Chemoattractant action and molecular signaling pathways of Kit ligand on mouse primordial germ cells

Using a Transwell chamber as migration assay for mouse primordial germ cells (PGCs), we show here that these cells posses directional migration in the absence of somatic cell and defined matrix support and in response to a Kit ligand (KL) gradient or medium conditioned by Aorta/Gonad/Mesonephros and gonadal ridges. Other putative PGC chemoattractants such as SDF1 and TGFbeta did not exert any attractive action on PGCs. The chemoattractant activity of KL and conditioned medium was also evidenced by their ability to stimulate actin reorganization in PGCs. In the aim to identify downstream signaling pathways governing KL chemoattraction on PGCs, we demonstrated that in such cells KL rapidly (5 min) increased autophosphorylation of its receptor c-Kit and caused phosphorylation of the serine-threonine kinase AKT through the action of PI3K. 740Y-P peptide, a direct activator of PI3 kinase, stimulated PGC migration at levels similar to those elicited by KL. LY294002 (a specific inhibitor of PI3K) abolished KL-dependent PGC migration or the chemoattractant activity of the conditioned medium and inhibited AKT phosphorylation; Src kinase inhibitors PP2 and SU6656, caused significant reduction of the KL-dependent PGC migration and AKT phosphorylation, while U0126, a selective inhibitor of the MEK/ERK protein kinase cascade, reduced PGC migration and AKT phosphorylation at lesser extent. SU6656 completely abolished the chemoattractant activity of the conditioned medium. Finally, SB202190 (a p38 inhibitor) and rapamycin (mTOR inhibitor) did not affect PGC migration. In addition, to demonstrate that somatic cells are not essential for PGC motility and directional migration, we evidenced a novel role for KL as PGC chemoattractant and for PI3K/AKT and Src kinase, as players involved in the activation of the PGC migratory machinery and likely important for their directional movement towards the gonadal ridges.     

Migration and proliferation of primordial germ cells in the rat

Information about early primordial germ cell (PGC) formation and migration in rats is lacking. In utero developed and in vitro cultivated whole rat embryos were studied on days 10-13 postcoitum (p.c.). The development of the PGCs was investigated in serial sections stained for alkaline phosphatase activity. On postcoital day 10, PGCs were found in the invaginating visceral yolk sac endoderm and at the base of the allantois. At day 11 p.c. PGCs were mostly found in the ventral and lateral gut wall or in the mesenchyme between the gut and the future genital ridges. At day 12 p.c. most of the PGCs (94%) could be localised in the mesenchyme or in the future genital ridges. On postcoital day 13 almost all PGCs had reached the now-well-developed genital ridges. Quantitative measurements showed an increase in the number of PGCs from 84 at day 10 p.c. up to 2,768 at day 13 p.c. Only slight differences were found between in vivo and in vitro embryos with respect to the number of PGCs and their developmental pattern. The in vitro culture of whole rat embryos enables the discrimination between the effects of indirect (maternal) and direct action of PGC-toxic agents.     

Insulin-like growth factor receptor 1b is required for zebrafish primordial germ cell migration and survival

Insulin-like growth factor (IGF) signaling is a critical regulator of somatic growth during fetal and adult development, primarily through its stimulatory effects on cell proliferation and survival. IGF signaling is also required for development of the reproductive system, although its precise role in this regard remains unclear. We have hypothesized that IGF signaling is required for embryonic germline development, which requires the specification and proliferation of primordial germ cells (PGCs) in an extragonadal location, followed by directed migration to the genital ridges. We tested this hypothesis using loss-of-function studies in the zebrafish embryo, which possesses two functional copies of the Type-1 IGF receptor gene (igf1ra, igf1rb). Knockdown of IGF1Rb by morpholino oligonucleotides (MO) results in mismigration and elimination of primordial germ cells (PGCs), resulting in fewer PGCs colonizing the genital ridges. In contrast, knockdown of IGF1Ra has no effect on PGC migration or number despite inducing widespread somatic cell apoptosis. Ablation of both receptors, using combined MO injections or overexpression of a dominant-negative IGF1R, yields embryos with a PGC-deficient phenotype similar to IGF1Rb knockdown. TUNEL analyses revealed that mismigrated PGCs in IGF1Rb-deficient embryos are eliminated by apoptosis; overexpression of an antiapoptotic gene (Bcl2l) rescues ectopic PGCs from apoptosis but fails to rescue migration defects. Lastly, we show that suppression of IGF signaling leads to quantitative changes in the expression of genes encoding CXCL-family chemokine ligands and receptors involved in PGC migration. Collectively, these data suggest a novel role for IGF signaling in early germline development, potentially via cross-talk with chemokine signaling pathways.     

