Growth factors in mouse primordial germ cell migration and proliferation

Information obtained mainly from in vitro culture studies and genetic analysis of mouse mutants White spotting and Steel indicate a pivotal role of growth factors in the development of mouse primordial germ cells (PGCs). While stem cell factor (SCF) and TGFβ1 seem to have a role in PGC migration (as an adhesion factor and a chemoattractant, respectively), the former is certainly required for PGC survival in vitro and probably in vivo as well. Recent findings suggest that the mechanism by which SCF supports PGC survival is by preventing PGC apoptosis. A similar action appears to be exerted by leukemia inhibitory factor (LIF), a further growth factor influencing PGC growth in culture.PGC proliferation seems to be mainly induced by cAMP dependent mechanisms, but futther investigations are needed to clarify the interrelationships among the different molecular pathways activated by SCF, LIF, cAMP and other putative PGC growth factors (i.e. bFGF). Stimulation of long-term proliferation of PGCs, leading to derivation of ES-like cells (embryonal germ cells) obtained by using a combination of growth factors (bFGF, SCF and LIF), opens new intriguing perspectives for such studies and transgenic technology.     

Guidance of primordial germ cell migration

Primordial germ cells (PGCs), the progenitors of the gametes, migrate from the position where they are specified towards the region where the gonad develops. To reach their target, the PGCs obtain directional cues from cells positioned along their migration path. One such cue, the chemokine SDF-1, has recently been found to be critical for proper PGC migration in zebrafish and in mice. In Drosophila, too, a molecule that is structurally related to chemokine receptors and is important for PGC migration has been identified. The ability to visualize chemokine-guided migration at a high resolution in vivo in these model organisms provides a unique opportunity to study this process, which is relevant for many events in normal development and disease.     

Genital ridges exert long-range effects on mouse primordial germ cell numbers and direction of migration in culture

The functional gametes of all vertebrates first arise in the early embryo as a migratory population of cells, the primordial germ cells (PGCs). These migrate to, and colonise, the genital ridges (GR) during the early organogenesis period, giving rise to the complete differentiating gonad. PGCs first become visible by alkaline phosphatase staining in the root of the developing allantois at 8.5 days post coitum (dpc). At 9.5 dpc they are found in the wall of the hind-gut and, during the following three days, they migrate along the hind-gut mesentery to the dorsal body wall, and then to the genital ridges. By 12.5 dpc, the great majority of PGCs have colonised the genital ridges. During this period the number of PGCs increases from less than 100 to approximately 4000. In a previous paper (Donovan et al. 1986), we showed that 10.5 dpc PGCs can be explanted from the hind-gut mesentery, and will spread and migrate on feeder cell layers. We showed also that the intrinsic ability of PGCs to spread and migrate changes as they colonise the genital ridges. In this paper, we examine extrinsic factors that control PGC behaviour in vitro. Using PGCs taken from 8.5 dpc embryos, at the beginning of their migratory phase, we show that culture medium conditioned by 10.5 dpc genital ridges causes an increase in the number of PGCs in these cultures. We also show that PGCs migrate towards 10.5 dpc genital ridges in preference to other explanted organs. These experiments show that genital ridges exert long-range effects on the migrating population of PGCs.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hematopoietic development of primordial germ cell-derived mouse embryonic germ cells in culture.

Induction of hematopoiesis in an embryonic germ (EG) cell line derived from mouse primordial germ cells (PGCs) was examined. When single undifferentiated EG-1 cells were inoculated directly into the methylcellulose medium, both primitive and definitive erythropoiesis were seen in embryoid bodies derived from the EG cells as observed in ES cells, and production of myeloid cell lineages was stimulated by IL-3. These results indicate that EG cells acquired in vitro potency to differentiate toward hematopoietic cells, although they were derived from PGC and are distinct from inner cell mass-derived ES cells with regard to gene expression and patterns of DNA methylation corresponding to genomic imprinting. It turns out that they are useful for study of cell differentiation in the animals whose ES cells are not available.     

