No inhibition of IL-27 signaling by soluble gp130

Soluble gp130 is the natural inhibitor of trans-signaling mediated by the soluble IL-6/IL-6R complex. In mouse models, recombinant sgp130 has been successfully applied for the treatment of diseases that are triggered and maintained by soluble IL-6R like Crohn's disease, peritonitis, rheumatoid arthritis, and colon cancer. The novel heterodimeric cytokine IL-27 (p28/EBV-induced gene 3) has been shown to act via a heterodimeric receptor complex of gp130 and the WSX-1 receptor, and to co-regulate the Th(1) immune response after infection. Therefore, we have tested the potential of the recombinant sgp130-Fc protein to also inhibit signaling-mediated IL-27. Here we show that sgp130-Fc does not interfere with IL-27 signaling. We therefore conclude that IL-27 does not bind with high affinity to gp130.     

Autonomous regulation of sex-specific developmental programming in mouse fetal germ cells

In mice, unique events regulating epigenetic programming (e.g., genomic imprinting) and replication state (mitosis versus meiosis) occur during fetal germ cell development. To determine whether these processes are autonomously programmed in fetal germ cells or are dependent upon ongoing instructive interactions with surrounding gonadal somatic cells, we isolated male and female germ cells at 13.5 days postcoitum (dpc) and maintained them in culture for 6 days, either alone or in the presence of feeder cells or gonadal somatic cells. We examined allele-specific DNA methylation in the imprinted H19 and Snrpn genes, and we also determined whether these cells remained mitotic or entered meiosis. Our results show that isolated male germ cells are able to establish a characteristic "paternal" methylation pattern at imprinted genes in the absence of any support from somatic cells. On the other hand, cultured female germ cells maintain a hypomethylated status at these loci, characteristic of the normal "maternal" methylation pattern in endogenous female germ cells before birth. Further, the surviving female germ cells entered first meiotic prophase and reached the pachytene stage, whereas male germ cells entered mitotic arrest. These results indicate that mechanisms controlling both epigenetic programming and replication state are autonomously regulated in fetal germ cells that have been exposed to the genital ridge prior to 13.5 dpc.     

Retinoic acid derived from the fetal ovary initiates meiosis in mouse germ cells

Meiotic initiation of germ cells at 13.5 dpc (days post‐coitus) indicates female sex determination in mice. Recent studies reveal that mesonephroi‐derived retinoic acid (RA) is the key signal for induction of meiosis. However, whether the mesonephroi is dispensable for meiosis is unclear and the role of the ovary in this meiotic process remains to be clarified. This study provides data that RA derived from fetal ovaries is sufficient to induce germ cell meiosis in a fetal ovary culture system. When fetal ovaries were collected from 11.5 to 13.5 dpc fetuses, isolated and cultured in vitro, germ cells enter meiosis in the absence of mesonephroi. To exclude RA sourcing from mesonephroi, 11.5 dpc urogenital ridges (UGRs; mesonephroi and ovary complexes) were treated with diethylaminobenzaldehyde (DEAB) to block retinaldehyde dehydrogenase (RALDH) activity in the mesonephros and the ovary. Meiosis occurred when DEAB was withdrawn and the mesonephros was removed 2 days later. Furthermore, RALDH1, rather than RALDH2, serves as the major RA synthetase in UGRs from 12.5 to 15.5 dpc. DEAB treatment to the ovary alone was able to block germ cell meiotic entry. We also found that exogenously supplied RA dose‐dependently reduced germ cell numbers in ovaries by accelerating the entry into meiosis. These results suggest that ovary‐derived RA is responsible for meiosis initiation. J. Cell. Physiol. 228: 627–639, 2013. © 2012 Wiley Periodicals, Inc.     

