不同直径山羊卵泡卵母细胞的发育特征及体外发育能力

目的研究山羊卵巢表面不同直径卵泡卵母细胞的发育特征及体外发育能力,优化山羊早期胚胎体外生产系统。方法收集繁殖期和非繁殖期山羊卵巢,采集表面直径小于1.5 mm、1.5-2.5 mm、2.5-3.5 mm和大于3.5 mm4种卵泡卵母细胞,以Hoechst33342染色检查核发育阶段;同时,利用体外培养方法观察不同直径卵泡卵母细胞的成熟、受精和早期胚胎发育能力。结果直径小于1.5 mm卵泡卵母细胞主要处于GVI期;1.5-2.5 mm卵泡卵母细胞以GVⅠ、GVⅡ和GVⅢ期为主;2.5-3.5 mm卵泡卵母细胞在GVⅡ到GVⅣ期间平均分布;大于3.5mm卵泡卵母细胞主要为GVⅢ到GVBD期。体外培养实验发现,直径小于1.5 mm卵泡卵母细胞仅有个别能完成成熟和卵裂;大于1.5 mm卵泡卵母细胞具有核成熟能力,能完成成熟和受精,但1.5-2.5 mm卵泡卵母细胞的受精卵通常阻滞于4-8细胞期;当卵泡直径大于2.5 mm时,卵母细胞才能较好地支持胚胎继续发育,其桑/囊胚的比例达到30%以上。卵泡卵母细胞的发育特征和体外发育能力与动物所处的繁殖季节无关。结论山羊卵巢上直径大于1.5 mm卵泡卵母细胞具有核成熟能力,大于2.5 mm卵泡卵母细胞能支持早期胚胎继续发育。     

银鲫卵母细胞Spindlin基因的表达特征及其功能分析

在卵母细胞成熟过程中,Spindlin与纺锤体微管蛋白相互作用,在配子到胚胎的过程中具有调节细胞周期的作用。前期研究表明,银鲫Spindlin(CagSpin)与微管蛋白相互作用,并与减数分裂的纺锤体共定位。在成熟过程中,CagSpin被磷酸化,在卵母细胞受精和卵胚转换中发挥重要的作用。研究通过对激素诱导后的卵母细胞进行追踪,采用RT-PCR和Western-blot分析,揭示卵母细胞在完成成熟的过程中,CagSpin持续大量表达。采用体外诱导卵母细胞成熟技术和显微注射的方法,揭示过量表达CagSpin导致胚泡(Germinalvesicle,GV)不能破裂,卵母细胞成熟过程被抑制。这些结果表明,CagSpin在卵母细胞成熟过程中发挥着关键的作用,同时为深入研究CagSpin的功能提供依据。     

雌核发育银鲫和两性融合彩鲫卵母细胞体外诱导成熟过程中周期蛋白 …

采用体外诱导卵母细胞成熟技术,比较研究了雌核发育银鲫和两性融合发育彩鲫卵母细胞成熟过程中周期蛋白合成和ＭＰＦ活性变化情况。结果表明：１７α,２０β－二氢孕酮（简称ＤＰ）浓度为０．５μｇ／ｍｌ,温度为２４℃,光照时间２０小时为最适诱导条件。在相同条件下,两性生殖彩鲫卵母细胞体外诱导成熟速度明显快于银鲫。相应的细胞学研究表明,在体外诱导时,银鲫和彩鲫卵母细胞的发育成熟是正常的。银鲫卵母细胞生发泡破裂（     

小鼠精子注入兔卵母细胞受精研究

利用显微操作仪将小鼠精子注入家兔卵母细胞的胞质内和透明带下,对鼠兔异种精卵互作和异种受精胚胎的发育进行了研究,并对注射精子的数量及卵的体外成熟时间等影响鼠兔异种显微受精的因素进行了探讨,结果如下:(1)将小鼠精子分别注入兔卵胞质内和透明带下,均能激活兔卵母细胞,导致精核解聚和原核形成;(2)小鼠精子注入兔卵胞质内和透明带下受精,杂种胚胎体外培养能发育到8-细胞期;(3)鼠兔异种受精4-细胞胚胎染色体标本制备观察结果表明,它们为正常二倍体;(4)鼠兔异种受精4-细胞胚胎的超微结构观察结果表明,它们极近似兔正常4-细胞胚胎的超微结构;(5)将小鼠精子注入兔卵透明带下,注射5—10个精子组卵的受精率(32.4%)和卵裂率(16.2%)均高于注射单个精子组的,但二组间差异不显著(P>0.05);DM 15%NCS液中体外成熟培养11—12h兔卵透明带下注入1—2个小鼠精子后的受精率(42.3%)和卵裂率(30.8%)均高于体外成熟培养24—25h组的,但二组间差异未达到显著水平(P>0.05)。     

