Origin of primordial germ cells in the prestreak chick embryo

The temporal and spatial pattern of segregation of the avian germline from the formation of the area pellucida to the beginning of primitive streak formation (stages VII–XIV, EG&K) was investigated using the culture of whole embryos and central and peripheral embryo fragments on vilelline membranes at stages VII–IX, immunohistological analysis of whole mount embryos and sections with monoclonal antibodies MC-480 against stage-specific embryonic antigen-1 (SSEA-1) and EMA-1, and with the culture of dispersed blastoderms at stages IX–XIV with and without an STO feeder layer. Whole embryos at intrauterine stages developed up to the formation of the primitive streak despite the absence of area pellucida expansion. Primordial germ cells (PGCs) appeared in the cultures of whole embryos and only in central fragments containing a partially formed area pellucida at stages VII–IX. When individual stage IX–XIV embryos were dispersed and cultured without a feeder layer, 25–45 PGCs/embryo were detected only with stage X–XIV, but not with stage IX blastoderms. However, the culture of dispersed cells from the area pellucida of stages IX–XIII on STO feeder layers yielded about 150 PGCs/embryo. The carbohydrate epitopes recognized by anti-SSEA-1 and EMA-1 first appeared at stage X on cells in association with polyingressing cells on the ventral surface of the epiblast and later on the dorsal surface of the hypoblast. The SSEA-1-positive hypoblast cells gave rise to chicken PGCs when cultured on a feeder layer of quail blastodermal cells. From these observations, we propose that the segregation and development of avian germline is a gradual, epigenetic process associated with the translocation of SSEA-1/EMA-1-positive cells from the ventral surface of the area pellucida at stage X to the dorsal side of the hypoblast at stages XI–XIV. © 1996 Wiley-Liss, Inc.     

Primordial germ cells of the young chick blastoderm originate from the central zone of the area pellucida irrespective of the embryo-forming process

Early chick blastoderms (stages X-XII) were divided by a circular cut into two fragments. In one experimental group, the area opaca was separated from the marginal zone and the central disc of the area pellucida, while in another group the area opaca plus marginal zone were separated from the central disc. Other blastoderms of equivalent stages were each cut into three strips of equal size (either perpendicular or parallel to the axis of symmetry). The fragments were isolated and incubated for 43-48 h after which they were PAS-stained, whole-mounted and checked for the presence of primordial germ cells (PGCs). The results showed that most of the PGCs originated from the central disc and not from the periphery of the area pellucida and that they segregated from this zone even if no embryonic axis developed in the explant. In such cases, the PGCs were found to be dispersed throughout the entire explant, usually in association with forming blood islands. When an axis did develop in the explant, the PGCs were found to be concentrated around its anterior end, in a pattern resembling the germinal crescent. No indication of a quantitative regulation of PGCs was found in the explants and the sum of PGCs, calculated for the complementary fragments of a blastoderm, matched the range of numbers in control blastoderms. Our results suggest that PGCs may already be determined as early as stage X and that their further differentiation is independent of the embryo-forming process.     

鸡原始生殖细胞转染条件优化

为获得鸡原始生殖细胞(primordial germ cells,PGCs)的最佳转染效率,本研究比较不同质粒用量和不同细胞数在3种转染试剂(Lipofectamine 2000、3000和LTX&Plus Reagent)中PGCs的转染效率,利用荧光激活细胞分选技术(fluorescence activated cell sorting technology,FACS)辅助优化Lipofectamine 3000转染试剂,经FACS进一步分选获得带绿色荧光蛋白(GFP)的PGCs,继续培养3周后,移植回注到受体鸡胚中,移植3.5 d后分离性腺拍照观察。结果显示,转染试剂Lipofectamine 3000的转染效率最高,质粒、Lipofectamine 3000转染试剂和PGCs细胞数的配比为3μg:4μL:0.5×10⁴个,转染5h转染效率最高,达到23.4%,与现有的研究结果相比提高了2倍以上。移植回注PGCs到受体鸡胚中,荧光显微镜观察到鸡胚性腺中有GFP阳性细胞。本研究综合考虑转染试剂、质粒用量和细胞数量的影响因素以优化PGCs的转染条件,为高...     