In vitro adhesion of mouse fetal germ cells to extracellular matrix components

Mouse primordial germ cells (PGCs) isolated from the dorsal mesentery and gonadal ridges of 10.5–12.5 days post coitum (dpc) embryos showed a progressively increasing adhesiveness to laminin and fibronectin coated substrates, whereas type I collagen and various glycosaminoglycans (hyaluronic acid, heparin and chondroitinsulphates) were poor adhesive substrates. At later stages germ cells appeared to lose their adhesiveness to fibronectin and laminin substrates; the ability to adhere to laminin decreased very rapidly in male and slowly in female germ cells. Oocytes and prospermatogonia from 15.5 dpc fetal gonads showed poor adhesiveness to all substrates tested. PGC adhesion to laminin and fibronectin substrates did not require calcium but was markedly trypsin sensitive. Antibodies against the fibronectin receptor of CHO fibroblasts and short peptides containing the Arg-Gly-Asp sequence greatly reduced PGC adhesion to fibronectin. Following adhesion to laminin or fibronectin, most PGCs did not exhibit a morphology typical of motile cells, but remained spherical. A significant proportion (about 30%) of oocytes from 13.5–14.5 dpc embryos appeared, however, able to spread and elongate following attachment to laminin. The results support the hypothesis that mouse PGCs may utilize laminin and/or fibronectin as adhesive substrates during migration and gonad colonization, but indicate that additional factors are probably required to promote PGC motility. In addition, our data provide indirect evidence that binding sites for specific components of extracellular matrix are present in PGCs, and that their expression may be developmentally regulated.     

Germ line chimera produced by transfer of cultured chick primordial germ cells.

Intrinsic primordial germ cells (PGCs) from stage 27 (5-day-old) chick embryonic germinal ridges were cultured in vitro for a further 5 days, and shown to proliferate on stroma cells derived from the germinal ridge. To determine whether these cultured PGCs could colonize and contribute to the germ-line, PGCs were isolated by gentle pipetting, labeled with PKH26 fluorescent dye and injected into the blood stream of stage 17 (2.5-day-old) chick embryos. The recipient embryos were incubated until they reached stage 28. Thin sections of these embryos were analysed by fluorescent confocal laser microscopy. These analyses showed that the labeled donor PGCs had migrated into the germinal ridges of the recipient embryos, and transplanted PGCs had undergone at least 3-7 divisions. These results suggest that PGCs that had passed far beyond the migration stage in vivo were still able to migrate, colonize and proliferate in recipient chick embryonic gonads.     

Generation of germ-line chimera zebrafish using primordial germ cells isolated from cultured blastomeres and cryopreserved embryoids

Primordial germ cells (PGCs) are the only cells in developing embryos with the potential to transmit genetic information to the next generation. In our previous study, a single PGC transplanted into a host differentiated into fertile gametes and produced germ-line chimeras of cyprinid fish, including zebrafish. In this study, we aimed to induce germ-line chimeras by transplanting donor PGCs from various sources (normal embryos at different stages, dissociated blastomeres, embryoids, or embryoids cryopreserved by vitrification) into host blastulae, and compare the migration rates of the PGCs towards the gonadal ridge. Isolated, cultured blastomeres not subject to mesodermal induction were able to differentiate into PGCs that retained their motility. Moreover, these PGCs successfully migrated towards the gonadal ridge of the host and formed viable gametes. Motility depended on developmental stage and culture duration: PGCs obtained at earlier developmental stages and with shorter cultivation periods showed an increased rate of migration to the gonadal ridge. Offspring were obtained from natural spawning between normal females and chimeric males. These results provide the basis for new methods of gene preservation in zebrafish.     