Induction of meiosis in fetal mouse testis in vitro

Fetal mouse testes and ovaries with their urogenital connections were cultured singly or in pairs on Nuclepore filters. When a testis in which the sex was not yet morphologically detectable was cultured together with older ovaries containing germ cells which were progressing through the meiotic prophase, the male germ cells were triggered to enter meiosis. When older fetal testes in which the testicular cords have developed were cultured together with ovaries of the same age with germ cells in meiosis, the oocytes were prevented from reaching diplotene stage. It was concluded that the fetal male and female gonads secrete diffusable substances which influence germ cell differentiation. The male gonad secretes a "meiosis-preventing substance" (MPS) which can arrest the female germ cells within the meiotic prophase. The female gonad secretes a "meiosis-inducing substance" (MIS) which can trigger the nondifferentiated male germ cells to enter meiosis.     

Forskolin and the meiosis inducing substance synergistically initiate meiosis in fetal male germ cells

We have shown that Meiosis Inducing Substance (MIS) and forskolin synergistically and dose dependently induce meiosis in germ cells of cultured fetal mouse testes. We used a bioassay which consists of fetal mouse testes and ovaries cultured for 6 days. In this study MIS media are spent culture media from 24 hour cultures of minced adult mouse testes. In the bioassay one gonad of each fetus is cultured either in MIS medium, in control medium with forskolin, or in MIS medium with forskolin. The other gonad serves as the control and is cultured in control medium. After culture the gonads are fixed, squashed, and DNA-stained. In these preparations germ cells and somatic cells can be distinguished, and the number of germ cells in the different stages of meiosis is counted as is the number of somatic cells in mitosis. MIS activity is defined to be present in a medium when meiosis is induced in male germ cells during culture. We found that MIS media as well as forskolin induced meiosis in fetal male germ cells in a dose-dependent manner. In addition, MIS media and forskolin acted synergistically by inducing meiosis. Female germ cells seem to be unaffected by the various culture media. These findings indicate that receptors for stimuli of meiotic initiation may exist in germ cells or neighbouring somatic cells. In addition to induction of meiosis, MIS media and forskolin also dose dependently increase the number of male germ cells compared to controls. This increase is correlated with induction of advanced stages of meiosis: Male germ cells seem to survive better if they are triggered to enter meiosis. Neither MIS media nor forskolin affected the growth of somatic cells. We therefore propose that MIS media has a growth factor activity with a specific effect on meiotic initiation. © 1993 Wiley-Liss, Inc.     

Precocious initiation of meiosis by male germ cells of the mouse

12 1/2-15 1/2 day embryonic mouse testes of 129/terSv and CBA/T6T6 strains were transplanted under the kidney capsule of adult hosts. After 3-5 days in 41% of CBA/T6T6 transplants and in 82% of 129/terSv transplants a limit number of germ cells began meiosis. The percentage of meiotic germ cells was inversely related to the total number of gonocytes and the organization of seminiferous cords. The presented evidence indicates that the ability of the germ cells to begin meiosis precociously depends on: 1) genotype of donor embryos; 2) age of transplanted testis, and 3) using whole of half of gonad for transplantation. After 10-15 days in two out of 46 129/terSv testes (4%) growing oocytes were observed.     

Nuclear transplantation of mouse fetal germ cells into enucleated two-cell embryos

Mouse fetal germ cells were fused with enucleated blastomeres of two-cell embryos. Donor germ cells were obtained from fetuses of albino CD-1 strain or pigmented F(1) (C57BL x CBA) female mice mated with the same strain males at 11.5 to 16.5 days post coitum. Recipient two-cell embryos, which were of a different strain from the donors, were obtained at 37 to 42 hours (Group 1), 42 to 47 hours (Group 2), and 47 to 52 hours (Group 3) after treatment with human chorionic gonadotropin (hCG). After removing the nucleus from one two-cell blastomere, a single germ cell was fused with the enucleated blastomere using the Sendai virus; the second blastomere was left intact. The reconstituted embryos were cultured for 3 days in vitro, to examine their developmental capacity. The fused blastomeres in Groups 1 and 2 did not divide, but a few transplanted blastomeres in Group 3 divided several times, and some of them developed into normal blastocysts. Most embryos developed into blastocysts from one blastomere, with an undivided blastomere remaining. Embryos developing into normal blastocysts or blastocysts with small blastomeres were transferred to the oviducts of Day-1 or the uteri of Day-3 pregnant albino CD-1 mice. None of the young showed any contribution of the germ cells, judging by the eye and coat colors and by the germ cells in the germ line following mating with albino mice. Possible reasons for failure of pluripotency of the germ cells are discussed here.     

