Autonomous transition into meiosis of mouse fetal germ cells in vitro and its inhibition by gp130-mediated signaling

Mouse primordial germ cells (PGCs) arrive at the urogenital ridge (UGR) at around 10.5 days postcoitum (dpc). They proliferate until around 13.5 dpc, then enter into meiosis in the female or become mitotically arrested in the male gonads. In this study, meiotic transition of mouse PGCs was examined in vitro. Female PGCs obtained from UGRs or genital ridges at 10.5-11.5 dpc began to express meiosis-specific genes, Scp3 and Dmc1, after dissociation and cultivation on feeder cells for several days. Meiotic transition into the leptotene stage was confirmed by the formation of axial cores. Male PGCs at 10.5-11.5 dpc and migratory PGCs obtained from mesenteries at 10.5 dpc also expressed Scp3 and formed axial cores after several days of culture, supporting the hypothesis that PGCs are capable of entering meiosis before arriving at the UGR. gp130-mediated signaling, known to promote survival/growth of PGCs and also to inhibit the differentiation of embryonic stem cells, suppressed the expression of Scp3 in PGCs and inhibited the following formation of axial cores in vitro. This novel activity of gp130-mediated signaling may provide some clues for the understanding of pluripotency of mammalian germ-line cells and/or the sex differentiation of fetal germ cells.     

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.     

Comparison of strains and culture media used for mouse in vitro fertilization

Success rates of superovulation in response to gonadotropic hormone treatment and in vitro fertilization (ie, mitotic cleavage following insemination) of mouse eggs from outbred CD-1, hybrid CB6F_l, or hybrid B6CBAF₁, mice were compared using either a mouse inseminationmedium, modified Krebs-Ringer-bicarbonate (m-KRB), or a human insemination medium, Ham's F10 nutrient mixture. Inseminations were performed in either organ culture dishes or screw-top, flat-side tissue culture tubes. Mean superovulation rates (± SD) were 24.2 (5.1) for CD-1, 33.0 (5.8) for CB6F₁, and 16.3 (6.6) for B6CBAF₁ mice. For in vitro cleavage the best combination of mouse strain, insemination medium, and culture container was achieved using CB6F₁, mice, m-KRB medium, and culture tubes. However, Ham's medium used with either hybrid mouse strain was shown to be employable for fertilization of mouse eggs in vitro as a quality control assay and/or experimental model system for testing the human in vitro fertilization procedure.     

Effects of cryopreservation of mouse embryos and in vitro fertilization on genotypic frequencies in colonies

To evaluate the effects of cryopreservation and in vitro fertilization (IVF) on genotypic frequencies in mouse colonies, genotypic frequencies at 15 biochemical, 4 immunological and 20 microsatellite loci were examined in three colonies of MCH (ICR) mice derived from noncryopreserved embryos obtained by natural mating without the induction of superovulation, cryopreserved embryos obtained by natural mating with the induction of superovulation, and cryopreserved embryos obtained by the induction of superovulation and IVF. Three (Pgm-1, Ldr-1 and Hbb) out of the 15 biochemical loci, two (Thy-1 and H2K) out of four immunological loci and five (D5Mit18, D6Mit15, D12Mit5, D13Mit26, and D14Mit7) out of 20 microsatellite loci that showed polymorphisms in every colony were used for detection of genotypic frequencies. The genotypic frequencies of the loci in the three colonies did not differ from the predicted genotypic frequencies (P > 0.05). The results suggested that genetic drift does not occur among colonies established from treated and untreated embryos, and it was clear that the embryo banking by cryopreservation is suitable for preservation of outbred stock without genetic drift.     

Genetic influences on mouse sperm capacitation in vivo and in vitro

Intial in vivo studies were performed to observe the proportion of eggs fertillized at specific intervals after natural mating and ovulation in our research mouse colony. Proestrous females of the C57BL/10Wt, SJL/Wt inbred strains and the F₁ hybrid cross (B10 × SJL or reciprocals) were paired in the after-noon with males of their respective strain and examined for vaginal plugs at the midpoint of the dark period (2400 hours). Oviducts were periodically collected from mated females, and ovulation was first observed at 4, 5.2, and 3 hours after 2400 hours in the B10, SJL, and F₁ hyrid, respectively. The clutch of eggs from each ovulating female, was placed in culture, and cleavage oviduct lavage verifying female mating was placed in culture, and cleavage was used as the criterion for fertilizaition. Fifty percent of the eggs were fertilized 2.2, 5.0, and 2.5 hours after ovulation in B10, SJL, and F₁ hybrid females, respectively. Because twice the legth of time was required to fertilize a similar proportion of eggs from the SJL strain as the F₁ hybrid, these two strains were used for determining their rate of fertilization under more fully controlled conditions in vitro. Forty-nine percent of F₁ hybrid eggs were fertilized after 4 hours incubation with SJL epididymal sperm, whereas 53% fo SJL and 56% of F₁ hybrid eggs were fertilized after only 2 hours incubation with F₁ hybrid epididymal sperm. Thus, using sperm from these two mouse strains, the amount of time required to fertilize approximately 50% of the eggs within a clutch both in vivo and vitro was very similar. These observations demonstrte teh validity of using this in vitro system for fertilization studies and confirm that the temporal events in sperm capacitation and egg penetration are dependent on the genotype of the sperm. Similarities in fertilization rates at specific times after ovulation or insemination in vitro imply that the initiationof sperm capacitation in vivo occurs near the time of ovulation and several hours after mating. We tentatively suggest that follicular fluid may be required for completion of mouse sperm capacitaiton in vivo.     