Derivation in culture of primordial germ cells from cells of the mouse epiblast: phenotypic induction and growth control by Bmp4 signalling

Primordial germ cells (PGCs) are the embryonic precursors of the gametes of the adult. PGCs derive from cells of the most proximal part of the cup-shaped epiblast corresponding to the presumptive region of the extraembryonic mesoderm. At 7.2 days post coitum (dpc) a small group of PGCs located at the base of the allantois can be recognised due to a strong alkaline phosphatase activity. Thus far, scant information was available on the mechanism(s) controlling the lineage of PGCs in the mouse embryo. However, results obtained in mice defective for bone morphogenetic protein-4 (Bmp4) secreted molecule revealed that this growth factor has important functions for the derivation of PGCs from extraembryonic mesoderm cells. In this paper, we have studied the effects in culture of Bmp4 on epiblast cells obtained from egg-cylinder stage mouse embryos (5.5-6.0 dpc) and PGCs from 11.5 dpc embryos. We found that Bmp4 treatment enables recruitment of pluripotent cells to a PGC phenotype by a multi-step process involving an initial pre-commitment of epiblast cells and a following stage of PGC phenotypic determination. We further provide evidences that Bmp4 may promote the growth of gonadal PGCs through a Smad1/4 signalling.     

Restriction of proliferation of primordial germ cells by the irradiation of Japanese quail embryos with soft X-rays.

Primordial germ cells (PGCs) are the progenitor cells for the gametes. Avian PGCs are located in the central region of the area pellucida at the blastoderm stage. Shortly after further incubation, they migrate to the extra-embryonic germinal crescent, and then as soon as the blood vessels form, they enter the circulation and finally settle in the gonadal primordium. We have developed a simple method using soft X-ray irradiation (18 kV power, 20 cm distance) to reduce the number of PGCs in Japanese quail embryos, which should be useful in preparing recipient embryos for PGC-transfer studies. When embryos were exposed to the soft X-rays for 40 s before incubation, the concentration of circulating PGCs was less than one-fifth that in controls after 2 days of incubation. Embryos at day 6 of incubation contained approximately half the number of PGCs compared to controls when they were exposed before or at day 2 of incubation. Irradiation for 40 s is recommended taking into consideration the restriction of proliferation of PGCs, and viability and hatchability.     

Effects of protease inhibitors and antioxidants on In vitro survival of porcine primordial germ cells

One of the problems associated with in vitro culture of primordial germ cells (PGCs) is the large loss of cells during the initial period of culture. This study characterized the initial loss and determined the effectiveness of two classes of apoptosis inhibitors, protease inhibitors, and antioxidants on the ability of porcine PGCs to survive in culture. Results from electron microscopic analysis and in situ DNA fragmentation assay indicated that porcine PGCs rapidly undergo apoptosis when placed in culture. Additionally, alpha(2)-macroglobulin, a protease inhibitor and cytokine carrier, and N:-acetylcysteine, an antioxidant, increased the survival of PGCs in vitro. While other protease inhibitors tested did not affect survival of PGCs, all antioxidants tested improved survival of PGCs (P: < 0.05). Further results indicated that the beneficial effect of the antioxidants was critical only during the initial period of culture. Finally, it was determined that in short-term culture, in the absence of feeder layers, antioxidants could partially replace the effect(s) of growth factors and reduce apoptosis. Collectively, these results indicate that the addition of alpha(2)-macroglobulin and antioxidants can increase the number of PGCs in vitro by suppressing apoptosis.     

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.     

The developmental origin of primordial germ cells and the transmission of the donor-derived gametes in mixed-sex germline chimeras to the offspring in the chicken

