大鼠卵母细胞体外发育过程中的微管组装研究(英)

大鼠卵母细胞的发育具有许多与其他哺乳动物不同的特点,用激光共聚焦显微术研究了大鼠卵母细胞发育过程中微管的组装过程,以及一些因素对微管组装过程的影响.结果表明,在大鼠卵母细胞减数分裂的细胞周期进程中,细胞微管系统发生广泛而剧烈的重组,紫杉醇、星形孢菌素和冈田酸等药物能显著改变卵母细胞内的微管组织状态.大鼠卵母细胞可以在体外发生自发的孤雌活化,也可以被细胞松弛素诱导发生胞质假分裂.因此,研究了在这些过程中微管结构的特殊构象,以期更加深入认识这些特殊细胞事件的生化机理.     

γ-微管蛋白在猪卵母细胞成熟和活化中的分布(英)

微管蛋白（tubulin）是一蛋白质超家族,其中α-,β-微管蛋白是主要的微管蛋白,而γ-微管蛋白主要在微管组装中起作用. 我们利用蛋白质印迹和激光共聚焦技术研究了γ-微管蛋白在猪卵母细胞成熟、受精和活化中的分布. γ-微管蛋白存在于猪卵母细胞中,并且在减数分裂成熟各个时期的量保持不变. 它聚集在微管上,特别是中期纺锤体的两极和后末期的中板. 体外受精和孤雌活化后,γ-微管蛋白聚集在雌雄原核的周围.另外它也存在于精子的顶体帽和颈部.在早期卵裂中,γ-微管蛋白聚集在胚胎的细胞核周围.实验结果表明,γ-微管蛋白在猪卵母细胞、精子和胚胎的微管组装中起重要的调节作用,在猪受精过程中,精子和卵子都向受精卵贡献中心体物质.     

γ-微管蛋白在猪卵母细胞成熟和活化中的分布

微管蛋白(tubulin)是一蛋白质超家族,其中α-,β-微管蛋白是主要的微管蛋白,而γ-微管蛋白主要在微管组装中起作用. 我们利用蛋白质印迹和激光共聚焦技术研究了γ-微管蛋白在猪卵母细胞成熟、受精和活化中的分布. γ-微管蛋白存在于猪卵母细胞中,并且在减数分裂成熟各个时期的量保持不变. 它聚集在微管上,特别是中期纺锤体的两极和后末期的中板. 体外受精和孤雌活化后,γ-微管蛋白聚集在雌雄原核的周围.另外它也存在于精子的顶体帽和颈部.在早期卵裂中,γ-微管蛋白聚集在胚胎的细胞核周围.实验结果表明,γ-微管蛋白在猪卵母细胞、精子和胚胎的微管组装中起重要的调节作用,在猪受精过程中,精子和卵子都向受精卵贡献中心体物质.     

体外受精和孤雌活化过程中小鼠胚胎细胞骨架的动态变化

为研究微管在体外受精与孤雌活化过程中的动态变化,本实验比较了体外受精胚胎、SrCl2激活的孤雌胚胎和体内受精的原核期胚胎在体外发育的情况,采用免疫荧光化学与激光共聚焦显微术检测卵母细胞孤雌活化过程中及体外受精后微管及核的动态变化,以分析微管在减数分裂过程中的作用及其对早期发育的影响.结果显示,体内受精胚胎的发育率显著高于体外受精和孤雌激活胚胎体外发育率(P<0.05),而体外受精与孤雌激活胚胎在各阶段发育率差异均不显著.在体外受精中,精子入卵,激活卵母细胞,减数分裂恢复,纺锤丝牵拉赤道板卜致密排列的母源染色体向纺锤体两侧迁移;后期将染色体拉向两极;末期时,微管分布于两组已去凝集的母源染色体之间,卵母细胞排出第二极体(the second polarbody,Pb2),解聚的母源染色体形成雌原核.同时,在受精后5～8 h精子染色质发生去浓缩与再浓缩,形成雄原核.在原核形成的同时,胞质星体在雌、雄原核的周围重组形成长的微管,负责雌、雄原核的迁移靠近.孤雌活化过程中,卵母细胞恢复减数分裂,姐妹染色单体分离,被拉向两极,经细胞松弛素B处理后,活化4～6 h,卵周隙中未见Pb2,而在胞质中出现两个混合的单倍体原核,之间由微管相连接,负责两个单倍体原核的迁移靠近.与体外受精相比较,孤雌活化时卵母细胞更容易被激活,减数分裂期间微管的发育早且更完善.     

