1 RNA (0.1-2.0 ng) and beta-gal RNA (0.5 ng) were injected into one of, usually, four germ plasm-bearing cells (GPBC) of 32-cell embryos, with the beta-gal RNA (2.0 ng) serving as both lineage tracer and control for XVLG1 RNA. The total number of PGC, including X-gal-stained and unstained PGC of injected and uninjected GPBC origins respectively, was examined in the experimental tadpoles developed from the injected embryos. The injected RNA, XVLG1 and beta-gal RNA, were translated, resulting in a large amount of corresponding proteins in presumptive PGC (pPGC) as well as in somatic cells derived from the injected GPBC. Nevertheless, the average number of total PGC per tadpole found in the experimental tadpoles from the XVLG1 RNA-injected embryos was not significantly different from that of beta-gal RNA-injected ones, irrespective of the injected dose of XVLG1 RNA. This indicates that the extra XVLG1 protein in pPGC is not sufficient to increase the number of PGC in the tadpoles.     

The histochemical identification of primordial germ cells in diploid parthenogenetic mouse embryos

An attempt has been made to improve the early post-implantation development potential of diploid parthenogenetic mouse embryos by transferring parthenogenetic blastocysts to one uterine horn of a pseudopregnant recipient and a similar number of fertilized embryos to the contralateral horn. In control studies, diploid parthenogenetic embryos were transferred to both uterine horns of appropriate recipients. Unfortunately no obvious advantage appeared to be gained by carrying out the former manoeuvre. A significant improvement in the development potential of the parthenogenones could have indicated that their poor post-implantation survival might have been associated with a deficiency, possibly of hormonal origin, in the functioning of their decidual reaction. However, sufficient somite-containing parthenogenetic embryos were obtained in this study to allow a comparison to be made between them and fertilized embryos that were morphologically at a comparable stage of development. The parthenogenones were found to have a markedly smaller crown-rump length than their fertilized counterparts. A high proportion of both the parthenogenetic and fertilized embryos were subsequently fixed and appropriately stained in order to localize alkaline phosphatase activity. The analysis of this material clearly demonstrated that parthenogenetic mouse embryos are in fact capable of producing primordial germ cells. The latter were recognized by their morphology, histochemical staining appearance, and characteristic location, being found in the early 'turned' embryos within the dorsal mesentery in close proximity to the developing gut tube, and in the more advanced limb-bud stage embryos within the gonadal ridges.     

Histochemical identification of primordial germ cells in diandric and digynic triploid mouse embryos

Diandric and digynic triploid mouse embryos were isolated in the morning on day 10 of gestation. The embryos were separated from their extraembryonic membranes, and the latter were analysed cytogenetically by G-banding to establish the ploidy and sex chromosome constitution of these embryos. The diandric triploid embryos were produced by the technique of nuclear micromanipulation. Females were mated with male mice with a morphologically distinguishable "marker" chromosome to confirm the diandric status of these embryos. Digynic triploid and normal diploid embryos were isolated from LT/Sv strain females. These females spontaneously ovulate both primary and secondary oocytes, which are fertilisable and give rise to digynic triploid and normal diploid embryos, respectively. All the embryos were serially sectioned and processed in order to demonstrate the presence of alkaline phosphatase enzyme activity. This histochemical technique allowed primordial germ cells to be readily recognised, due to their characteristic location, cellular morphology, and staining appearance. Primordial germ cells were found in all the embryos studied, being located within the visceral yolk sac, at the base of the allantois, and/or in association with the wall or mesentery of the hindgut. The total number of germ cells present was established in nine diandric triploids and in five digynic triploids. The findings presented here represent the first demonstration that primordial germ cells can differentiate in either diandric or digynic triploid mammalian embryos.     

Simple method for isolation of primordial germ cells from chick embryos.