Premeiotic fetal murine germ cells cultured in vitro form typical oocyte-like cells but do not progress through meiosis

A convenient method for fetal murine premeiotic germ cells to develop into oocytes in vitro has been established. Fetal ovaries from mice, collected 12.5 d postcoitus (dpc), were organ-cultured in vitro using a medium for organ growth, and the developmental potential regarding oocyte formation was determined. After 28 d of culture, premeiotic female germ cells developed into oocytes with a mean (±SD) diameter of 73.3 ± 7.7 μm. However, follicles developed in vitro versus in vivo had fewer granulosa cells (32 ± 2.6 vs. 142 ± 9.5, respectively; P < 0.01), and the ovaries had less mRNA for Cx37 and Cx43 (P < 0.01). Oocytes in the first meiotic division phase were isolated from cultured ovaries or after hormone treatments. After exposure to okadaic acid at a final concentration of 1 μM, oocytes derived from premeiotic fetal female germ cells were able to undergo germinal vesicle breakdown but failed to complete the first meiotic division. Furthermore, the intracellular content of GSH in oocytes cultured in vitro was lower than that of oocytes matured in vivo (P < 0.01). In conclusion, premeiotic germ cells derived from murine fetuses as early as 12.5 dpc were able to differentiate into germinal vesicle-stage oocytes but were unable to complete meiosis I in vitro.     

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.     

Notch pathway regulates female germ cell meiosis progression and early oogenesis events in fetal mouse

A critical process of early oogenesis is the entry of mitotic oogonia into meiosis, a cell cycle switch regulated by a complex gene regulatory network. Although Notch pathway is involved in numerous important aspects of oogenesis in invertebrate species, whether it plays roles in early oogenesis events in mammals is unknown. Therefore, the rationale of the present study was to investigate the roles of Notch signaling in crucial processes of early oogenesis, such as meiosis entry and early oocyte growth. Notch receptors and ligands were localized in mouse embryonic female gonads and 2 Notch inhibitors, namely DAPT and L-685,458, were used to attenuate its signaling in an in vitro culture system of ovarian tissues from 12.5 days post coitum (dpc) fetus. The results demonstrated that the expression of Stra8, a master gene for germ cell meiosis, and its stimulation by retinoic acid (RA) were reduced after suppression of Notch signaling, and the other meiotic genes, Dazl, Dmc1, and Rec8, were abolished or markedly decreased. Furthermore, RNAi of Notch1 also markedly inhibited the expression of Stra8 and SCP3 in cultured female germ cells. The increased methylation status of CpG islands within the Stra8 promoter of the oocytes was observed in the presence of DAPT, indicating that Notch signaling is probably necessary for maintaining the epigenetic state of this gene in a way suitable for RA stimulation. Furthermore, in the presence of Notch inhibitors, progression of oocytes through meiosis I was markedly delayed. At later culture periods, the rate of oocyte growth was decreased, which impaired subsequent primordial follicle assembly in cultured ovarian tissues. Taken together, these results suggested new roles of the Notch signaling pathway in female germ cell meiosis progression and early oogenesis events in mammals.     

