高中生物电化教学一例

一、课题:减数分裂与有性生殖细胞的成熟二、教材分析:凡是进行有性生殖的动植物,在从原始的生殖细胞发展到成熟的生殖细胞的过程中,都要进行减数分裂。减数分裂是细胞连续分裂两次,而染色体在整个过程中只复制一次的特殊方式的有丝分裂。分裂结果,细胞中的染色体数目比原来的减少了一半。教材结合动物的精子和卵细胞的形成过程,比较详细地讲述了减数分裂的基本过程。由于减数分裂是研究肉眼看不见,     

减数分裂型黏连蛋白RAD21L的作用机制

减数分裂是在有性生殖过程中高度专业化的真核细胞分裂。在减数分裂过程中,DNA复制一次,细胞连续分裂两次,子细胞染色体数目减半。在减数第一次分裂过程中为确保同源染色体正确分离,必须通过同源染色体配对、联会及重组等减数分裂特异性染色体运动。如果其中任一运动发生异常会导致先天性疾病或不孕不育症。因此,了解这些减数分裂型染色体的运动机制极为重要。该综述重点探讨了减数分裂型黏连蛋白RAD21L的特殊作用及其在哺乳动物减数分裂过程中对染色体运动的调控机制。     

山羊卵母细胞体外成熟过程中线粒体的动态分布

目的研究山羊卵母细胞减数分裂过程中线粒体的动态分布。方法收集山羊卵母细胞,在M199中分别培养4、8、12、16、20和24 h,用特异性线粒体标记探针进行标记,用激光扫描共聚焦显微镜观察线粒体的分布情况。结果生发泡期线粒体多分散在卵母细胞的胞质内,并且距生发泡有一定的距离;生发泡破裂期线粒体逐渐移向染色质;第一次减数分裂中期与第二次减数分裂中期线粒体成簇密布在染色体周围。排出的第一极体中也含有大量的线粒体。结论同其他哺乳动物卵母细胞体外成熟过程中线粒体分布情况相比,线粒体在山羊卵母细胞中的分布具有明显的相似性。线粒体密布在成熟卵母细胞染色体周围可能与极体的排出和受精后染色体的迁移有关。     

去甲斑蝥酸钠对小鼠卵母细胞第一次减数分裂的影响

体外培养的小鼠卵母细胞在１２ｈ内可完成第一次减数分裂,排出第一极体。将卵母细胞培养在含２５０μｇ／ｍｌ去甲斑蝥酸钠的培养液中,生发泡破裂（ＧＶＢＤ）过程不受影响,但卵母细胞不能完成减数分裂过程,卵母细胞中没有减数分裂器的形成,染色体紧密凝缩在一起;去甲斑蝥酸钠对小鼠卵母细胞减数分裂的影响在６ｈ内具有可逆性：卵母细胞ＧＶ破裂后用去甲斑蝥酸钠处理２ｈ换正常培养液培养,整个减数分裂过程不受影响;ＧＶ期卵母细胞用去甲斑蝥酸钠连续处理６ｈ,洗去药物继续培养,减数分裂可继续进行,但第一极体的排放时间推迟。去甲斑蝥酸钠对分裂期细胞特异性磷蛋白的出现影响不显著,在连续处理的卵母细胞中分裂期细胞特异性磷蛋白仍然存在。     

“减数分裂”教学的重要性及建议

(一)减数分裂与细胞学、遗传学的关系现行《生物》课本中“减数分裂与生殖细胞的成熟”一节教材是全书中重要的一节,减数分裂是一种特殊的有丝分裂。在减数分裂过程中细胞经过连续两次分裂,而染色体只复制一次,结果使性细胞中染色体数目减半。性细胞再经受精作用形成合子,合子中染色体数目又恢复到亲代体细胞中染色体数目,从而使亲子代细胞中的遗传物质保持相对稳定。减数分裂的前期I,细胞中的染色体发生了一系列特殊的变化——同源染色体联会、交叉互换和分离。每一对同源染色体中的两条染色体彼此分离,以后随机地分配到二个子细胞中去;异源染色体     