雌核发育银鲫和两性融合彩鲫卵母细胞体外诱导成熟过程中周期蛋白合成和MPF活性变化的比较研究

采用体外诱导卵母细胞成熟技术 ,比较研究了雌核发育银鲫和两性融合发育彩鲫卵母细胞成熟过程中周期蛋白合成和MPF活性变化情况。结果表明 :1 7α ,2 0 β 二氢孕酮(简称DP)浓度为 0 5μg/ml,温度为 2 4℃ ,光照时间 2 0小时为最适诱导条件。在相同条件下 ,两性生殖彩鲫卵母细胞体外诱导成熟速度明显快于银鲫。相应的细胞学研究表明 ,在体外诱导时 ,银鲫和彩鲫卵母细胞的发育成熟是正常的。银鲫卵母细胞生发泡破裂 (GVBD)时已有周期蛋白的合成 ,但生发泡破裂开始后则呈现合成速度下降直至没有合成的现象。尽管如此 ,卵母细胞中MPF活性却仍保持继续增强之势 ,至GVBD达1 0 0 %时 ,活性最强。而在两性融合发育彩鲫卵母细胞成熟过程中 ,周期蛋白的合成呈现出由较多到无 ,再逐渐到多的变化。GVBD开始时 ,周期蛋白合成较多 ,此后则急剧下降至几无周期蛋白的合成 ,以后随着成熟诱导的进行 ,周期蛋白的合成速度又缓慢回升至GVBD开始时的状态。与此相对应 ,MPF活性也出现从较强变无 ,再逐渐增至最强的变迁。这些结果初步揭示 ,鱼类卵母细胞中周期蛋白的合成和MPF活性的出现与卵母细胞的成熟分裂密切相关 ,雌核发育银鲫卵母细胞生发泡破裂开始以后 ,周期蛋白合成的消失可能与其特殊的三极纺锤体形成及其后的动力     

斑马鱼卵母细胞的体外成熟及成熟卵的受精发育

采用体外培养的方法,研究斑马鱼卵母细胞的成熟过程。Ⅳ时相初级卵母细胞在o．5μg／m1 17a－羟基孕酮的EM－199培养液中,80％氧气,25℃的体外培养条件下,在40min内,胚泡(GV)逐渐由卵母细胞中央至动物极边缘l／2处移到动物极边缘,进八V时相卵母细胞。30min后胚泡破裂(GVBD),胚泡破裂率为59％。此种卵母细胞继续培养2h才完全成熟。成熟卵不能从滤泡膜中自然排出。冷开水中剥离其外边的滤泡膜后加入具有受精能力的精子,即能使成熟卵受精,受精膜举起,胚盘在动物极形成。其后受精卵的分裂、发育等与自然成熟受精卵相同。以发育至囊胚为受精标准,这种体外成熟卵受精率为78％。这是斑马鱼卵母细胞体外培养成熟的首例报道。鱼类卵母细胞体外成熟技术的建立,为外源基因卵母细胞胚泡内转移奠定了基础。     

利用IVF废弃胚胎为核移植受体构建人体细胞克隆胚胎

目的：探讨利用IVF废弃胚胎构建人体细胞克隆胚胎的发育潜能及其在人治疗性克隆应用的可能性。方法：收集2008年7-12月在广州医学院第三附属医院进行体外受精-胚胎移植周期中的多精受精胚胎和MII期体外受精失败卵母细胞,运用显微操作技术构建人体细胞克隆胚胎,观察胚胎发育情况。结果：多精受精胚胎为核移植受体的克隆胚胎能够发育到8-细胞期,受精失败MII期卵母细胞为核移植受体的克隆胚胎能够激活,但不能够卵裂。两种IVF废弃的胚胎构建的人体细胞克隆胚胎在去核成功率,注核成功率上无显著差异（P＆gt;0.05）,但卵裂率和8细胞率上具有显著差异（P＆lt;0.05）。结论：多精受精胚胎比MII期体外受精失败卵母细胞更适合作为人核移植受体细胞。     