Regulation of the female mouse germ cell cycle during entry into meiosis

During mouse embryonic development germ cells proliferate extensively until they commit to the male or female pathway and arrest in mitosis or meiosis respectively. Whilst the transition of female germ cells exiting the mitotic cell cycle and entering meiosis is well defined histologically, the essential cell cycle proteins involved in this process have remained unresolved. Using flow cytometry we have examined the entry of female germ cells into meiosis, their termination of DNA synthesis and entry into prophase I. Analysis of key G₂/M cell cycle proteins revealed that entry into meiosis and cell cycle exit at G₂/M involves repression of G₂/M promoting Cyclin B1, coincident upregulation of G₂/M repressing Cyclin B3 and robust establishment of the ATM/CHK2 pathway. By contrast we show that the ATR/CHK1 pathway is activated in male and female germ cells. This data indicates that an important G₂/M surveillance mechanism operates during germ cell proliferation and that passage into meiotic G₂/M involves the combined repression of G₂/M through Cyclin B3 and activation of the key G₂/M checkpoint regulatory network modulated through ATM and CHK2. This work shows that the core regulatory machinery that controls G₂/M progression in mitotic cells is activated in female mouse germ cells as they enter meiosis.     

Culture of mouse germ cells isolated from fetal gonads

Mouse germ cells isolated from male or female genital ridges at 121/2 days post coitum were cultured at room temperature for up to 6 days, with [3H]thymidine present in the culture medium for either the first 24 h or the last 24 h of each culture period. Germ cells were also isolated 131/2-161/2 days post coitum and cultured for 24 h in the presence of [3H]thymidine. The proportion of cells in metaphase, and the proportion of labelled interphase and metaphase nuclei, was recorded. The labelling index declined from 131/2 days onwards, after development either in vivo or in vitro. No labelled metaphase plates were seen after 24 h in the presence of [3H]thymidine, suggesting that under these culture conditions the duration of the G2 phase exceeded 24 h. The results showed that the culture system, in spite of the low temperature, allowed the germ cells to replicate their DNA and undergo mitosis for up to 6 days. Addition of db-cAMP to the culture medium proved highly toxic to male germ cells, and did not markedly increase the proliferation rate of female germ cells.     

Transactivation of gp130 in myeloma cells

Receptor transactivation, i.e., interaction between unrelated receptor systems, is a growing theme in cytokine and growth factor signaling. In this study we reveal for the first time the ability of IFN-alpha to transactivate gp130 in myeloma cells. An epidermal growth factor receptor/gp130 chimeric receptor previously shown by us to transactivate endogenous gp130, provided a complementary tool to study the underlying mechanisms of receptor cross-talk. Further analysis revealed that transactivation of gp130 by IFN-alpha did not require the extracellular or trans-membrane domain of gp130. Moreover, transactivation of gp130 was critically dependent upon Janus kinase activation by the initiating receptor and correlated with rapid and sustained Janus kinase 1 and tyrosine kinase (Tyk) 2 tyrosine phosphorylation. Finally, transactivation of gp130 may be a common theme in myeloma cells, perhaps providing a mechanism for enhanced or qualitatively distinct cellular responses to specific stimuli.     

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.     

Live offspring produced by mouse oocytes derived from premeiotic fetal germ cells

Mature mouse oocytes currently can be generated in vitro from the primary oocytes of primordial follicles but not from premeiotic fetal germ cells. In this study we established a simple, efficient method that can be used to obtain mature oocytes from the premeiotic germ cells of a fetal mouse 12.5 days postcoitum (dpc). Mouse 12.5-dpc fetal ovaries were transplanted under the kidney capsule of recipient mice to initiate oocyte growth from the premeiotic germ cell stage, and they were recovered after 14 days. Subsequently, the primary and early secondary follicles generated in the ovarian grafts were isolated and cultured for 16 days in vitro. The mature oocytes ovulated from these follicles were able to fertilize in vitro to produce live offspring. We further show that the in vitro fertilization offspring were normal and able to successfully mate with both females and males, and the patterns of the methylated sites of the in vitro mature oocytes were similar to those of normal mice. This is the first report describing premeiotic fetal germ cells able to enter a second meiosis and support embryonic development to term by a combination of in vivo transplantation and in vitro culture. In addition, we have shown that the whole process of oogenesis, from premeiotic germ cells to germinal vesicle (GV)-stage oocytes, can be carried out under the kidney capsule.     

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.