A simple one step centrifugation method was developed for purification of primordial germ cells (PGCs) of chick embryos. PGCs, constituting less than 0.1% of the total blood cells of stage 13-14 embryos that contained a microliter amount of blood, were concentrated at the interface of a 6.3% (w/v) and 14.4% (w/v) Ficoll bilayer by centrifugation at 800 x g for 30 min. the purity of these PGCs was 86%, which was 22 times that obtained previously.     

Ontogenesis of primordial germ cells

In sexually reproducing animals all gametes of either sex arise from primordial germ cells (PGC). PGC represent a small cell population, appearing early during embryo development. They represent a key cell population responsible for the survival and the evolution of a species. Indeed, the production of gametes will assure fertilisation and therefore the establishment of the next generation. Until recently only few laboratories were working on PGC biology. A new interest emerged since these cells have the ability to function as pluripotent stem cells when established as cell lines. Indeed, like embryonic stem cells (ESC), embryonic germ cells (EGC) are able to differentiate in a wide variety of tissues. In vivo, EGC are able, after injection into a host blastocyst cavity to colonise the inner cell mass and to participate in embryonic development. In vitro studies in human and mouse have also shown their capacity to differentiate into a large variety of cell types allowing the study of processes involved in cardiomyocyte, haematopoietic, neuronal and myogenic differentiation pathways. We present here the last updates of PGC ontogeny focusing mainly on the murine model.     

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.     

Detection and characterization of primordial germ cells in pheasant (Phasianus colchicus) embryos

The developmental similarity between the chicken and pheasant (Phasianus colchicus) allows the novel biotechnologies developed in the chicken to be applied to the production of transgenic pheasants and interspecies germline chimeras. To detect pheasant primordial germ cells (PGCs) efficiently, which is important for inducing germline transmission, the ultrastructure of PGCs and their reactivity to several antibodies (2C9, QB2, anti-SSEA-1, and QCR1) and periodic acid-Schiff's solution (PAS) were examined. To obtain PGCs, blood was taken from embryos incubated for 62-72 h or from gonads from embryos incubated for 156-216 h. The PGCs collected from both sources had the typical ultrastructure of pluripotent cells: a large nucleus with a distinct nucleolus, a high ratio of nuclear to cytoplasmic volume, and a distinct cytoplasmic membrane. In comparing the morphology of PGCs collected from different sites, more mitochondria and better-developed membrane microvilli were found in gonadal PGCs than in circulating PGCs. The nucleus of gonadal PGCs was flattened and had a large eccentrically positioned nucleolus. Of the antibodies tested, only QCR1 antibody reacted with an epitope in pheasant PGCs, and no specific signal was detected to other antibodies. The temporal change in the PGC populations in the blood and gonads of embryos was examined. In blood, the population was greater (P < 0.0001) in embryos incubated for 64 h than in embryos incubated for 62 or 66-72 h (31.4 versus 5.6-16.2 microL(-1)). In embryonic gonads, the number of PGCs increased continuously from 156 to 216 h of incubation (193-2,718 cells/embryo), although the ratio of PGCs to total gonadal cells did not change significantly (0.50-0.61%). In conclusion, pheasant PGCs have typical germ cell morphology and possess the QCR1 epitope. Circulating blood and the gonads of embryos incubated for 64 and 216 h, respectively, are good sources of PGCs.     

The primordial germ cells in early mouse embryos: light and electron microscopic studies

The migrating primordial germ cells in mouse embryos aged between 8.5 and 11 days were identified under the light and electron microscopes by means of localizing alkaline phosphatase activity, and their ultrastructure was studied. Most of the migrating primordial germ cells were round with smooth contour; they were invariably in close contact with irregularly shaped surrounding cells. The ultrastructural characteristics of early primordial germ cells included: prominent nucleoli, cytoplasmic protrusions into the nuclei, Golgi complexes with alkaline phosphatase activity, disappearance of granular endoplasmic reticulum with increasing age of the embryos, dense cytoplasm with extremely abundant ribosomes, and cytoplasmic dense granules. The significance of these findings is discussed in relation to the origin and migration of mouse primordial germ cells.     