卵母细胞在哺乳动物卵巢排卵过程中的决定性作用

哺乳动物卵巢排卵是一个复杂的调控过程。卵泡成熟破裂后,卵母细胞从卵巢中排出。卵泡细胞感受排卵刺激,并诱导卵母细胞减数分裂的恢复及其随后的释放。卵母细胞及其周围颗粒细胞的旁分泌在对此起关键性作用,其中卵母细胞对其释放具有决定性作用。作者先前已经阐述过颗粒细胞在哺乳动物卵巢排卵过程中的调控作用,该文将从卵母细胞的发育及其调控角度重点阐明其在排卵过程中的决定作用,旨在进一步理解哺乳动物卵巢的排卵过程,同时为不孕不育等卵巢疾病的治疗提供重要的研究方向和理论基础。     

绵羊卵泡成分对卵母细胞体外减数分裂调控的研究

哺乳动物卵巢中的卵母细胞一直处于减数分裂的停滞状态,卵泡内各成分被认为是产生抑制因子的主要来源。本研究以绵羊卵泡各成分为研究对象,用共培养的方法对卵丘细胞、颗粒细胞、膜细胞在卵母细胞体外减数分裂过程中的作用加以探讨。结果表明：1．卵泡整体及卵泡分泌物在体外可以有效地维持减数分裂停滞,经过24h培养,这两个处理组中,处于GV期的卵母细胞分别为69．6％和49．1％。经抑制处理后的卵母细胞脱离抑制环境后可以继发成熟,MⅡ比率可达88．9％。去掉卵丘细胞的裸卵其减数分裂过程不能被卵泡分泌物有效抑制,24h培养后其GV期比例为17．8％。以上结果说明卵泡中的抑制因子主要是通过卵丘细胞束发挥其调控作用的。2．用颗粒细胞与卵母细胞共培养,结果发现具有颗粒细胞卵丘细胞缝隙连接的卵母细胞(COCGs)在培养24小时后47．4％达到MⅡ,与在不具有细胞连接的总浮颗粒细胞中共培养的卵母细胞之间存在无显差异,无论是紧密连接的颗粒细胞层还是悬浮在培养液中的颗粒细胞都不能有效抑制生发泡破裂(GVBD)的发生,只能将卵母细胞抑制在MⅡ以前的各个时期。以上结果说明颗粒细胞在体外分泌抑制图子的活力大大下降。3．卵泡膜细胞具有分泌抑制成熟分裂因子的能力,与膜细胞层共培养的卵母细胞在8h和24h时,其GV期的比例为34．4％和32．7％,显高于没有膜细胞层的对照组(4．5％和1.1％)。综上所述,绵羊卵泡中的抑制因子不仅来自于颗粒细胞,而且膜细胞也参与了成熟分裂的抑制,这些细胞在体外仍具有分泌抑制因子的能力,只是与体内分泌能力有所不同。     

细胞不对称分裂

细胞不对称分裂是多细胞生物发育的基础。细胞不对称分裂的重要特征是细胞命运决定子在细胞分裂期间的不对称分离。细胞不对称分裂一般要经历4个步骤：在细胞中建立一个极性轴;沿此轴定向并形成纺锤体;细胞命运决定子沿极性轴作极性分布;细胞分裂后,不同的细胞命运决定子指导决定细胞的不同命运。     

小鼠卵母细胞减数分裂染色体的制备

PreparationofMeioticKarytypeofMouseOocyteLiChaojunYanLeipingZhangXiranChenYifeng(BiologyDepartmentofNanjingNormalUniversity,Nanjing210097)哺乳动物的卵母细胞的减数分裂过程中存在两次自发的停滞现象,第一次是在第一次减数分裂前期的双线期,这一静止期持续很长时间,一直到动物性成熟后卵母细胞进入发有周刎,在保住腺激素的作用下,卵母细胞的第一次减数分裂才重新启动．完成第一次减数分裂后．又停滞在第二次减数分裂的中期,在椅子或化学因素刺激的作用下,完成第二次减数分裂[4]．因此,对哺乳动物的卵母细胞在一…     