In vitro culture of mouse primordial germ cells

Germ cells were isolated from mouse fetal gonads 11 1/2-16 1/2 days post coitum (dpc), and exposed to various methods of in vitro culture. From 13 1/2 dpc onwards, both male and female germ cells survived well at 37 degrees C for several days. During the culture period the proportion of female germ cells in meiosis increased and later stages of meiotic prophase were seen. The gonadal environment is therefore not essential for the progress of meiosis. Male germ cells in vitro did not enter meiosis. Germ cells isolated from gonads 11 1/2 or 12 1/2 dpc did not survive at 37 degrees C in any of the three culture systems used (Petri dishes, microtest plate wells, drops under oil); cell density, substrate and culture medium were varied, and several additives tested, but no improvement in viability was detected. Below 30 degrees C, on the other hand, 11 1/2 and 12 1/2 day germ cells survived in vitro for at least a week. They did not enter meiosis in culture, but continued to undergo mitotic proliferation.     

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.     

Autonomous modes of behavior in primordial germ cell migration

Zebrafish primordial germ cells (PGCs) are guided toward their targets by the chemokine SDF-1a. PGCs were followed during three phases of their migration: when migrating as individual cells, while remaining in a clustered configuration, and when moving as a cell cluster within the embryo. We found that individually migrating PGCs alternate between migratory and pausing modes. Pausing intervals are characterized by loss of cell polarity and correlate with subsequent changes in the direction of migration. These properties constitute an intrinsic behavior of PGCs, enabling erasure of prior polarity and re-sampling of the environment. Following migration arrest at a site of high SDF-1a levels, PGCs resume migration as a cluster. The seemingly coordinated cluster migration is a result of single-cell movement in response to local variations in SDF-1a distribution. Together, these behavioral modes allow the cells to arrive at specific destinations with high fidelity and remain at their target site.     

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.     

Migratory and postmigratory mouse primordial germ cells behave differently in culture

In all vertebrate groups, the progenitors of the germ line, the primordial germ cells (PGCs) arise extragonadally and move to the developing gonad early in embryonic development. We have examined the behavior of isolated pregonadal and gonadal PGCs in vitro on feeder layers of an embryo-derived cell line. Histochemically and serologically identified pregonadal germ cells are found to be actively motile in vitro and, furthermore, show behavior characteristic of invasive cells. PGCs isolated from the developing gonad, however, show little locomotory activity and are not invasive on the same cellular substrate. These observations suggest that PGCs undergo a major change in phenotype at the time of their entry into the gonad anlagen.     

Autocrine and paracrine mechanisms regulating primordial germ cell proliferation

Although several mitogens and survival factors have been previously shown to act on primordial germ cells (PGCs) in culture, it is not clear whether they are responsible for controlling proliferation of PGCs in the embryo. We show here that during their migratory phase, PGCs do not express FGF-4, FGF-8, or FGF-17, but these FGFs are expressed by neighboring cells. Thus, any FGF action on migrating PGCs would appear to be through a paracrine mechanism. We found that after entering into the gonads, PGCs start to express FGF-4 and FGF-8. On this basis, we hypothesize that FGF signaling is involved in both a paracrine manner in initiating PGC proliferation during their migration and an autocrine manner in sustaining PGC proliferation after their arrival in the gonads. We then studied the role of soluble stem cell factor (SCF), which acts as a survival factor or a mitogen in culture, to determine whether it interacts with FGFs. We found that SCF has a complex effect on PGC proliferation. On one hand, soluble SCF promoted PGC proliferation synergistically with FGF in the absence of membrane-bound SCF. Conversely, soluble SCF inhibited FGF-stimulated proliferation of PGCs in the presence of membrane-bound SCF. We account for these findings in a model involving regulation of PGC proliferation, in which SCF modulates the response to FGFs.     

The role of cadherins during primordial germ cell migration and early gonad formation in the mouse

Primordial germ cells (PGCs) are the founder cells of the gametes. In mammals, PGCs migrate from the hindgut to the genital ridges, where they coalesce with each other and with somatic cells to form the primary sex cords. We show here that, in both sexes, PGCs express P- and E-cadherins during and after migration, and N-cadherin at post-migratory stages. E-Cadherin is not expressed by PGCs whilst in the hindgut, but is upregulated as they leave. Blocking antibodies against E-, but not P-cadherin cause defective PGC-PGC coalescence, and in some cases, ectopic PGCs.     