A novel system has been developed to determine the origin and development of primordial germ cells (PGCs) in avian embryos directly. Approximately 700 cells were removed from the center of the area pellucida, the outer of the area pellucida, and the area opaca of the stage X blastoderm (Eyal-Giladi and Kochav, 1976; Dev Biol 49:321–337). When the cells were removed from the center of the area pellucida, the mean number of circulating PGCs per 1 μl of blood was significantly decreased to 13 (P < 0.05) in the embryo at stage 15 (Hamburger and Hamilton, 1951: J Morphol 88:49–92) as compared to intact embryos of 51. When the removed recipient cells from the center of the area pellucida were replenished with 500 donor cells, no reduction in the PGC number was observed. The removal of cells from the outer of area pellucida or from the area opaca had no effect on the number of PGCs. When another set of the manipulated embryos were cultured ex vivo to hatching and reared to sexual maturity, the absence of germ cells and the degeneration of seminiferous tubules were observed in resulting chickens derived from the blastoderm from which the cells were removed from the center of the area pellucida. Chimeric embryos produced by the male donor cells and the female recipient contained the female-derived cells at 97.2% in the whole embryo and 94.3% in the erythrocytes at 5 days of incubation. At 5–7 days of incubation, masculinization was observed in about one half of the mixed-sex embryos. The proportions of the female-derived cells in the whole embryo and in the erythrocytes were 76.5% and 80.2% at 7 days to 55.7% and 62.5% at 10 days of incubation, respectively. When the chimeras reached their sexual maturity, they were test mated to assess donor contribution to their germline. Five of six male chimeras (83%) and three of five female chimeras (60%) from male donor cells and a female recipient embryo from which 700 cells at the center of area pellucida were removed were germline chimeras. Three of the five male germline chimeras (60%) and one of the three female germline chimeras (33%) transmitted exclusively (100%) donor-derived gametes into the offspring. When embryonic cells were removed from the outer of area pellucida or area opaca, regardless of the sex combination of the donor and the recipient, the transmission of the donor-derived gametes was essentially null. The findings in the present studies demonstrated, both in vivo and in vitro, that the PGCs originate in the central part of the area pellucida and that the developmental fate to germ cell (PGCs) had been destined at stage X blastoderm in chickens. Mol. Reprod. Dev. 48:501–510, 1997. © 1997 Wiley-Liss, Inc.     

Wingless signaling initiates mitosis of primordial germ cells during development in Drosophila

The germline cells of Drosophila are derived from pole cells, which form at the posterior pole of the blastoderm and become primordial germ cells (PGCs). To elucidate the signal transduction pathways for the development of embryonic PGCs, we examined the effects of various growth factors on the proliferation of PGCs. Up- and down-regulation of Wingless (Wg) in both of soma and PGCs caused an increase and a decrease in the number of PGCs, respectively. The Wg/β-catenin signaling pathway began to occur in PGCs at the same time as the PGCs began to divide during the embryonic stage in both sexes. In addition, PGCs were found to produce wg mRNA as they begin to divide. Thus, Wg functions as an autocrine factor to initiate mitosis in embryonic PGCs. Decapentaplegic affected the growth of PGCs from the end of the embryonic stage. The results indicate that these growth factors regulate the division of embryonic PGCs in a stage-specific manner.     

Mutations affecting early distribution of primordial germ cells in Medaka (Oryzias latipes) embryo

The development of germ cells has been intensively studied in Medaka (Oryzias latipes). We have undertaken a large-scale screen to identify mutations affecting the development of primordial germ cells (PGCs) in Medaka. Embryos derived from mutagenized founder fish were screened for an abnormal distribution or number of PGCs at embryonic stage 27 by RNA in situ hybridization for the Medaka vasa homologue (olvas). At this stage, PGCs coalesce into two bilateral vasa-expressing foci in the ventrolateral regions of the trunk after their migration and group organization. Nineteen mutations were identified from a screen corresponding to 450 mutagenized haploid genomes. Eleven of the mutations caused altered PGC distribution. Most of these alterations were associated with morphological abnormalities and could be grouped into four phenotypic classes: Class 1, PGCs dispersed into bilateral lines; Class 2, PGCs dispersed in a region more medial than that in Class 1; Class 3, PGCs scattered laterally and over the yolk sac area; and Class 4, PGCs clustered in a single median focus. Eight mutations caused a decrease in the number of PGCs. This decrease was observed in the offspring of heterozygous mothers, indicating the contribution of a maternal factor in determining PGC abundance. Taken together, these mutations should prove useful in identifying molecular mechanisms underlying the early PGC development and migration.     

Presumptive Primordial Germ Cells (pPGCs) and PGCs in Tadpoles from UV-irradiated embryos of Xenopus

In order to determine whether or not tadpoles that once lacked primordial germ cells (PGCs) in the genital ridges and dorsal mesentery as a result of ultraviolet (UV) irradiation subsequently contained germ cells at more advanced stages of larval development, the numbers of presumptive PGCs or PGCs were carefully examined in Xenopus tadpoles at Nieuwkoop and Faber's stage 35/36–52 that developed normally from UV-irradiated eggs.
No late-appearing germ cells were observed in almost all the UV-irradiated tadpoles examined at stages 49–52. This same population had completely lacked PGCs at about stage 46. Moreover, presumptive PGCs (pPGCs) or cells with granular cytoplasm that reacted with a monoclonal antibody specific for the germ plasm of cleaving Xenopus eggs stayed in the central part of the endoderm cell mass in the irradiated tadpoles at stage 35/36, when the majority of those cells were located in the dorsal part of the endoderm in unirradiated controls. Furthermore, in the irradiated embryos pPGCs were demonstrated to decrease in number with development and eventually to disappear in tadpoles at about stage 40. The results strongly suggest that UV irradiation under the conditions used here totally eliminated germline cells from the irradiated animals.     