硬骨鱼类卵母细胞最终成熟机制的研究进展

在硬骨鱼类中,发育完全的未成熟的卵母细胞被阻滞在第一次减数分裂前期,这一时期也称为生发泡期。性成熟后,当卵母细胞受到促黄体生成素及其他内分泌、自分泌/旁分泌因子的调节,可突破第一次减数分裂阻滞,发生生发泡破裂,这标志着卵母细胞恢复了第一次减数分裂。这一过程被既复杂又严格精密的机制所调控,对产生可受精的雌配子尤为关键。明确卵母细胞成熟分裂进程中的调控因子及各因子之间直接或间接地相互作用是目前研究的热门领域,但是关于这些机制的研究主要集中于哺乳动物,在硬骨鱼类中的研究相对较少且分散。因此,本研究综述了近年来国内外硬骨鱼类卵母细胞最终成熟过程调控机制及研究进展;以第一次减数分裂的阻滞和第一次减数分裂的恢复两条主线,重点分析总结了17β-雌二醇、环磷酸腺苷、胰岛素样生长因子、丝裂原活化蛋白激酶等调控因子及它们与上游调节因子和下游作用底物构成的信号网络对此过程的调控。本综述为研究硬骨鱼类卵母细胞的最终成熟机制提供理论支持与参考。     

The spatial and mechanical challenges of female meiosis

Recent work shows that cytokinesis and other cellular morphogenesis events are tuned by an interplay among biochemical signals, cell shape, and cellular mechanics. In cytokinesis, this includes cross-talk between the cortical cytoskeleton and the mitotic spindle in coordination with cell cycle control, resulting in characteristic changes in cellular morphology and mechanics through metaphase and cytokinesis. The changes in cellular mechanics affect not just overall cell shape, but also mitotic spindle morphology and function. This review will address how these principles apply to oocytes undergoing the asymmetric cell divisions of meiosis I and II. The biochemical signals that regulate cell cycle timing during meiotic maturation and egg activation are crucial for temporal control of meiosis. Spatial control of the meiotic divisions is also important, ensuring that the chromosomes are segregated evenly and that meiotic division is clearly asymmetric, yielding two daughter cells - oocyte and polar body - with enormous volume differences. In contrast to mitotic cells, the oocyte does not undergo overt changes in cell shape with its progression through meiosis, but instead maintains a relatively round morphology with the exception of very localized changes at the time of polar body emission. Placement of the metaphase-I and -II spindles at the oocyte periphery is clearly important for normal polar body emission, although this is likely not the only control element. Here, consideration is given to how cellular mechanics could contribute to successful mammalian female meiosis, ultimately affecting egg quality and competence to form a healthy embryo.     

Specific deletion of Cdc42 does not affect meiotic spindle organization/migration and homologous chromosome segregation but disrupts polarity establishment and cytokinesis in mouse oocytes

Mammalian oocyte maturation is distinguished by highly asymmetric meiotic divisions during which a haploid female gamete is produced and almost all the cytoplasm is maintained in the egg for embryo development. Actin-dependent meiosis I spindle positioning to the cortex induces the formation of a polarized actin cap and oocyte polarity, and it determines asymmetric divisions resulting in two polar bodies. Here we investigate the functions of Cdc42 in oocyte meiotic maturation by oocyte-specific deletion of Cdc42 through Cre-loxP conditional knockout technology. We find that Cdc42 deletion causes female infertility in mice. Cdc42 deletion has little effect on meiotic spindle organization and migration to the cortex but inhibits polar body emission, although homologous chromosome segregation occurs. The failure of cytokinesis is due to the loss of polarized Arp2/3 accumulation and actin cap formation; thus the defective contract ring. In addition, we correlate active Cdc42 dynamics with its function during polar body emission and find a relationship between Cdc42 and polarity, as well as polar body emission, in mouse oocytes.     

Cortical Mechanics and Meiosis II Completion in Mammalian Oocytes Are Mediated by Myosin-II and Ezrin-Radixin-Moesin (ERM) Proteins

Cell division is inherently mechanical, with cell mechanics being a critical determinant governing the cell shape changes that accompany progression through the cell cycle. The mechanical properties of symmetrically dividing mitotic cells have been well characterized, whereas the contribution of cellular mechanics to the strikingly asymmetric divisions of female meiosis is very poorly understood. Progression of the mammalian oocyte through meiosis involves remodeling of the cortex and proper orientation of the meiotic spindle, and thus we hypothesized that cortical tension and stiffness would change through meiotic maturation and fertilization to facilitate and/or direct cellular remodeling. This work shows that tension in mouse oocytes drops about sixfold during meiotic maturation from prophase I to metaphase II and then increases ∼1.6-fold upon fertilization. The metaphase II egg is polarized, with tension differing ∼2.5-fold between the cortex over the meiotic spindle and the opposite cortex, suggesting that meiotic maturation is accompanied by assembly of a cortical domain with stiffer mechanics as part of the process to achieve asymmetric cytokinesis. We further demonstrate that actin, myosin-II, and the ERM (Ezrin/Radixin/Moesin) family of proteins are enriched in complementary cortical domains and mediate cellular mechanics in mammalian eggs. Manipulation of actin, myosin-II, and ERM function alters tension levels and also is associated with dramatic spindle abnormalities with completion of meiosis II after fertilization. Thus, myosin-II and ERM proteins modulate mechanical properties in oocytes, contributing to cell polarity and to completion of meiosis.     

