体外培养小鼠卵母细胞及其生长分化因子-9基因表达

体外培养小鼠的窦前卵泡以得到第二次减数分裂中期(MⅡ)卵母细胞,比较体外发育卵母细胞与体内生长的卵母细胞生长分化因子-9(GDF-9)的基因表达量,探讨GDF-9的表达对卵母细胞体外发育成熟的影响。选择体外培养第2天(D2)、D4、D6、D8、D10、D12卵母细胞作为体外发育组;同窝雌性小鼠出生后D12、D14、D16、D18、D20、D22卵母细胞作为体内发育组;半定量逆转录多聚酶链反应技术分别检测两组MⅠ卵母细胞GDF-9基因表达量。结果体外培养小鼠窦前卵泡可以得到MⅡ期卵母细胞,卵泡成活率、窦腔形成率、卵母细胞成熟率分别达到89·5%、51·8%和56·6%。小鼠卵母细胞GDF-9基因表达量随发育时间的改变而发生变化,而体外发育D8—12卵母细胞GDF-9表达量显著低于同期体内发育卵母细胞(P<0·05)。体外发育D8—12卵母细胞GDF-9基因表达量低于同期体内发育的卵母细胞的原因之一可能是其发育潜能较低。     

体外培养小鼠卵母细胞及其生长分化因子-9基因表达

体外培养小鼠的窦前卵泡以得到第二次减数分裂中期(MⅡ)卵母细胞，比较体外发育卵母细胞与体内生长的卵母细胞生长分化因子-9(GDF-9)的基因表达量，探讨GDF-9的表达对卵母细胞体外发育成熟的影响。选择体外培养第2天(D2)、D4、D6、D8、D10、D12卵母细胞作为体外发育组；同窝雌性小鼠出生后D12、D14、D16、D18、D20、D22卵母细胞作为体内发育组；半定量逆转录多聚酶链反应技术分别检测两组MⅠ卵母细胞GDF-9基因表达量。结果体外培养小鼠窦前卵泡可以得到MⅡ期卵母细胞，卵泡成活率、窦腔形成率、卵母细胞成熟率分别达到89.5%、51.8%和56.6%。小鼠卵母细胞GDF-9基因表达量随发育时间的改变而发生变化，而体外发育D8—12卵母细胞GDF-9表达量显著低于同期体内发育卵母细胞(P<0.05)。体外发育D8—12卵母细胞GDF-9基因表达量低于同期体内发育的卵母细胞的原因之一可能是其发育潜能较低。     

卵泡发生过程中GDF-9和BMP-15(GDF-9B)的作用

近年来,对卵巢内卵泡发育,即从原始卵泡募集、优势选择、卵泡生长、排卵到黄体形成的调控研究取得了很大的进展.研究表明TGF-β超家族的许多成员在各阶段卵泡发生中起重要的调节作用.TGF-β超家族的两个成员-生长分化因子-9(GDF-9)和骨形态因子-15(BMP-15,或GDF-9B)主要在哺乳动物卵母细胞中表达,对卵泡生长发育起关键作用.本文对GDF-9和BMP-15在卵泡发育过程中的作用进行了综述.     

颗粒细胞EGF类因子信号通路在调控卵母细胞成熟和发育中的作用

动物体内卵泡排卵前促黄体素(luteinizing hormone, LH)诱导了卵丘颗粒细胞扩散,并启动卵母细胞恢复减数分裂。普遍认为,卵泡壁层颗粒细胞表达LH受体,卵母细胞及其周围卵丘细胞不表达LH受体,LH通过作用于卵泡壁层颗粒细胞产生信号分子,这些信号分子作用于卵丘颗粒细胞介导了LH生物作用。然而,一直以来,关于排卵前介导LH作用而诱导卵母细胞成熟的机制一直存在争议。目前研究认为,LH作用于卵泡壁层颗粒细胞后产生了EGF类因子,并与颗粒细胞的受体结合,促进了卵母细胞的成熟和发育。由于体外成熟的卵丘卵母细胞复合体来源于生长卵泡,其卵丘颗粒细胞EGF类因子信号系统不完善,目前的体外成熟培养体系难以模拟卵泡内的生理环境,导致卵母细胞体外发育能力较差,限制了这些卵母细胞的利用效率。本文综述了颗粒细胞EGF类因子信号系统、EGF类因子在调控卵母细胞成熟中的作用及对卵母细胞发育能力的影响,为优化卵母细胞体外成熟培养体系,完善卵丘颗粒细胞的EGF类因子的信号系统,进而提高卵母细胞体外成熟效率提供理论依据。     