Autonomous Regulation of Proliferation and Growth Arrest in Mouse Primordial Germ Cells Studied by Mixed and Clonal Cultures

In culture, mouse primordial germ cells (PGCs) proliferate and undergo growth arrest with a time course similar to thatin vivo.It is unclear whether this behavior is regulated autonomously or by coexisting somatic cells. We performed mixed culture experiments using PGCs from 8.5- and 11.5-d.p.c. embryos and found no interaction between the PGCs and somatic cells at the two stages. Next, we carried out clonal culture of PGCs and examined the proliferation of and morphological change in individual clones. Such clonal culture did not reveal any subpopulation of PGCs with an increased growth rate or less differentiated characteristics, which might have been suggested by formation of the embryonic germ cell lines. Our results suggest that there is an autonomous regulation of growth and cell shape change in PGCs which occur as stochastical events but are not strictly timed by the number of cell divisions.     

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)     

不同时期鸡胚原始生殖细胞分离的研究

采用Ficoll密度梯度离心,酶解离两种方法在鸡胚孵化的第14期、19期、28期,分离、培养鸡胚中的原始生殖细胞(PGCs)。探索PGCs分离、培养的适宜时期及方法,以期获得较多数量,较高活力的PGCs作介导生产转基因鸡。结果表明：1．提取、分离PGCs的最佳时期依次为19期、28期。2．两种分离方法均能分离到一定数量的PGCs细胞。但在19期和28期,酶解离法分离到的PGCs的相对数量较多,存活时间较长,是一种较适宜的分离方法。     

A novel method to isolate primordial germ cells and its use for the generation of germline chimeras in chicken

A novel method was developed to isolate chick primordial germ cells (PGCs) from circulating embryonic blood. This is a very simple and rapid method for the isolation of circulating PGCs (cPGCs) using an ammonium chloride-potassium (ACK) buffer for lysis of the red blood cells. The PGCs were purified as in vitro culture proceeded. Most of the initial red blood cells were removed in the first step using the ACK lysis buffer. The purity of the cPGCs after ACK treatment was 57.1%, and the recovery rate of cPGCs from whole blood was 90.3%. The ACK process removed only red blood cells and it did not affect cPGC morphology. In the second step, the red blood cells disappeared as the culture progressed. At 7 days of in vitro culture, the purity of the PGCs was 92.9%. Most of these cells expressed germline-specific antibodies, such as those against chicken vasa homolog (CVH). The cultured PGCs expressed the Cvh and Dazl genes. Chimeric chickens were produced from these cultured PGCs, and the donor cells were detected in the gonads, suggesting that the PGCs had biological function. In conclusion, this novel isolation system for PGCs should be easier to use than previous methods. The results of the present study suggest that this novel method will become a powerful tool for germline manipulation in the chicken.     

影响鸡原始生殖细胞分离克隆因素的研究（简报）

具有多向分化潜能的胚胎干细胞有两种来源：一是来自于早期胚胎内细胞团的胚胎干细胞(Em．bryonic Stem Cells,ESCs),另一种是来自于胚胎生殖腺原始生殖细胞(Primordial Germ Cells,PGCs)的胚胎生殖细胞(Embryonic Germ Cells,EGCs)。     

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.     

PRODUCTION OF GERMLINE CHIMERIC CHICKENS BY TRANSFER OF CULTURED PRIMORDIAL GERM CELLS

Primordial germ cells (PGCs) from stage 27 (5.5-day-old) Korean native ogol chicken embryonic germinal ridges were cultured in vitro for 5 days. As in in vivo culture, these cultured PGCs were expected to have already passed beyond the migration stage. Approximately 200 of these PGCs were transferred into 2.5-day-old white leghorn embryonic blood stream, and then the recipient embryos were incubated until hatching. The rate of hatching was 58.8% in the manipulated eggs. Six out of 60 recipients were identified as germline chimeric chickens by their feather colour. The frequency of germline transmission of donor PGCs was 1.3–3.1% regardless of sex. The stage 27 PGCs will be very useful for collecting large numbers of PGCs, handling of exogenous DNA transfection during culture, and for the production of desired transgenic chickens.