Regulation of zebrafish primordial germ cell migration by attraction towards an intermediate target.

Migration of primordial germ cells (PGCs) from their site of specification towards the developing gonad is controlled by directional cues from somatic tissues. Although in several animals the PGCs are attracted by signals emanating from their final target, the gonadal mesoderm, little is known about the mechanisms that control earlier steps of migration. We provide evidence that a key step of zebrafish PGC migration, in which the PGCs become organized into bilateral clusters in the anterior trunk, is regulated by attraction of PGCs towards an intermediate target. Time-lapse observations of wild-type and mutant embryos reveal that bilateral clusters are formed at early somitogenesis, owing to migration of PGCs towards the clustering position from medial, posterior and anterior regions. Furthermore, PGCs migrate actively relative to their somatic neighbors and they do so as individual cells. Using mutants that exhibit defects in mesoderm development, we show that the ability to form PGC clusters depends on proper differentiation of the somatic cells present at the clustering position. Based on these findings, we propose that these somatic cells produce signals that attract PGCs. Interestingly, fate-mapping shows that these cells do not give rise to the somatic tissues of the gonad, but rather contribute to the formation of the pronephros. Thus, the putative PGC attraction center serves as an intermediate target for PGCs, which later actively migrate towards a more posterior position. This final step of PGC migration is defective in hands off mutants, where the intermediate mesoderm of the presumptive gonadal region is mispatterned. Our results indicate that zebrafish PGCs are guided by attraction towards two signaling centers, one of which may represent the somatic tissues of the gonad.     

Evidence for crucial role of hindgut expansion in directing proper migration of primordial germ cells in mouse early embryogenesis

During mouse gastrulation, primordial germ cells (PGCs) become clustered at the base of the allantois and move caudally into the hindgut endoderm before entering the genital ridges. The precise roles of endoderm tissues in PGC migration, however, remain unclear. By using Sox17 mutants with a specific endoderm deficiency, we provide direct evidence for the crucial role of hindgut expansion in directing proper PGC migration. In Sox17-null embryos, PGCs normally colonize in the allantois and then a small front-row population of PGCs moves properly into the most posterior gut endoderm. Defective hindgut expansion, however, causes the failure of further lateral PGC movement, resulting in the immobilization of PGCs in the hindgut entrance at the later stages. In contrast, the majority of the remaining PGCs moves into the visceral endoderm layer, but relocate outside of the embryonic gut domain. This leads to a scattering of PGCs in the extraembryonic yolk sac endoderm. This aberrant migration of Sox17-null PGCs can be rescued by the supply of wildtype hindgut cells in chimeric embryos. Therefore, these data indicate that hindgut morphogenic movement is crucial for directing PGC movement toward the embryonic gut side, but not for their relocation from the mesoderm into the endoderm.     

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.     

Evidence for substrate guidance of primordial germ cells

Primordial germ cells (PGCs) have been removed from their normal migratory route in early embryos of Xenopus laevis, and their behaviour studied in vitro. They adhere to, and move over the upper surface of, layers of outgrowing cells from expiants of adult Xenopus mesentery. They move by the extrusion of single filopodia, elongation, forward streaming of the yolky cytoplasm and retraction of their trailing ends. When the underlying cells are polarized in one direction only, PGCs always elongate and move along the same direction. Furthermore, when PGCs elongate and move over less obviously polarized cells, they always do so in the direction of ‘stress fibres’ (actin bundles) in the underlying cells. A substrate-guidance hypothesis for PGC migration is only tenable if there is some orientation in their natural substrate in vivo. Using the scanning electron microscope, we demonstrate that the coelpmic lining cells, beneath which PGCs migrate up the dorsal mesentery of the gut, are orientated in the direction of travel. Furthermore, this orientation changes at the time of gonadal ridge formation. This raises the intriguing possibility that PGCs are guided for at least part of their migration in Xenopus laevis embryos by a substrate-guidance mechanism.     