处理方式不同的颗粒细胞和卵泡液对牛卵母细胞体外受精后卵裂率和囊胚率的影响

将牛的卵母细胞置于添加有不同预处理颗粒细胞及含有卵泡液的培养液或不舍有卵泡液的培养液中进行体外成熟、受精及胚胎发育培养,研究了颗粒细胞、卵泡液及颗粒细胞与卵泡液交互作用对牛卵母细胞成熟、受精后卵裂率、囊胚率的影响。2178枚卵母细胞体外成熟受精后胚胎发育的对比观察结果表明：颗粒细胞、卵泡液及颗粒细胞与卵泡液交互作用对卵母细胞成熟受精后胚胎的卵裂具有显著影响（P〈0．05）;颗粒细胞对囊胚的发育有显著影响（P〈0．05）;卵泡液及颗粒细胞与卵泡液交互作用对囊胚的发育无显著影响（P〉0．05）。不同因素对卵裂率、囊胚率的影响表现为：颗粒细胞因素〉培养液因素〉培养液&#215;颗粒细胞交互作用。结论：TCM199培养液中添加卵泡液和单层颗粒细胞组成的培养系统用于牛卵母细胞体外成熟及胚胎发育的效果较好。共培养体系中的单层颗粒细胞用经酶消化分散处理后在培养箱中孵育10min的颗粒细胞替代时,胚胎的发育效果并不受影响。     

Gas6在猪卵母细胞及早期胚胎中表达模式与功能的初步研究

该研究通过免疫组化和QRT-PCR等方法系统分析了Gas6（growth arrest-special gene 6）基因在猪卵泡发生及早期胚胎发育过程中的表达规律,并提出了一种改良猪卵母细胞体外成熟系统的方法。研究结果显示,Gas6基因表达于猪卵巢中的卵母细胞细胞核及其周围的卵丘细胞,在卵母细胞体外成熟及早期胚胎发育过程中始终有表达,且在囊胚中表达最高。Gas6 mRNA在卵母细胞成熟过程中始终存在,但在孤雌激活后迅速消失,直到发育到囊胚时再次出现。在猪卵母细胞体外培养系统中添加不同浓度的Gas6重组蛋白培养卵母细胞,发现添加Gas6重组蛋白对卵母细胞的极体率无显著影响;但是当添加浓度为100 ng/mL时,培养的卵母细胞孤雌激活后分裂率、囊胚率及囊胚细胞数都显著增高。Gas6可能是通过改善卵母细胞细胞质的成熟质量提高卵母细胞的发育潜能,从而获得了更多、更好的胚胎。     

沉默Gpr3基因表达对猪卵泡颗粒细胞凋亡的影响

G蛋白偶联受体3（G protein-coupled receptor 3,Gpr3）属于G蛋白偶联受体超家族成员,能够维持卵泡卵母细胞减数分裂的前期阻滞,但在卵泡颗粒细胞中的作用不清。该研究利用RNAi技术,以化学合成的siRNA转染体外培养的猪卵泡颗粒细胞,并利用Real-time PCR和Western blot技术检验Gpr3基因的沉默效果;利用MTT（四甲基偶氮唑盐）、流式细胞术和Real-time PCR技术检测沉默Gpr3基因表达对猪卵泡颗粒细胞凋亡以及凋亡相关基因表达的影响。结果显示,Gpr3-siRNA能够有效地抑制猪卵泡颗粒细胞中Gpr3基因mRNA和蛋白的表达（P〈0.01）;在沉默Gpr3基因表达后,猪卵泡颗粒细胞的细胞活性由0.419升高至0.586,同时细胞凋亡率由2.67%下降至0.42%,并在显著上调Bcl-2表达的同时,下调了Bax的表达（P〈0.05）。结果表明,沉默Gpr3基因的表达抑制了猪卵泡颗粒细胞的凋亡,其机制可能与调控Bcl-2和Bax表达有关。     