Centriolin,a centriole-appendage protein,regulates peripheral spindle migration and asymmetric division in mouse meiotic oocytes

Unlike somatic cells mitosis, germ cell meiosis consists of 2 consecutive rounds of division that segregate homologous chromosomes and sister chromatids, respectively. The meiotic oocyte is characterized by an absence of centrioles and asymmetric division. Centriolin is a relatively novel centriolar protein that functions in mitotic cell cycle progression and cytokinesis. Here, we explored the function of centriolin in meiosis and showed that it is localized to meiotic spindles and concentrated at the spindle poles and midbody during oocyte meiotic maturation. Unexpectedly, knockdown of centriolin in oocytes with either siRNA or Morpholino micro-injection, did not affect meiotic spindle organization, cell cycle progression, or cytokinesis (as indicated by polar body emission), but led to a failure of peripheral meiotic spindle migration, large polar body emission, and 2-cell like oocytes. These data suggest that, unlike in mitotic cells, the centriolar protein centriolin does not regulate cytokinesis, but plays an important role in regulating asymmetric division of meiotic oocytes.     

Egg maturation and parthenogenetic recovery of diploidy in the scorpion Liocheles australasiae (Fabricius) (Scorpions, ischnuridae)

In the scorpion Liocheles australasiae, egg maturation and parthenogenetic recoveries of chromosome number and nuclear DNA content were examined by histological, karyological observations and quantitative measurements of DNA. The primary oocyte becomes mature through two successive maturation divisions. The first maturation division takes place in the primary oocyte to produce a secondary oocyte and a first polar body. The second maturation division soon occurs in the secondary oocyte, in which the nucleus is divided into a mature egg nucleus and a second polar body nucleus, not followed by cytoplasmic fission. The first polar body, in one case, was successively divided into two second polar bodies; in the other case it was not divided. In either case, these polar bodies remained attached to the early embryo. The fate of these polar bodies during further embryogenesis were studied. In the karyological analysis, the chromosome number was divided into two groups, one from 27-32, the other was 54-64. The former was presumably the metaphase chromosome number at the meiotic division; the latter was presumably the metaphase chromosome number at the mitotic division. DNA content in the diploid nucleus of the primary oocyte, doubled before the maturation divisions, was reduced through the maturation divisions by one-half in the nuclei of the secondary oocyte and the first polar body and by one-fourth in the nuclei of the egg and the second polar bodies. The first reduction of DNA content corresponded to halving the number of the chromosomes in the first maturation division and the second to the nuclear division in the secondary oocyte. These reductions represent a common process of egg maturation, except the final production of the mature egg with two haploid nuclei, an egg nucleus, and a second polar body nucleus. These two nuclei, which were formed apart in the mature egg, drew near to fuse into a zygote nucleus. The chromosome number and nuclear DNA content were doubled in the zygote and each blastomere in embryos, supporting the hypothesis that the egg nucleus fuses with the second polar body nucleus and this conjugation initiates subsequent embryonic development.     

Centriole behavior during meiosis in oocytes of the sea urchin Hemicentrotus pulcherrimus

Ultrastructural changes in the maturing oocyte of the sea urchin Hemicentrotus pulcherrimus were observed, with special reference to the behavior of centrioles and chromosomes, using oocytes that had spontaneously started the maturation division process in vitro after dissection from ovaries. The proportion of oocytes entering the maturation process differed from batch to batch. In those eggs that accomplished the maturation division, it took ~4.5-5 h from the beginning of germinal vesicle breakdown to the formation of a second polar body. Serial sections revealed that a young oocyte before germinal vesicle breakdown had a pair of centrioles with procentrioles, located between the presumed animal pole and the germinal vesicle and accompanied by amorphous aggregates of moderately dense material and dense granules (granular aggregate). Just before germinal vesicle breakdown, a pair of fully grown centrioles located in the granular aggregate, which is present until this stage and then disappears, had already separated from another pair of centrioles. In meiosis I, each division pole had two centrioles, whereas in meiosis II each had only one. The two centrioles in the secondary oocyte separated into single units and formed the mitotic figure of meiosis II. The first polar body had two centrioles and the second had only one. The two centrioles in the first polar body did not form the mitotic figure nor did they separate at the time of meiosis II. These results indicate that, in sea urchins, duplication of the centrioles does not occur during the two successive meiotic divisions and the egg inherits only one centriole from the primary oocyte, confirming the results previously reported for starfish oocytes.     