卵母细胞的生发泡移植

生发泡(germinal vesicle,GV)移植到去核的GV期卵母细胞后,获得重构卵,重构卵在体外能成熟,受精和进行胚胎发育。GV移植到去核的第二次减数分裂中期(metaphase Ⅱ,MII)卵母细胞后,重构卵能发生GV破裂,但难以排出第一极体。GV移植后,通过连续核移植,重构合子具有发育到终期的能力。GV移植为研究卵母细胞的发育提供了一种重要工具。     

银鲫ZP3的表达特征和卵壳ZP3蛋白的分离

克隆得到银鲫(Carassius auratus gibelio)ZP3基因全长cDNA,在体外表达出银鲫的ZP3融合蛋白,并制备出多抗血清;通过免疫印迹和RT-PCR分析,研究了银鲫ZP3在卵子发生过程中的表达特征和在早期发育胚胎中的状态变化。研究结果表明,银鲫ZP3的转录发生在卵黄发生以前,而ZP3蛋白的翻译起始于卵黄形成阶段,且随着卵母细胞进一步成熟,其含量不断增加。ZP3蛋白的存在状态在受精后和早期胚胎发育过程中发生了明显变化。在受精后5-30min期间,抽提液中原始的ZP3蛋白带迅速消失,取而代之的是分子量大约为90KD以及更高分子量的蛋白带;而在受精后80min和8-16胞期的胚胎抽提液中,二聚体和多聚体复合体蛋白带也相继消失。这种状态变化意味着ZP3蛋白在卵子受精后有可能与自身或其他蛋白共价结合转变成了二聚体和多聚体。接着,用获得的ZP3抗体作为检测指标,通过卵壳蛋白的凝胶分离,从卵壳中分离纯化出银鲫ZP3蛋白。       

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×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。     

不同年龄昆明白小鼠卵母细胞的生发泡互换

为探讨卵母细胞减数分裂异常及其与年龄相关变化之间的关系,对不同年龄段昆明白小鼠卵母细胞进行了生发泡(GV)移植研究。应用显微操作和电融合技术,将6~8周龄小鼠GV期卵母细胞分别与6月龄9、月龄和12月龄小鼠GV期卵母细胞进行GV互换,所形成的6种GV-胞质体复合体的融合率(89.7%~95.6%)和6种重组卵母细胞的成熟率(83.5%~88.2%)并不因小鼠年龄的改变而有所变化。成熟的6种重组卵母细胞经体外受精后,形成原核期胚和2-细胞期胚的比率(分别为80.0%~87.3%和42.7%~50.9%)并不因不同年龄小鼠卵母细胞GV互换所带来的细胞质或细胞核的改变而受到影响。     

Establishment of a novel method for cryopreservation and thawing of the mouse ovary

During cryopreservation of ovarian tissue, the conditions of freezing and thawing are big factors controlling the survival rate of oocytes obtained. However, the conditions and procedures as they pertain to ovarian follicles and oocytes have not been established. Thus, we tried to determine the appropriate freeze-thaw times using the vitrification method with ethylene glycol and DMSO as cryoprotective agents and dd Y female mouse ovaries. The maturity rate from GV to the metaphase-II (MII) stage was 62.8% with ethylene glycol and 69.3% using DMSO, while the controls (GV oocytes obtained from a fresh ovary) showed a maturation rate of 83.6% (46/55). MII oocytes obtained by culturing GV oocytes in vitro showed a 64.3% (18/28) fertility rate via in vitro fertilization and a developmental rate into a 2 cell stage embryo of 35.7% (10/28) and into a 4-cell stage, 7.1% (2/28). However, development beyond the 8 cell stage embryo was not observed. A significant difference was not recognized between control (fresh) and ovarian tissues that had been frozen/thawed with respect to their ability to produce hormones. It is concluded that the vitrification method was effective for both freezing ovarian tissues and preserving its functional ability (maturation and capacitation).     

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.     