微管蛋白亚型及其功能

微管是真核细胞构成细胞骨架的主要成分,由α/β微管蛋白组装而成。微管在细胞多种活动中发挥着重要的作用,其功能主要受微管结合蛋白、微管蛋白的翻译后修饰以及微管蛋白亚型的调控。已有研究发现,α/β微管蛋白存在多种亚型,微管蛋白亚型在不同组织以及发育过程中的表达模式差异较大。多种微管蛋白亚型基因的突变可以引起神经系统疾病。该文综述了微管蛋白亚型的研究进展,尤其在微管功能调控、神经系统发育及其相关疾病中的作用。     

小鼠母源因子对早期胚胎发育的影响

在脊椎动物中发育过程中,卵母细胞要经历MII期停滞、受精、早期胚胎发育的启动、胚胎基因组的转录激活、并指导完成个体的发育过程。同时,核移植过程中,分化的细胞核在去核的卵母细胞中能够重编程到胚胎早期的状态并能完成个体的发育过程。在这些发育过程中母源因子都发挥了极其的重要作用。在小鼠胚胎发育研究中发现,小鼠的基因组激活发生在2细胞期,这一时期标志着合子的发育由卵母细胞控制向胚胎控制的过渡,期间发生一系列复杂的生化过程。体外培养的小鼠的胚胎的发育阻断也易发生的2细胞时期。因此对卵母细胞及早期胚胎母源因子的研究,将有利于了解早期体外培养胚胎和克隆胚胎发育失败的原因,为提高体外培养和克隆胚胎发育的成功率提供理论的基础。     

秋水仙碱对微管蛋白的作用机制及其细胞效应研究进展

秋水仙碱诱导染色体同源加倍的生物学机理与构成纺锤体微管蛋白密切相关. 秋水仙碱作用于细胞的根本效应是改变细胞微管的状态,使微管解聚或停止组装;秋水仙碱作用于微管的方式是其分子结构中的 A 环与β微管蛋白354半胱氨酸结合、C环结合在239半胱氨酸和N末端氨基酸;不同植物种类微管蛋白的处理效应有明显的差异.秋水仙碱的处理效应影响到细胞一切与微管活动有关的功能,具体表现为改变细胞的发育进程、阻断染色体的分裂及细胞器不能正常运动,除此之外,秋水仙碱还可以诱导染色体结构变异.本文主要综述了秋水仙碱作用于微管蛋白的机制及秋水仙碱处理的细胞效应等研究进展,为该领域的研究提供信息资料.     

蕨类植物精细胞运动器和细胞骨架的研究

介绍了近年来蕨类植物游动精子运动器和细胞骨架的研究进展.游动精子由配子体精子器中的非运动细胞发育形成,其分化过程包括了运动器官和细胞骨架的合成和组装.精子发生过程中形成的运动器的各部分结构包括鞭毛、基体、多层结构及附属结构;基体是细胞中新形成的结构,在不同类群的蕨类植物中分别由双中心粒、分支生毛体和生毛体产生.鞭毛、基体和多层结构中的微管带形成了游动精子三个独特的微管列阵,由于微管蛋白的后修饰作用这些微管列阵十分稳定;centrin是运动器中的重要成分,但功能尚不清楚,可能和细胞骨架及运动器的构建有关.     

钙调蛋白依赖的蛋白激酶Ⅱ在卵母细胞减数分裂和受精中的作用

钙调蛋白依赖的蛋白激酶 (CaMK)是一类分布广泛的丝 /苏氨酸蛋白激酶家族 ,在钙离子和钙调蛋白存在的条件下发生自磷酸化而被激活 ,在细胞内对于钙信号的传递具有重要的介导作用 .近年来的研究表明CaMKⅡ是参与调节卵母细胞减数分裂的重要分子 ,在卵母细胞成熟、极体排放、受精和活化等过程中发挥作用 .CaMKⅡ作为Ca2 的下游信号分子 ,在受精后促进成熟促进因子 (MPF)和细胞静止因子 (CSF)的失活 ,并调节纺锤体微管的组装和中心体的复制过程 .虽然CaMKⅡ在减数分裂中的作用广泛而关键 ,但目前的研究主要集中于低等动物和小鼠 ,今后有待进一步阐明该蛋白激酶在其他哺乳动物中的作用和调节机制     