Isolation of teleost primordial germ cells using flow cytometry

Primordial germ cells (PGCs) generate gametes, the only cells that can transmit genetic information to the next generation. A previous report demonstrated that a fusion construct of green fluorescent protein (gfp) and zebrafish nos 1 3UTR mRNA could be used to label PGCs in a number of fish species. Here, we sought to exploit this labeling strategy to isolate teleost PGCs by flow cytometry (FCM), and to use these isolated PGCs to examine germ cell migration to the gonadal region. In zebrafish, medaka and goldfish, the PGCs were labeled by injecting the gfp-nos1 3UTR mRNA into 1- 4 cell embryos. When the embryos had developed to the somitogenesis or later stages, they were enzymatically disaggregated and GFP positive cells isolated using FCM. PGCs in the different species clustered in the same segments of the FCM scatter diagrams for total embryonic cells produced by plotting the forward scatter intensity against GFP intensity. In situ hybridization showed that the sorted zebrafish cells expressed vasa RNA in their cytoplasm, suggesting that they were PGCs. When the migration ability of the sorted cells from zebrafish was examined in an in vivo transplantation experiment, approximately 30% moved to the gonadal region of host embryos. These observations demonstrate that PGCs can be isolated without use of transgenic fishes and that the isolated PGCs retain the ability to migrate. Our data indicate that this technique will be of value for isolating PGCs from a range of fish species.     

The mechanism for primordial germ-cell migration is conserved between Japanese eel and zebrafish

Primordial germ cells (PGCs) are segregated and specified from somatic cells during early development. These cells arise elsewhere and have to migrate across the embryo to reach developing gonadal precursors. Several molecules associated with PGC migration (i.e. dead-end, nanos1, and cxcr4) are highly conserved across phylum boundaries. However, since cell migration is a complicated process that is regulated spatially and temporally by multiple adaptors and signal effectors, the process is unlikely to be explained by these known genes only. Indeed, it has been shown that there are variations in PGC migration pattern during development among teleost species. However, it is still unclear whether the actual mechanism of PGC migration is conserved among species. In this study, we studied the migration of PGCs in Japanese eel (Anguilla japonica) embryos and tested the migration mechanism between Japanese eel and zebrafish (Danio rerio) for conservation, by transplanting eel PGCs into zebrafish embryos. The experiments showed that eel PGCs can migrate toward the gonadal region of zebrafish embryos along with endogenous PGCs, even though the migration patterns, behaviors, and settlements of PGCs are somewhat different between these species. Our results demonstrate that the migration mechanism of PGCs during embryonic development is highly conserved between these two distantly related species (belonging to different teleost orders).     

Differentiation of mouse primordial germ cells into female or male germ cells.

Mouse primordial germ cells (PGCs) migrate from the base of the allantois to the genital ridge. They proliferate both during migration and after their arrival, until initiation of the sex-differentiation of fetal gonads. Then, PGCs enter into the prophase of the first meiotic division in the ovary to become oocytes, while those in the testis become mitotically arrested to become prospermatogonia. Growth regulation of mouse PGCs has been studied by culturing them on feeder cells. They show a limited period of proliferation in vitro and go into growth arrest, which is in good correlation with their developmental changes in vivo. However, in the presence of multiple growth signals, PGCs can restart rapid proliferation and transform into pluripotent embryonic germ (EG) cells. Observation of ectopic germ cells and studies of reaggregate cultures suggested that both male and female PGCs show cell-autonomous entry into meiosis and differentiation into oocytes if they were set apart from the male gonadal environments. Recently, we developed a two-dimensional dispersed culture system in which we can examine transition from the mitotic PGCs into the leptotene stage of the first meiotic division. Such entry into meiosis seems to be programmed in PGCs before reaching the genital ridges and unless it is inhibited by putative signals from the testicular somatic cells.     