Somatic and germ cell interactions during histogenetic aggregation of mouse fetal testes.

In the present study we examined the capacity of somatic and germ cells dissociated from fetal mouse testes at various stages to reform seminiferous cords in culture. We found that after 12 h in culture, seminiferous cords became segregated from stromal cells. Although Sertoli cells were incorporated into seminiferous cords at all stages studied, the germ cells dramatically changed their histogenetic behavior with age. Most germ cells which had been dissociated at 12.5 days postcoitum (dpc) were incorporated into the seminiferous cords, whereas at 14.5 dpc or later the majority remained among the stromal cells or as clusters on the surface of the aggregates. We considered three possible causes for this change in behavior of germ cells: (i) Failure to deposit some extracellular matrix components in the aggregates. (ii) Decrease in adhesiveness of prospermatogonia to either extracellular matrix components or Sertoli cells. (iii) A change in adhesiveness of Sertoli cells to germ cells with age. We found that laminin and fibronectin were similarly deposited in aggregates at 12.5 and 15.5 dpc. When prospermatogonia at 15.5 dpc labeled with colloidal gold were reaggregated with somatic cells at 12.5 dpc, 50% were incorporated into seminiferous cords. Moreover, [3H]thymidine-labeled Sertoli cells at 15.5 dpc formed heterochronic seminiferous cords with Sertoli cells at 12.5 dpc. These results suggest that mouse Sertoli cells change their surface property which is essential for binding to germ cells when they enter the mitotic resting stage (T-prospermatogonia).     

Inhibition of sperm transport and fertilization in superovulating ewes

In Experiment 1, all ewes were treated with follicle stimulating hormone (FSH-P) to induce superovulation. Ewes came into natural estrus or were treated with prostaglandin F(2)alpha (PGF(2)alpha) or 6-methyl-17-acetoxyprogesterone (MAP) to regulate the time of estrus. The ewes were mated during estrus and necropsied 3 h after mating. Regulation of estrus with either compound reduced the number of sperm recovered from the cervix, uterus, and oviducts and increased the proportions of sperm recovered from the cervix and uterine body that were immotile, dead, or had disrupted membranes. In Experiment 2, all ewes were in natural estrus. They either ovulated naturally or were superovulated, and ewes in each group were necropsied at 3 or 23 h after mating. Superovulation reduced the number of sperm in oviducts, uterus, and anterior segments of the cervix at both time intervals and increased the proportions of sperm that were immotile, dead, or had disrupted membranes. In Experiment 3, of 3x2 design, ewes were in either natural estrus or estrus regulated with PGF(2)alpha or with MAP; they ovulated naturally or were superovulated. Ewes were necropsied 3 d after mating and ova were examined. Both regulation of estrus and superovulation reduced the proportion of ova that were fertilized and reduced the number of accessory sperm attached to fertilized ova.     

昆明小鼠胚胎干细胞滋养层制备条件的实验研究

目的:建立小鼠胚胎成纤维细胞(MEFS)滋养层,用于昆明小鼠胚胎干细胞的培养。方法:取妊娠13.5的胎鼠,采用组织消化法分离培养出原代成纤维细胞,对MEFs的生长形态、生长曲线及分裂指数进行观察;MTT法筛选丝裂霉素C(MMC)作用的最佳浓度和时间;取妊娠3.5d的囊胚在经MMC处理的饲养层上培养,观察胚胎干细胞集落生成情况。结果:MEFS为一种贴壁生长且增殖速度较快的细胞,第三代细胞增殖旺盛,第5代以后细胞开始变形并趋于衰老;MMC能抑制胚胎成纤维细胞的增殖,最佳的作用浓度和时间是10ug/ml作用2.5～4h,20ug/ml作用1-2.5h。妊娠3.5d小鼠囊胚在饲养层上培养能形成典型的"鸟巢"状干细胞集落,并可维持胚胎干细胞的正常形态且不发生分化。结论:这种方法制备的滋养细胞层适用于胚胎干细胞的培养。     