人重组卵泡刺激素和表皮生长因子对性未成熟小鼠卵母细胞和颗粒细胞复合体体外发育的作用

卵泡刺激素（FSH）对有腔卵泡和排卵前卵泡的促生命作用已被普遍接受,但关于其对腔前卵泡发育的作用报道结果不尽相同,关于表皮生长因子（EGF）对腔前卵泡的作用尚不确切,本研究目的在于探讨人重组卵泡刺激素（rechFSH)和EGF对早期卵泡发育的作用,利用胶原酶消化法从12日龄的小鼠卵巢中分离得到卵母细胞－颗粒细胞复合体（OGCs)(Fig.1)。体外每孔30－40个培养物并分别添加胎牛血清（FBS）,rechFSH和EGF。培养物每4天测量卵母细胞和OGCs直径,并每天照相,结果显示,rechFSH显著促进小鼠OGCs 及其卵母细胞的体外发育,这一作用可被EGF进一步增强（P＜0．05）（Fig.2),但到第八天培养结束时,培养后的OGCs卵母细胞要显著小于体内期生长对照组（P＜0．05）（Fig.3),说明FSH和EGF在卵泡早期发育中起重要作用。     

人重组卵泡刺激素和表皮生长因子对性未成熟小鼠卵母细胞和颗粒细胞复合体体外发育的作用(英文)

卵泡刺激素(FSH)对有腔卵泡和排卵前卵泡的促生长作用已被普遍接受,但关于其对腔前卵泡发育的作用报道结果不尽相同。关于表皮生长因子(EGF)对腔前卵泡的作用尚不确切。本研究目的在于探讨人重组卵泡刺激素(rechFSH)和EGF对早期卵泡发育的作用。利用胶原酶消化法从12日龄的小鼠卵巢中分离得到卵母细胞-颗粒细胞复合体(OGCs)(Fig.1)。体外每孔30~40个培养物并分别添加胎牛血清(FBS)、rechFSH和EGF。培养物每4天测量卵母细胞和OGCs直径,并每天照相。结果显示rechFSH显著促进小鼠OGCs及其卵母细胞的体外发育,这一作用可被EGF进一步增强(p<0.05)(Fig.2)。但到第八天培养结束时,培养后的OGCs卵母细胞要显著小于体内同期生长对照组(p<0.05)(Fig.3)。说明FSH和EGF在卵泡早期发育中起重要作用。     

大熊猫生长分化因子9(GDF-9)基因克隆与序列分析

生长分化因子9(GDF-9)是转化生长因子β(TGF-β)超家族的一个新成员,主要表达于卵母细胞,调节卵泡早期发育. 本文以大熊猫基因组DNA为模板,克隆了大熊猫GDF-9基因.序列分析显示:大熊猫GDF-9基因含两个外显子,编码一个由453个氨基酸组成的蛋白前体.该结果为进一步分析大熊猫GDF-9基因生物学功能奠定了基础.     

Expression of GDF-9, BMP-15 and their receptors in mammalian ovary follicles

The synergetic process of folliculogenesis is mainly regulated by GDF-9 and BMP-15 as well as their receptors, such as BMPR2, TβR1 and BMPR1B. Expressions of these factors and the receptors are significant different among species. This study was designed to detect expression of GDF-9, BMP-15 and their receptors in mouse, porcine and human healthy follicles by immunohistochemistry. Three ages of human ovary were studied according to ovarian developmental schedule, i.e. gestational week (GW) 16, puberty (14 year-old) and adult (40 year-old). The results showed that both GDF-9 and BMP-15 were detectable in oocytes from primary follicles onward, besides, BMP-15 also presented in granulosa cells (GCs) and follicular follicle of mature follicles in mouse. However, they were maintained in oocytes and GCs from primordial to mature follicles in porcine except that GDF-9 was undetectable in GCs of mature follicles. For human ovary, GDF-9 presented in oocytes of primordial follicles in all samples, whereas BMP-15 was only observed in primordial follicle of adult ovary. Receptors, BMPR2, TβR1 and BMPR1B were found in oocytes and GCs of all follicles in mouse and porcine. In human, they were stained in oocytes from primordial follices but BMPR1B was not expressed in pubertal primordial follicles. Furthermore, we found that GDF-9, BMP-15 and three receptors distributed in adult corpus lutea. Collectively, our studies suggested that GDF-9, BMP-15 and their receptors might correlate with primordial follicular recruitment in pig and human. Positive expression of the receptors (BMPR2, TβR1 and BMPR1B)in primordial follicles of mouse ovaries indicated that these receptors might interact with others ligands besides GDF-9 and BMP-15 to regulate primordial follicular activity in mouse. Moreover, presence of GDF-9 in oocytes and BMP-15 in oocytes and GCs of mature follicles from mice and porcine elucidated coordinated roles of GDF-9 and BMP-15 in cumulus oophorus expansion. Additionally, expression of these factors in adult human corpus lutea suggested they play roles in corpus luteum activity.     