Activin receptor-like kinase (ALK)1 is an antagonistic mediator of lateral TGFbeta/ALK5 signaling

Transforming growth factor-beta (TGFbeta) regulates the activation state of the endothelium via two opposing type I receptor/Smad pathways. Activin receptor-like kinase-1 (ALK1) induces Smad1/5 phosphorylation, leading to an increase in endothelial cell proliferation and migration, while ALK5 promotes Smad2/3 activation and inhibits both processes. Here, we report that ALK5 is important for TGFbeta/ALK1 signaling; endothelial cells lacking ALK5 are deficient in TGFbeta/ALK1-induced responses. More specifically, we show that ALK5 mediates a TGFbeta-dependent recruitment of ALK1 into a TGFbeta receptor complex and that the ALK5 kinase activity is required for optimal ALK1 activation. TGFbeta type II receptor is also required for ALK1 activation by TGFbeta. Interestingly, ALK1 not only induces a biological response opposite to that of ALK5 but also directly antagonizes ALK5/Smad signaling.     

Activin and TGFbeta limit murine primordial germ cell proliferation

Mammalian primordial germ cells (PGCs) proliferate as they migrate from their initial location in the extraembryonic mesoderm to the genital ridge, the gonadal anlage. Once in the genital ridge, PGCs cease dividing and differentiate according to their gender. To identify ligands that might limit PGC proliferation, we analyzed growth factor receptors encoded in RNA obtained from purified germ cells shortly after their arrival in the genital ridge. Receptors for two members of the TGFbeta superfamily were found, TGFbeta1 and activin. As the signal-transducing domains of both receptor systems are highly conserved, the effects of both TGFbeta1 and activin on PGCs would be expected to be similar. We found that both ligands limited the accumulation of germ cells in primary PGC cultures. BrdU incorporation assays demonstrated that either ligand inhibits PGC proliferation. These results suggest that these signal transduction pathways are important elements of the mechanism that determines germ cell endowment.     

TGF beta 1 inhibits proliferation and has a chemotropic effect on mouse primordial germ cells in culture.

Primordial germ cells are the stem cells that provide the functional gametes of adult animals. In many animal groups they are set aside at the earliest stages of development, and migrate from their sites of first appearance to the sites where the gonad will form, the genital ridges. During this migration they proliferate. In the mouse embryo their numbers increase from less than one hundred to approximately four thousand during the period of their migration. In a previous paper we showed that both the proliferation and the direction of migration of mouse PGCs in culture were influenced by soluble factors released from their target tissue, the genital ridges. Studies on other stem cell populations have shown that complex combinations of growth factors control their proliferation, migration and differentiation. In this paper, we show that TGF beta 1 inhibits proliferation of PGCs taken from 8.5 day old embryos and cultured on embryonic fibroblast feeder layers. We also show that the previously reported chemotropic effect of genital ridges in this culture system is mediated by TGF beta 1, or a closely related molecule, released from the genital ridges.     

Purification of Mouse Primordial Germ Cells by MiniMACS Magnetic Separation System

During migration toward gonadal ridges, primordial germ cells (PGCs; the earliest identifiable germ cells in the embryo) are very few in number, move along different tissues, and are not identifiable by morphological criteria alone. Here we report the use of the magnetic cell sorter MiniMACS as a tool for the isolation of such rare cells from 10.5- to 13.5-days post coitum mouse embryos. Cells stained sequentially by TG-1 (a monoclonal IgM antibody known to bind to the surface of PGCs) and superparamagnetic microbeads coated with secondary anti-mouse IgM antibody were separated on a magnetic column. Unlabeled cells (somatic cells) pass through the column, while labeled cells (germ cells) are retained. The retained cells can be eventually easily eluted and immediately used for biochemical studies or grown in suitable in vitro culture systems.