BALB/c小鼠繁殖性能的观察及分析

为提高BALB／c小鼠受学率,对其生殖性能进行了研究。结果表明：性周期动情期的鉴定是提高小鼠受孕率的关键。光照、温度、噪音及湿度等因素对小鼠性周期影响很大。自然交配的受精卵质量远比超数排卵的好,但超数排卯仍不失为一种良好的获得更多卵子的辅助办法。     

Combined action of stem cell factor,leukemia inhibitory factor,and cAMP on in vitro proliferation of mouse primordial germ cells

In the present paper we investigated the effects of stem cell factor/mastocyte growth factor (SCF/MGF), leukemia inhibitory factor/differentiating inhibitory activity (LIF/DIA) (two growth factors known to affect primordial germ cell growth in vitro) and forskolin (FRSK) (an activator of adenylate cyclase in many cell types) alone or in combination on the survival and proliferation of primordial germ cells (PGCs) obtained from 8.5, 10.5, and 11.5 days post coitum (dpc) mouse embryos and cultured without pre-formed cell feeder layers. The results showed that both at 1 and 3 days of culture the addition of 100 ng/ml SCF, 20 μM FRSK, or in some instances 20 ng/ml LIF alone caused a significant increase of PGC number as compared with controls. The highest effects were obtained when SCF and/or LIF were used together with FRSK. Moreover, we found that FRSK elevated cAMP levels in purified 11.5 dpc PGCs and that this compound, but not SCF and LIF, stimulated PGC proliferation, as assessed by 5-bromo-2′-deoxyuridin (BrdU) incorporation. These results suggest a mechanism of combined action of cAMP with SCF and/or LIF in the control of proliferation of mouse PGCs in vitro. © 1993 Wiley-Liss, Inc.     

SD大鼠体外受精与早期胚胎体外培养体系的初步建立

目的改造IVF-30和HTFplus培养液,观察在改造后培养液里卵的受精和早期胚胎的发育状况,寻找适合SD大鼠体外受精和早期胚胎培养的实验体系。方法采用两种方法(超数排卵及体内成熟)采集成熟卵母细胞用于体外受精。选择两种商品化的培养液IVF-30(Vitrolife),HTFplus(Lifeglobal)。分别在以上的培养基中增加10、20、30mmol/L的NaCl,将培养液的渗透压提升至325~355mOsM之间,观察在改造前与改造后的培养液内SD大鼠卵母细胞受精率和囊胚发育率等指标。结果经改造的培养液HTFplus和IVF-30,体外受精率分别从13%、15%提升至70%、67%。改造后的IVF-30和HTFplus的2细胞,大于4细胞及囊胚的发育率分别为85%,74%,22%;96%,75%,32%。HTFplus,IVF-30经过改造后更适合于SD大鼠的体外受精及早期胚胎培养。与超排相比较更多的在自然周期的体内成熟卵母细胞(16%,28%)发育到了囊胚。结论成功建立了SD大鼠的体外受精和体外培养系统。     

An alternative simple method for mass production of chimeric embryos by coculturing denuded embryos and embryonic stem cells in Eppendorf vials

The generation of germline competent chimeric mice via embryonic stem (ES) cells is a crucial step in developing gene-manipulated mouse models. To date, techniques for generating chimeric mice include direct microinjection of ES cells into the cavity of 3.5-d post-coitum (dpc) blastocysts and aggregating or coculturing 2.5 dpc zona pellucida-free (denuded) embryos with ES cells. We present here a procedure that is simple and reproducible for mass producing (10-150 embryos/vial/time) chimeric embryos by coculturing denuded 8-cell embryos and morula in 0.8 mL KSOM-AA medium containing 5 x 10(5)mL-1 purified green fluorescence protein-expressing ES cells (either fresh or thawed) in an 1.7 mL Eppendorf vial for 3h. The resulting chimeras had substantial levels of chimerism and high germline transmission rates. Therefore, the method developed in this study can provide a simple and mass reproducible alternative method (to germline transmitter chimeric mice), without technological and instrumental difficulties, for generating chimeric embryos.     

Birth of mice after nuclear transfer by electrofusion using tail tip cells

Mice have been successfully cloned from cumulus cells, fibroblast cells, embryonic stem cells, and immature Sertoli cells only after direct injection of their nuclei into enucleated oocytes. This technical feature of mouse nuclear transfer differentiates it from that used in domestic species, where electrofusion is routinely used for nuclear transfer. To examine whether nuclear transfer by electrofusion can be applied to somatic cell cloning in the mouse, we electrofused tail tip fibroblast cells with enucleated oocytes, and then assessed the subsequent in vitro and in vivo development of the reconstructed embryos. The rate of successful nuclear transfer (fusion and nuclear formation) was 68.8% (753/1094) and the rate of development into morulae/blastocysts was 40.8% (260/637). After embryo transfer, seven (six males and one female; 2.5% per transfer) normal fetuses were obtained at 17.5-21.5 dpc. These rates of development in vitro and in vivo are not significantly different from those after cloning by injection (44.7% to morulae/blastocysts and 4.8% to term). These results indicate that nuclear transfer by electrofusion is practical for mouse somatic cell cloning and provide an alternative method when injection of donor nuclei into recipient oocytes is technically difficult.     