外源中心体在哺乳动物胚胎发育中的遗传机制

中心体是一个非膜包被的半保留细胞器,由一对相互垂直的圆柱形中心粒及其周围大量的高电子密度的蛋白质-中心体基质(pericentriolar material,PCM)组成.在所有哺乳动物细胞中,中心体(centrosome)作为主要的微管组织中心(microtubule organizing centers,MTOCs),起到组装和稳定微管的关键功能.在大多数哺乳动物精子形成过程中,精子保留了近端中心粒,失去了大部分的中心体旁蛋白和远端中心粒,而在卵母细胞形成过程中两个中心粒被逐渐降解,主要的中心体旁蛋白被保留了下来,弥散于卵胞质中.受精后,在卵母细胞中精子中心粒被进一步降解,来源于卵母细胞和精子的中心体旁蛋白形成受精卵的MTOCs在胚胎分裂过程中行使功能.但在小鼠等啮齿类动物精子形成过程中,两个中心粒全部被降解,因此受精卵中的MTOCs主要由来源于卵母细胞中心体旁蛋白组成.在大多数哺乳动物核移植胚胎中.外源中心粒在胚胎1-细胞期即被降解,而是来源于供体细胞和受体卵母细胞的中心体旁蛋白形成重构胚的MTOCs指导纺锤体形成,中心粒是在囊胚期才从头合成的.在灵长类中,来源于精子的中心粒能与PCM一起组成典型的中心体在胚胎分裂过程中行使功能,但在其核移植胚胎中,体细胞中心体和去核卵母细胞中剩余的中心体旁蛋白不能有效的组装形成功能性中心体,这可能是灵长类哺乳动物体细胞克隆失败的一个关键原因. 成过程中,两个中心粒全部被降解,因此受精卵中的MTOCs主要由来源于卵母细胞中心体旁蛋白组成.在大多数哺乳动物核移植胚胎中.外源中心粒在胚胎1-细胞期即被降解,而是来源于供体细胞和受体卵母细胞的中心体旁蛋白形成重构胚的MTOCs指导纺锤体形成,中心粒是在囊胚期才从头合成的.在灵长类中,来源于精子的中心粒能与PCM一起组成典型的中心 在胚胎分裂过程中行使功能,但在其核移植胚胎中,体细胞中心体和去核卵母细胞中剩余的中心体旁蛋白不能有效的组装形成功能性中心体,这可能是灵长类哺乳动物体细胞克隆失败的一个关键原因. 成过程中,两个中心粒全部被降解,因此受精卵中的MTOCs主要由来源于卵母细胞中心体旁蛋白组成.在大多数哺乳动物核移植胚胎中.外源中心粒在胚胎1-细胞期即被降解,而是来源于供体细胞和受体卵母细胞的中心体旁蛋白形成重构胚的MTOCs指导纺锤体形成,中心粒是在囊胚期才从头合成的.在灵长类中,来源于精子的中心粒能与PCM一起组成典型的中心 在胚胎分裂过程中行使功能,但在其核移植胚胎中,体细胞中心体和去核卵母细胞中剩余的中心体旁蛋白不能有效的组     

Differential effect of recipient cytoplasm for microtubule organization and preimplantation development in rat reconstituted embryos with two-cell embryonic cell nuclear transfer

In the present study, we examined the developmental ability of enucleated zygotes, MII oocytes, and parthenogenetically activated oocytes at pronuclear stages (parthenogenetic PNs) as recipient cytoplasm for rat embryonic cell nuclear transfer. Enucleated zygotes as recipient cytoplasm receiving two-cell nuclei allowed development to blastocysts, whereas the development of embryos reconstituted with MII oocytes and parthenogenetic PNs was arrested at the two-cell stage. Previous observations in rat two-cell embryos suggested that the distribution of microtubules is involved in two-cell arrest. Therefore, we also examined the distribution of microtubules using immunofluorescence. At the two-cell stage after nuclear transfer into enucleated zygotes, microtubules were distributed homogeneously in the cytoplasm during interphase, and normal mitotic spindles were observed in cleaving embryos from the two- to four-cell stage. In contrast, embryos reconstituted with MII oocytes and parthenogenetic PNs showed aberrant microtubule organization. In enucleated zygotes, fibrous microtubules were distributed homogeneously in the cytoplasm. In contrast, dense microtubules were localized at the subcortical area in the cytoplasm and strong immunofluorescence intensity was observed at the plasma membrane, while very weak intensity was detected in the central part of enucleated MII oocytes. In enucleated parthenogenetic PNs, high-density and fibrous microtubules were distributed in the subcortical and central areas, respectively. Pre-enucleated parthenogenetic PNs also showed lower intensity of microtubule immunofluorescence in the central cytoplasm than zygotes. In conclusion, the results of the present study showed that zygote cytoplasm is better as recipient than MII oocyte and parthenogenetic PNs for rat two-cell embryonic cell nuclear transfer to develop beyond four-cell stage. Furthermore, microtubule organization is involved in the development of reconstituted embryos to overcome the two-cell arrest.     