Effect of maturation stage at cryopreservation on post-thaw cytoskeleton quality and fertilizability of equine oocytes

Oocyte cryopreservation is a potentially valuable technique for salvaging the germ-line when a valuable mare dies, but facilities for in vitro embryo production or oocyte transfer are not immediately available. This study examined the influence of maturation stage and freezing technique on the cryopreservability of equine oocytes. Cumulus oocyte complexes were frozen at the immature stage (GV) or after maturation in vitro for 30 hr (MII), using either conventional slow freezing (CF) or open pulled straw vitrification (OPS); cryoprotectant-exposed and untreated nonfrozen oocytes served as controls. After thawing, GV oocytes were matured in vitro, and MII oocytes were incubated for 0 or 6 hr, before staining to examine meiotic spindle quality by confocal microscopy. To assess fertilizability, CF MII oocytes were subjected to intracytoplasmic sperm injection (ICSI) and cultured in vitro. At 12, 24, and 48 hr after ICSI, injected oocytes were fixed to examine their progression through fertilization. Both maturation stage and freezing technique affected oocyte survival. The meiosis resumption rate was higher for OPS than CF for GV oocytes (28% vs. 1.2%; P < 0.05), but still much lower than for controls (66%). Cryopreserving oocytes at either stage induced meiotic spindle disruption (37%-67% normal spindles vs. 99% in controls; P < 0.05). Among frozen oocytes, however, spindle quality was best for oocytes frozen by CF at the MII stage and incubated for 6 hr post-thaw (67% normal); since this combination of cryopreservation/IVM yielded the highest proportion of oocytes reaching MII with a normal spindle (35% compared to <20% for other groups), it was used when examining the effects of cryopreservation on fertilizability. In this respect, the rate of normal fertilization for CF MII oocytes after ICSI was much lower than for controls (total oocyte activation rate, 26% vs. 56%; cleavage rate at 48 hr, 8% vs. 42%: P < 0.05). Thus, although IVM followed by CF yields a respectable percentage of normal-looking MII oocytes (35%), their ability to support fertilization is severely compromised.     

Developmental potential of selectively enucleated immature mouse oocytes upon nuclear transfer

Selective enucleation (SE) was applied to germinal vesicle (GV) oocytes by removing the chromatin attached to nuclear envelope, and leaving the liquid contents of GV in the cytoplast. However, after reconstruction with 1/8 blastomeres or fetal fibroblasts (FFs) neither the maturation efficiency nor the frequency of normal (asymmetric) division was improved as compared with completely enucleated (CE) oocytes. Chromosomal aberrations introduced with somatic nuclei were not rescued in SE oocytes either. On the other hand, timing of maturation division in SE GV oocytes, but not in CE GV oocytes, reconstructed with GV-karyoplasts was like in the control. After maturation and fertilization in vitro, SE oocytes reconstructed with 1/8 blastomeres developed nucleolated donor pronuclei, contrary to CE oocytes. The latter could be rescued with nucleoli-containing nucleus, but not anucleolate nucleus, from a 1/2 blastomere. SE oocytes reconstructed with FFs contained nucleolated pronuclei upon activation, unlike CE GV oocytes. These experiments show that the ooplast nucleolar material and/or embryonic nucleolus are indispensable for pronuclei formation. SE oocytes reconstructed with 1/8 blastomeres or FFs failed to cleave after activation or in vitro fertilization. Control GV oocytes enucleolated before fertilization seized cleavage at the 6-cell stage, as oppose to intact GV oocytes, which in 50.9% yielded morulae/blastocysts. These results suggest that ooplast nucleolar material is essential for the cleavage divisions. Activation of cumulus-enclosed SE GV oocytes matured in hormone-supplemented medium and fused to 1/2 blastomere-karyoplasts, yielded morulae, and blastocysts in 45.5% and 23.4% of reconstructed oocytes, respectively.     

Micromanipulation of cleaved embryos cultured in protein-free medium: a mouse model for assisted hatching.

A mouse model for studying anomalies of human embryonic hatching following micromanipulation is proposed. Initiation and completion of mouse blastocyst hatching was severely impaired (34/292; 12% and 28/292; 10%, respectively) with protein deprivation, resembling the situation in human in vitro fertilization. Hatching ability was restored when an artificial gap was introduced in the zona pellucida by micromanipulation at the cleaved embryo stage. This enabled 77% (285/371) and 36% (134/371) of the embryos to initiate and complete hatching in protein-free medium. No differences were found in overall cell counts between the two groups of embryos. Transfer of micromanipulated blastocysts to pseudopregnant females resulted in development of healthy fetuses.     