Rabbit blastocyst: Allocation of cells to the inner cell mass and trophectoderm

The proportion of total cells in the blastocyst allocated to the inner cell mass (ICM) and trophectoderm (TE) is important for future development and may be a sensitive indicator to evaluate culture conditions. The number of cells and their distribution within the two primary cell lineages were determined for the rabbit embryo developing in vivo after superovulation or nonsuperovulation or embryo transfer and compared with embryos developing in vitro. Comparisons were made with cultured embryos or embryos grown in vivo until 3.5, 4.0, and 4.5 days of age. Embryos from superovulated rabbits developed in vivo for 3.5, 4.0, and 4.5 days, respectively, had 361, 758, and 902 total cells (P<0.05), and in nonsuperovulated rabbits 130, 414, and 905 total cells (P<0.05), with increasing proportions of ICM cells over time (P<0.05). One-cell embryos recovered from superovulated females and transferred to nonsuperovulated recipients developed more slowly with 70, 299, and 550 total cells after 3.5, 4.0, and 4.5 days of culture (P<0.05), respectively. The proportion of ICM cells increased with age of the embryo. Corresponding values for one-cell embryos cultured in vitro resulted in 70, 299, and 550 total cells (P<0.05). However, in vitro culture of morula-stage embryos in the presence of fetal bovine serum for 24 hr did not delay growth. In addition, the proportions of ICM/total cells were 0.17, 0.25, and 0.29 for embryos developing in vitro at 3.5, 4.0, and 4.5 days, respectively, similar to those for embryos developing in vivo at each of the three recovery times. These data establish for the first time the number and proportion of cells allocated to the ICM of the rabbit embryo developing in vivo or under defined conditions in vitro. © 1995 Wiley-Liss, Inc.     

Mouse oocytes derived from fetal germ cells are competent to support the development of embryos by in vitro fertilization

Mouse oocyte development in vitro has been studied in the past several years, but no evidence showed that the fertilizable oocytes could be obtained from the fetal mouse germ cells before the formation of the primordial follicles. In this study, an efficient and simple method has been established to obtain the mature oocytes from the fetal mouse germ cells at 16.5 days post-coitum (dpc). For the initial of follicular formation, fetal mouse 16.5 dpc ovaries were transplanted to the recipient under the kidney capsule, and the ovaries were recovered after 14 days. Subsequently, the growing preantral follicles in the ovarian grafts were isolated and cultured in vitro for 12 days. Practically, the mature oocytes ovulated from the antral follicles were able to be fertilized in vitro and support the embryonic development. The results demonstrate that the fetal mouse 16.5 dpc germ cells are able to form primordial follicles with the ovarian pregranulosa cells during the period of transplantation in the ectopic site, and the oocytes within the growing follicles are able to mature in vitro, then are able to support the embryonic development.     

Successful cryopreservation of mouse ovaries by vitrification

We developed a new method of cryopreservation of whole ovaries by vitrification using DAP213 (2 M dimethyl sulfoxide, 1 M acetamide, and M propylene glycol) as a cryoprotectant. Four-week-old C57BL/6 mice that underwent partial ovariectomy were orthotopically transplanted with cryopreserved or fresh ovaries (experimental or control group) isolated from 10-day-old green fluorescent protein (GFP)-transgenic mice (+/+). GFP-positive pups were similarly obtained from both groups by natural mating or in vitro fertilization (IVF) followed by embryo transfer, indicating that the cryopreserved ovaries by vitrification retain their fecundity. However, a statistically significant difference (P < 0.05) was found between both groups with respect to the following parameters: the number of GFP-positive pups born by natural mating/grafted ovary (0.8 +/- 0.3 for the experimental group versus 2.0 +/- 0.7 for the control group, mean +/- SEM), the number of collected oocytes by superovulation per mouse (7.0 +/- 1.7 for the experimental group versus 22.7 +/- 3.2 for the control group), the percentage of two-cell embryos obtained from GFP-positive oocytes by IVF (38.5% for the experimental group versus 90.0% for the control group). Histologically, normal development of follicles and formation of corpora lutea were observed in frozen-thawed grafts. However, estimated number of follicles decreased in frozen-thawed ovaries compared with fresh ovaries. Taken together, cryopreservation of the ovary by vitrification seems a promising method to preserve ovarian function, but further studies are required to overcome the possible inhibitory effects of this method on the growth of the ovarian graft.