Development of parthenogenetic rat embryos

In an effort to establish cloning technology for the rat, we tested several methods (electric stimulation, treatment with ethanol or strontium) for the parthenogenetic activation of rat oocytes. We observed marked individual differences among rats of the outbred Wistar strain in their ability to yield activatable oocytes. These differences were independent of the activation protocol and may be due to a genetic predisposition that is crucial for the parthenogenetic activation of oocytes. The activation of oocytes was dependent upon the time between superovulation of the donor animal and the collection of the embryos. Aged oocytes (derived about 24 h after superovulation) were more prone to activation by each method than were younger oocytes, and some even underwent spontaneous activation without treatment and exhibited pronuclear formation and blastocyst development. All activation methods were effective in generating parthenogenetic rat embryos, and rat parthenotes developed until implantation. However, in general, short-term (15 min) and long-term (2 h) strontium treatment was superior to stimulation by ethanol or electric pulse for parthenogenetic activation. These results will be helpful in achieving successful cloning in the rat.     

Ultrastructural analysis of abnormalities in the morphology of the second meiotic spindle in ethanol-induced parthenogenones

A high frequency of parthenogenetic activation occurs when ovulated mouse oocytes are briefly exposed to a dilute solution of ethanol in vitro. Cytogenetic analyses of parthenogenones at metaphase of the first cleavage division have confirmed that parthenogenetic activation, per se, does not increase the incidence of chromosome segregation errors during the completion of the second meiotic division. Ethanol-induced activation, however, significantly increases the incidence of aneuploidy. The ultrastructural changes that occur in the morphology and organization of the second meiotic spindle apparatus in ethanol- and hyaluronidase-activated oocytes is reported here. Abnormalities in the arrangement of microtubule arrays and chromosome position were principally observed in ethanol-activated oocytes at anaphase and telophase of the second meiotic division, but were only rarely observed in hyaluronidase-activated oocytes. It is proposed that the abnormalities in spindle morphology and chromosome displacement observed in ethanol-activated oocytes represent the initial events that lead to chromosome segregation errors following exposure to this agent.     

Leptin accelerates pronuclear formation following intracytoplasmic sperm injection of porcine oocytes: Possible role for MAP kinase inactivation

Leptin, a multifunctional hormone, is present in mammalian oocytes and follicular fluids and cumulus cells. While leptin modulates oocyte maturation in vitro which seems to result in enhancement of embryo development, it is unclear whether leptin treatment of oocytes affects cytoplasmic maturation and fertilization processes. In order to gain a better understanding of the role of leptin during oocyte maturation, we examined microtubule and microfilament assembly following oocyte maturation and blastocyst formation, mitogen-activated protein kinase (MAPK) activity, and pronuclear formation following parthenogenetic stimuli or intracytoplasmic sperm injection (ICSI) in leptin-treated oocytes. Addition of 10 or 100 ng/ml leptin during oocyte maturation did not increase the proportion of metaphase II oocytes, but enhanced development to blastocyst stage by day 7 (P < 0.01) after parthenogenetic activation (PA), accompanied by increased cell number. However there was no effect on the number of apoptotic cells in blastocysts. Following maturation in the presence of leptin, there were more oocytes with normal spindle formation. MAPK activity decreased more rapidly, and pronuclear formation was accelerated after parthenogenetic activation or ICSI of leptin-treated oocytes. These results suggested that exogeneous leptin enhanced spindle assembly and accelerated pronuclear formation following fertilization, possibly via the MAPK pathway.     