Regulation of primordial germ cell development in the mouse

Primordial germ cells (PGCs) are the founders of the gametes. They arise at the earliest stages of embryonic development and migrate to the gonadal ridges, where they differentiate into oogonia/oocytes in the ovary, and prospermatogonia in the testis. The present article is a review of the main studies undertaken by the author with the aim of clarifying the mechanisms underlying the development of primordial germ cells. Methods for the isolation and purification of migratory and post-migratory mouse PGCs devised in the author's laboratory are first briefly reviewed. Such methods, together with the primary culture of PGCs onto suitable cell feeder layers, have allowed the analysis of important aspects of the control of their development, concerning in particular survival, proliferation and migration of mouse PGCs. Compounds and growth factors affecting PGC numbers in culture have been identified. These include survival anti-apoptotic factors (SCF, LIF) and positive regulators of proliferation (cAMP, PACAPs, RA). Evidence has been provided that the motility of migrating PGCs relies on integrated signals from extracellular matrix molecules and the surrounding somatic cells. Moreover, homotypic PGC-PGC interaction has been evidenced that might play a role in PGC migration and in regulating their development. Several molecules (i.e. integrins, specific types of oligosaccharides, E-cadherin, the tyrosine kinase receptor c-kit) have been found to be expressed on the surface of PGCs and to mediate adhesive interactions of PGCs with the extracellular matrix, somatic cells and neighbouring PGCs.     

小鼠原生殖细胞体外培养及其应用研究

原生殖细胞（ｐｒｉｍｏｒｄｉａｌｇｅｒｍｃｅｌｌ,ＰＧＣ）是胚胎生殖谱系最原始形式的细胞,在体胚胎迁移期ＰＧＣ增殖极为旺盛。体外培养的小鼠迁移期ＰＧＣ在饲养层细胞和三种生长因子（干细胞生长因子、碱性成纤维细胞生长因子及白血病抑制因子）的共同作用下,可发展为长期增殖并维持不分化状态的胚胎性干细胞,即胚胎生殖细胞（ｅｍｂｒｙｏｎｉｃｇｅｒｍｃｅｌｌ,ＥＧ）,具全能性发育潜能。ＥＧ建系成功对于研究生殖细胞发育以及寻找新的转基因动物操作的有效载体具有重要价值。     

Analysis of hypomorphic KitlSl mutants suggests different requirements for KITL in proliferation and migration of mouse primordial germ cells

Germ cell development in mice is initiated when a small number of primordial germ cells (PGCs) are set aside from somatic cells during gastrulation. In the subsequent 4 to 5 days, PGCs enter the hindgut, undergo a directed migration away from the hindgut into the developing gonads, and undergo a massive increase in cell number. It is well established that Kit ligand (KITL, also known as stem cell factor and mast cell growth factor) is required for the survival and proliferation of PGCs. However, there is little information on a direct role for KITL in PGC migration. By comparing the effects of multiple Kitl mutations, including two N-ethyl-N-nitrosourea-induced hypomorphic mutations, we were able to distinguish stages of PGC development that are preferentially affected by certain mutations. We provide evidence that the requirements for KITL in proliferation are different in PGCs before and after they start migrating, and different levels of KITL function are required to support PGC proliferation and migration. This study illustrates the usefulness of an allelic series of mutations to dissect developmental processes and suggests that these mutants may be useful for further studies of molecular mechanisms of KITL functions in gametogenesis.     

Interleukin-2 induces the proliferation of mouse primordial germ cells in vitro

Primordial germ cells (PGCs) are the stem cell precursors of the germ line. Several growth factors contribute to enlarging the PGC population by acting as mitogens, survival factors or both. Interleukin-2 (IL-2) has a growth-promoting activity for T and B-lymphocytes, but its role in PGCs had not yet been studied. Here, we show that PGCs isolated from 10.5, 11.5 and 12.5 day postcoitum (dpc) mouse embryos constitutively express the three subunits (alpha, beta and gamma) of the IL-2 receptor (IL-2R). In contrast, IL-2 mRNA was not detected in these cells. However, the addition of recombinant IL-2 to the culture medium increased the number of PGCs in vitro via a mitogenic effect, as indicated by bromodeoxyuridine incorporation assays. Neutralization of the IL-2 receptor using anti-IL-2R subunit antibodies inhibited this IL-2-mediated proliferative effect on PGCs from 11.5 dpc embryos. Together, these data are indicative of a paracrine effect of IL-2 on PGC proliferation. In this regard, we also compared the effect of IL-2 with other compounds such as basic fibroblast growth factor (bFGF), steel factor, leukemia inhibitory factor and forskolin, and found that the degree of proliferation induced by IL-2 was similar to that induced by bFGF and forskolin. These observations support the notion that similar patterns of molecular signaling may underlie the developmental pathways of hematopoietic and germ stem cell precursors.     