Polo-like kinase-1 in porcine oocyte meiotic maturation, fertilization and early embryonic mitosis.

Polo-like kinases (Plks) are a family of serine/threonine protein kinases that regulate multiple stages of mitosis. Expression and distribution of polo-like kinase 1 (Plk1) were characterized during porcine oocyte maturation, fertilization and early embryo development in vitro, as well as after microtubule polymerization modulation. The quantity of Plk1 protein remained stable during meiotic maturation. Plk1 accumulated in the germinal vesicles (GV) in GV stage oocytes. After germinal vesicle breakdown (GVBD), Plk1 was localized to the spindle poles at metaphase I (MI) stage, and then translocated to the middle region of the spindle at anaphase-telophase I. Plk1 was also localized in MII spindle poles and on the spindle fibers and on the middle region of anaphase-telophase II spindles. Plk1 was not found in the spindle region when colchicine was used to inhibit microtubule organization, while it accumulated as several dots in the cytoplasm after taxol treatment. After fertilization, Plk1 concentrated around the female and male pronuclei. During early embryo development, Plk1 was found to be in association with the mitotic spindle at metaphase, but distributed diffusely in the cytoplasm at interphase. Our results suggest that Plk1 is a pivotal regulator of microtubule organization and cytokinesis during porcine oocyte meiotic maturation, fertilization, and early embryo cleavage in pig oocytes.     

The importance of mitochondrial metabolic activity and mitochondrial DNA replication during oocyte maturation in vitro on oocyte quality and subsequent embryo developmental competence

Mitochondrial metabolic capacity and DNA replication have both been shown to affect oocyte quality, but it is unclear which one is more critical. In this study, immature oocytes were treated with FCCP or ddC to independently inhibit the respective mitochondrial metabolic capacity or DNA replication of oocytes during in vitro maturation. To differentiate their roles, we evaluated various parameters related to oocyte maturation (germinal vesicle break down and nuclear maturation), quality (spindle formation, chromosome alignment, and mitochondrial distribution pattern), fertilization capability, and subsequent embryo developmental competence (blastocyst formation and cell number of blastocyst). Inhibition of mitochondrial metabolic capacity with FCCP resulted in a reduced percent of oocytes with nuclear maturation; normal spindle formation and chromosome alignment; evenly distributed mitochondria; and an ability to form blastocysts. Inhibition of mtDNA replication with ddC has no detectable effect on oocyte maturation and mitochondrial distribution, although high-dose ddC increased the percent of oocytes showing abnormal spindle formation and chromosome alignment. ddC did, however, reduce blastocyst formation significantly. Neither FCCP nor ddC exposure had an effect on the rate of fertilization. These findings suggest that the effects associated with lower mitochondrial DNA copy number do not coincide with the effects seen with reduced mitochondrial metabolic activity in oocytes. Inhibiting mitochondrial metabolic activity during oocyte maturation has a negative impact on oocyte maturation and subsequent embryo developmental competence. A reduction in mitochondrial DNA copy number, on the other hand, mainly affects embryonic development potential, but has little effect on oocyte maturation and in vitro fertilization.     

In vitro maturation and fertilization of oocytes from Norwegian semi-domestic reindeer (Rangifer tarandus )

Reindeer oocytes were submitted to in vitro maturation, fertilization and culture (IVM,IVF,IVC) using the established procedures for bovine in vitro embryo production. The study was conducted outside the main breeding season. Semen was collected from epididymides immediately after slaughter, and was diluted in Tris-fructose-citric acid extender containing 6% glycerol and 20% egg-yolk and then frozen in liquid nitrogen. Following 24 h of maturation, cumulus expansion was complete, and 71% of the oocytes reached Metaphase II (MII), with extrusion of the first polar body. Of the remaining oocytes, 22% were at the germinal vesicle stage (GV), 2% at diakinesis and 5% at Metaphase I (MI). The percentages of fertilization and cleavage were 36.0 and 31.8%, respectively. Two of the fertilized oocytes developed to the morula stage after 7 d of culture.