Involvement of mitogen-activated protein kinase cascade during oocyte maturation and fertilization in mammals

Mitogen-activated protein kinase (MAPK) is a family of Ser/Thr protein kinases that are widely distributed in eukaryotic cells. Studies in the last decade revealed that MAPK cascade plays pivotal roles in regulating the meiotic cell cycle progression of oocytes. In mammalian species, activation of MAPK in cumulus cells is necessary for gonadotropin-induced meiotic resumption of oocytes, while MAPK activation is not required for spontaneous meiotic resumption. After germinal vesicle breakdown (GVBD), MAPK is involved in the regulation of microtubule organization and meiotic spindle assembly. The activation of this kinase is essential for the maintenance of metaphase II arrest, while its inactivation is a prerequisite for pronuclear formation after fertilization or parthenogenetic activation. MAPK cascade interacts extensively with other protein kinases such as maturation-promoting factor, protein kinase A, protein kinase C, and calmodulin-dependent protein kinase II, as well as with protein phosphatases in oocyte meiotic cell cycle regulation. The cross talk between MAPK cascade and other protein kinases is discussed. The review also addresses unsolved problems and discusses future directions.     

Parthenogenetic activation and subsequent development of rat oocytes in vitro.

Studies were undertaken to determine whether electrical stimulation, or ethanol treatment alone or in combination with 6-dimethylaminopurine (6-DMAP) influenced the rate of parthenogenetic activation of rat oocytes. The percentages of activated oocytes with pronuclei (89-91%) and those developed to the two-cell stage (68-72%) were significantly higher after electrical stimulation with direct current (DC) at 100 V/mm, 99 microsec once or twice, than when other DC voltages (75, 150, and 200) were applied or when ethanol or 6-DMAP treatment was given alone. However, none of the activated oocytes developed beyond the four-cell stage. The percentages of activated oocytes with pronuclei (100%) that developed to the two-cell (100%), eight-cell (89%) and blastocyst stages (50%) were significantly higher when electrical stimulation was followed by treatment with 2 mM 6-DMAP for 4 hr than when other combined procedures were applied. In conclusion, the results of the present study clearly showed that combined treatment of electrical stimulation or ethanol with 6-DMAP induces parthenogenetic activation and subsequent development of rat oocytes in vitro.     

Parthenogenetic activation pattern and microtubular organization of the mouse oocyte after exposure to 1,2-propanediol.

We have studied the effect of 1,2-propanediol (PROH) on cumulus-oocyte complexes from the mouse. We determined the morphological survival rate, the pattern of parthenogenetic activation, and the microtubular and chromosomal organization. Cumulus-oocyte complexes were collected at 16 h post hCG from superovulated female hybrid mice. These cumulus-intact oocytes were exposed to 1.5 or 3 M PROH for 6, 12, or 18 min at 0, 22, or 37 degrees C. The cryoprotectant was diluted out in a 1 M sucrose solution at 22 degrees C. After 5-6 h at 37 degrees C, oocytes were denuded and examined under Nomarski optics. The results show that PROH can induce degeneration and parthenogenetic activation in the mouse oocyte in a concentration, temperature, and time-dependent way. As the activation stimulus was strengthened, an increasing proportion of oocytes shifted from parthenogenetic activation with polar body extrusion to parthenogenetic activation with polar body retention and even to immediate cleavage. Nontoxic and nonactivating conditions involved mainly exposure to 1.5 M PROH at 0 degrees C. Spindle integrity and chromosomal organization were analyzed for exposure to 1.5 and 3 M PROH for 12 min at 0 degrees C. The separate effect of cooling and exposure to 1 M sucrose were also evaluated. Microtubules were visualized by monoclonal anti-alpha-tubulin labeling followed by immunogold-silver staining. Cooling and exposure to 1 M sucrose or to 1.5 M PROH did not induce major abnormalities in the microtubular or chromosomal organization. On the other hand, a significant percentage of deformities such as spindle size reduction and loss of bipolarity were observed after exposure to 3 M PROH. The results of the present study demonstrate that the use of PROH as a single cryoprotectant for the freezing of mature unfertilized oocytes cannot be recommended in procedures involving ambient temperature or concentrations exceeding 1.5 M PROH. On the other hand, the potential beneficial effect of low temperatures may outweigh the effect of concentration at subzero temperatures and could be explored further in the tailoring of conditions for slow controlled freezing.