Comparison of recombinant growth differentiation factor-9 and oocyte regulation of KIT ligand messenger ribonucleic acid expression in mouse ovarian follicles

Oocytes secrete factors that regulate the development of the surrounding granulosa cells in ovarian follicles. KIT ligand (KL) mRNA expression in granulosa cells is thought to be regulated by oocytes; however, the factor(s) that mediate this effect are not known. One candidate is the oocyte-specific gene product growth differentiation factor-9 (GDF-9). This study examined the effect of recombinant GDF-9 (rGDF-9) on steady-state KL mRNA expression levels in preantral and mural granulosa cells in vitro. Furthermore, the study compared the effect of rGDF-9 with that of coculture with oocytes at different developmental stages. As determined by RNase protection assay, both KL-1 and KL-2 mRNA levels in preantral and mural granulosa cells were suppressed by 25-250 ng/ml rGDF-9. Fully grown oocytes also suppressed both KL-1 and KL-2 mRNA expression levels. Partly grown oocytes isolated from 7-, 10-, or 12-day-old mice either had no effect on KL mRNA levels or promoted KL-1 mRNA steady-state expression. It is concluded that GDF-9 is likely to mediate the action of fully grown, but not partly grown, oocytes on granulosa cell KL mRNA expression.     

Growth differentiation factor 9 is antiapoptotic during follicular development from preantral to early antral stage

Ovarian follicular atresia represents a selection process that ensures the release of only healthy and viable oocytes during ovulation. The transition from preantral to early antral stage is the penultimate stage of development in terms of gonadotropin dependence and follicle destiny (survival/growth vs. atresia). We have examined whether and how oocyte-derived growth differentiation factor 9 (GDF-9) and FSH regulate follicular development and atresia during the preantral to early antral transition, by a novel combination of in vitro gene manipulation (i.e. intraoocyte injection of GDF-9 antisense oligos) and preantral follicle culture. Injection of GDF-9 antisense suppressed basal and FSH-induced preantral follicle growth in vitro, whereas addition of GDF-9 enhanced basal and FSH-induced follicular development. GDF-9 antisense activated caspase-3 and induced apoptosis in cultured preantral follicles, a response attenuated by exogenous GDF-9. GDF-9 increased phospho-Akt content in granulosa cells of early antral follicles. Although granulosa cell apoptosis induced by ceramide was attenuated by the presence of GDF-9, this protective effect of GDF-9 was prevented by the phosphatidylinositol 3-kinase inhibitor LY294002 and a dominant negative form of Akt. Injection of GDF-9 antisense decreased FSH receptor mRNA levels in cultured follicles, a response preventable by the presence of exogenous GDF-9. The data suggest that GDF-9 is antiapoptotic in preantral follicles and protects granulosa cells from undergoing apoptosis via activation of the phosphatidylinositol 3-kinase/Akt pathway. An adequate level of GDF-9 is required for follicular FSH receptor mRNA expression. GDF-9 promotes follicular survival and growth during the preantral to early antral transition by suppressing granulosa cell apoptosis and follicular atresia.     