Response to fibronectin of mouse primordial germ cells before, during and after migration.

The adhesive extracellular matrix glycoprotein fibronectin is thought to play a central role in cell migration during embryogenesis. In order to define this role, we have examined the response to fibronectin in cell culture of mouse primordial germ cells (PGCs) before, during and after their migration from the hindgut into their target tissue, the genital ridges. Using an explant culture system, we show that PGCs will emigrate from tissue fragments containing hindgut, and that fibronectin stimulates this migration. Adhesion assays show that the start of PGC migration is associated with a fall in adhesion to fibronectin. Double-labelling studies using in situ hybridization and histochemistry demonstrate that migrating PGCs do not contain detectable fibronectin mRNA, suggesting that they do not synthesize and secrete the fibronectin within their migratory substratum. Taken together, these findings are consistent with an important role for fibronectin in stimulating PGC migration. In addition, however, they suggest that the interaction between PGCs and fibronectin may be important in timing the start of migration, with the fall in adhesion allowing the PGCs to commence their migration towards the genital ridges.     

A role for E-cadherin in mouse primordial germ cell development

In this study we show that mouse primordial germ cells and fetal germ cells at certain stages of differentiation express E-cadherin and alpha and beta catenins. Moreover, we demonstrate that the formation of germ cell aggregates that rapidly occurs when monodispersed germ cell populations are released from embryonic gonads in culture is E-cadherin mediated, developmentally regulated, and dependent on the sex of the germ cells. Immunoblotting analyses indicate that the lower ability to form aggregates of primordial germ cells in comparison to fetal germ cells is not due to gross changes in E-cadherin expression, altered association with beta catenin, or changes in beta catenin phosphorylation. Investigating possible functions of E-cadherin-mediated adhesion in primordial germ cell development, we found that E-cadherin-mediated adhesion may stimulate the motility of primordial germ cells. Moreover, treatment of primordial germ cells cultured on STO cell monolayers with an anti-E-cadherin antibody caused a significant decrease in their number and markedly reduced their ability to form colonies in vitro. The same in vitro treatment of explanted undifferentiated gonadal ridges cultured for 4 days results in decreased numbers and altered localization of the germ cell inside the gonads. Taken together these results suggest that E-cadherin plays an important role in primordial germ cell migration and homing and may act as a modulator of primordial germ cell development.     

Collagen and tenascin-C expression along the migration pathway of mouse primordial germ cells

Primordial germ cells (PGCs) are the progenitor cells of the vertebrate germ line. These cells originate outside of the embryo and, through separation, migration, and colonization, arrive at the genital ridge, contributing to gonad development. Diverse extracellular matrix molecules are present along the PGC migratory pathway, permitting or inhibiting PGC displacement. Collagens and tenascin form the substratum for in vitro migration of neural crest cells and PGCs. However, little is known about the expression and distribution of these molecules during in situ PGC migration. Using immunohistochemistry, we identified tenascin-C and types I, III, and V collagen along the mouse PGC migration pathway. These molecules were spatiotemporally expressed in basement membranes of hindgut, coelomic epithelia, and mesonephric tubules and mesenchyme throughout the study. Our results complement previous data from our laboratory and contribute to building comprehension of the composition of the mouse PGC migratory pathway extracellular matrix, thereby enhancing understanding of the process.     

Guidance of primordial germ cell migration by the chemokine SDF-1

The signals directing primordial germ cell (PGC) migration in vertebrates are largely unknown. We demonstrate that sdf-1 mRNA is expressed in locations where PGCs are found and toward which they migrate in wild-type as well as in mutant embryos in which PGC migration is abnormal. Knocking down SDF-1 or its receptor CXCR4 results in severe defects in PGC migration. Specifically, PGCs that do not receive the SDF-1 signal exhibit lack of directional movement toward their target and arrive at ectopic positions within the embryo. Finally, we show that the PGCs can be attracted toward an ectopic source of the chemokine, strongly suggesting that this molecule provides a key directional cue for the PGCs.