Study on the concentration of circulating primordial germ cells (cPGCs) in early chick embryos

Experiments were conducted to elucidate the factor that influences the concentration of circulating primordial germ cells (cPGCs) in two-day old chick embryos. The concentration of cPGCs was observed to be highest at stage 14 (66.9 +/- 23.2 microliters) and decreased thereafter. However, considerable egg to egg variations in cPGC concentration, especially at stages 13, 14, 15, and 16 were observed. After conducting experiments to elucidate the source of egg to egg variation in cPGC concentration among embryos, it was revealed that there are hens that lay eggs which contain either constantly high (more than 80 PGCs/microliter) or constantly low (less than 30 PGCs/microliter) concentration of cPGCs. The results obtained from the present experiments showed that one of the major source of egg to egg variation in the concentration of cPGCs was due to the individual differences among females that produced the eggs.     

Induction of pluripotency in primordial germ cells

Primordial germ cells (PGCs) are the founder cells of all gametes. PGCs differentiate from pluripotent epiblasts cells by mesodermal induction signals during gastrulation. Although PGCs are unipotent cells that eventually differentiate into only sperm or oocytes, they dedifferentitate to pluripotent stem cells known as embryonic germ cells (EGCs) in vitro and give rise to testicular teratomas in vivo, which indicates a "metastable" differentiation state of PGCs. We have shown that an appropriate level of phosphoinositide-3 kinase (PI3K)/Akt signaling, balanced by positive and negative regulators, ensures the establishment of the male germ lineage by preventing its dedifferentiation. Specifically, hyper-activation of the signal leads to testicular teratomas and enhances EGC derivation efficiency. In addition, PI3K/Akt signaling promotes PGC dedifferentiation via inhibition of the tumor suppressor p53, a downstream molecule of the PI3K/Akt signal. On the other hand, Akt activation during mesodermal differentiation of embryonic stem cells (ESCs) generates PGC-like pluripotent cells, a process presumably induced through equilibrium between mesodermal differentiation signals and dedifferentiation-inducing activity of Akt. The transfer of these cells to ESC culture conditions results in reversion to an ESC-like state. The interconversion between ESC and PGC-like cells helps us to understand the metastability of PGCs. The regulatory mechanisms of PGC dedifferentiation are discussed in comparison with those involved in the dedifferentiation of testicular stem cells, ESC pluripotency, and somatic nuclear reprogramming.     

Isolation of mouse primordial germ cells

Primordial germ cells (PGCs) were obtained from fetal mouse gonads of both sexes days post coitum (dpc), either by collagenase treatment, or by mechanical procedures with or without prior EDTA treatment. With mechanical procedures alone, yield was relatively low and many of the cells released were dead. After EDTA treatment, both yield and viability were significantly improved. Collagenase treatment gave the best yield of cells, since the entire gonad was disaggregated, but contamination with somatic cells was substantial, and the adhesive properties of the germ cells were altered by the treatment. When cells released following EDTA treatment were fractionated on a simple Percoll gradient, several thousand viable PGCs per gonad could be obtained in 2–3 h, with not more than 10–20% somatic cell contamination.     

禽类原始生殖细胞的迁移能力

Blood samples were collected from chicken embryos at stage 11-15,and labeled with fluorescent dye PKH26.Primordial germ cells (PGCs)were then isolated from blood samples by nycodenz density gradient centrifugation.After PGCs were labeled and isolated,about 200 PGCs in one microliter were injected into the subgerminal cavity of quail blastoderm at stageX.After 48 hours incubation,chicken PGCs were identified by fluorescent microscopy.Red fluorescence emitted from PKH26 labeled chicken PGCs was observed in the head, the heart and the developing gonadal anlage of quail embryos.The result suggests that chicken PGCs still keep migration ability after 56 hours[Acta Zoologica Sinica 49(6):868-872,2003].