Growth and differentiation factor-9 stimulates progression of early primary but not primordial rat ovarian follicle development

The ovary contains a pool of primordial follicles containing oocytes arrested in meiosis that are the source of developing follicles for the female. Growth and differentiation factor-9 (GDF-9) is a member of the transforming growth factor beta superfamily of growth factors, and follicles of GDF-9 knockout mice arrest in the primary stage of development. The effect of GDF-9 treatment on the primordial to primary follicle transition and on subsequent follicle progression was examined using a rat ovary organ culture system. Ovaries from 4-day-old rats were cultured under serum-free conditions in the absence or presence of growth factors. GDF-9 treatment caused a decrease in the proportion of stage 1 early primary follicles and a concomitant increase in the proportion of stage 2 mature primary follicles. GDF-9 did not effect primordial follicles or stage 0 to stage 1 follicle transition. GDF-9 also did not influence stage 3 or 4 secondary follicle numbers. Isolated antral follicle granulosa and theca cell cultures were used to analyze the actions of GDF-9. GDF-9 treatment did not directly influence either granulosa or theca cell proliferation. The ability of GDF-9 to influence the expression of another growth factor was examined. GDF-9 treatment increased kit ligand (KL) mRNA expression in bovine granulosa cells after 2 days of culture. Ovaries from 4-day-old rats were also cultured with or without GDF-9 treatment, and total ovary expression of KL mRNA was increased by GDF-9. In summary, GDF-9 was found to promote the progression of early primary follicle development but did not influence primordial follicle development. The actions of GDF-9 on specific stages of follicle development may in part be mediated through altering the expression of KL.     

Meiotic competence of in vitro grown goat oocytes

The objective of the present study was to grow meiotically incompetent goat oocytes from early antral follicles in vitro and to render them competent to undergo germinal vesicle breakdown. Cumulus-oocyte complexes with pieces of parietal granulosa cells were isolated from follicles 0.35-0.45 mm in diameter using both mechanical and enzymatic methods. The cumulus-oocyte complexes were divided into two groups according to oocyte diameter (group A: < 95 microm; group B: > 95 microm) and cultured for 8 or 9 days on granulosa cell monolayers. Within 8 days of culture, the mean oocyte diameter increased from 86 +/- 0.4 microm to 95 +/- 0.7 microm in group Aand from 106 +/- 0.2 microm to 109 +/- 0.5 microm in group B. After 9 days of culture, the mean diameter of oocytes from groups A and B were 99 +/- 0.5 microm and 112 +/- 0.4 microm, respectively. The meiotic competence of oocytes grown in vitro was evaluated by in vitro maturation. Within 8 days of culture, only 3% of oocytes from group A and 6% of oocytes from group B acquired the ability to undergo germinal vesicle breakdown. After 9 days of culture, 7% of group A oocytes and 42% of group B oocytes were competent to resume meiosis. The expression of p34(cdc2) in oocytes grown in vitro was analysed by the western blot technique. During 9 days of culture, p34(cdc2) accumulated in both groups of growing oocytes, but its concentration was lower than in fully grown oocytes used as controls. The results showed for the first time that goat oocytes from early antral follicles can grow, accumulate p34(cdc2) and acquire the ability to resume meiosis, when cultured for 9 days on granulosa cell monolayers.     

Growth differentiation factor-9 stimulates proliferation but suppresses the follicle-stimulating hormone-induced differentiation of cultured granulosa cells from small antral and preovulatory rat follicles

In addition to pituitary gonadotropins and paracrine factors, ovarian follicle development is also modulated by oocyte factors capable of stimulating granulosa cell proliferation but suppressing their differentiation. The nature of these oocyte factors is unclear. Because growth differentiation factor-9 (GDF-9) enhanced preantral follicle growth and was detected in the oocytes of early antral and preovulatory follicles, we hypothesized that this oocyte hormone could regulate the proliferation and differentiation of granulosa cells from these advanced follicles. Treatment with recombinant GDF-9, but not FSH, stimulated thymidine incorporation into cultured granulosa cells from both early antral and preovulatory follicles, accompanied by increases in granulosa cell number. Although GDF-9 treatment alone stimulated basal steroidogenesis in granulosa cells, cotreatment with GDF-9 suppressed FSH-stimulated progesterone and estradiol production. In addition, GDF-9 cotreatment attentuated FSH-induced LH receptor formation. The inhibitory effects of GDF-9 on FSH-induced granulosa cell differentiation were accompanied by decreases in the FSH-induced cAMP production. These data suggested that GDF-9 is a proliferation factor for granulosa cells from early antral and preovulatory follicles but suppresses FSH-induced differentiation of the same cells. Thus, oocyte-derived GDF-9 could account, at least partially, for the oocyte factor(s) previously reported to control cumulus and granulosa cell differentiation.