Small GTPase RhoA regulates cytoskeleton dynamics during porcine oocyte maturation and early embryo development

Mammalian oocyte maturation is distinguished by asymmetric division that is regulated primarily by cytoskeleton, including microtubules and microfilaments. Small Rho GTPase RhoA is a key regulator of cytoskeletal organization which regulates cell polarity, migration, and division. In this study, we investigated the roles of RhoA in mammalian oocyte meiosis and early embryo cleavage. (1) Disrupting RhoA activity or knock down the expression of RhoA caused the failure of polar body emission. This may have been due to decreased actin assembly and subsequent spindle migration defects. The involvement of RhoA in this process may have been though its regulation of actin nucleators ROCK, p-Cofilin, and ARP2 expression. (2) In addition, spindle morphology was also disrupted and p-MAPK expression decreased in RhoA inhibited or RhoA KD oocytes, which indicated that RhoA also regulated MAPK phosphorylation for spindle formation. (3) Porcine embryo development was also suppressed by inhibiting RhoA activity. Two nuclei were observed in one blastomere, and actin expression was reduced, which indicated that RhoA regulated actin-based cytokinesis of porcine embryo. Thus, our results demonstrated indispensable roles for RhoA in regulating porcine oocyte meiosis and cleavage during early embryo development.     

Anillin localization suggests distinct mechanisms of division plane specification in mouse oogenic meiosis I and II

Anillin is a conserved cytokinetic ring protein implicated in actomyosin cytoskeletal organization and cytoskeletal-membrane linkage. Here we explored anillin localization in the highly asymmetric divisions of the mouse oocyte that lead to the extrusion of two polar bodies. The purposes of polar body extrusion are to reduce the chromosome complement within the egg to haploid, and to retain the majority of the egg cytoplasm for embryonic development. Anillin's proposed roles in cytokinetic ring organization suggest that it plays important roles in achieving this asymmetric division. We report that during meiotic maturation, anillin mRNA is expressed and protein levels steadily rise. In meiosis I, anillin localizes to a cortical cap overlying metaphase I spindles, and a broad ring over anaphase spindles that are perpendicular to the cortex. Anillin is excluded from the cortex of the prospective first polar body, and highly enriched in the cytokinetic ring that severs the polar body from the oocyte. In meiosis II, anillin is enriched in a cortical stripe precisely coincident with and overlying the meiotic spindle midzone. These results suggest a model in which this cortical structure contributes to spindle re-alignment in meiosis II. Thus, localization of anillin as a conserved cytokinetic ring marker illustrates that the geometry of the cytokinetic ring is distinct between the two oogenic meiotic cytokineses in mammals.     

Small Molecule Inhibitor of Formin Homology 2 Domains (SMIFH2) Reveals the Roles of the Formin Family of Proteins in Spindle Assembly and Asymmetric Division in Mouse Oocytes

Dynamic actin reorganization is the main driving force for spindle migration and asymmetric cell division in mammalian oocytes. It has been reported that various actin nucleators including Formin-2 are involved in the polarization of the spindle and in asymmetric cell division. In mammals, the formin family is comprised of 15 proteins. However, their individual roles in spindle migration and/or asymmetric division have not been elucidated yet. In this study, we employed a newly developed inhibitor for formin family proteins, small molecule inhibitor of formin homology 2 domains (SMIFH2), to assess the functions of the formin family in mouse oocyte maturation. Treatment with SMIFH2 during in vitro maturation of mouse oocytes inhibited maturation by decreasing cytoplasmic and cortical actin levels. In addition, treatment with SMIFH2, especially at higher concentrations (500 μM), impaired the proper formation of meiotic spindles, indicating that formins play a role in meiotic spindle formation. Knockdown of the mDia2 formins caused a similar decrease in oocyte maturation and abnormal spindle morphology, mimicking the phenotype of SMIFH2-treated cells. Collectively, these results suggested that besides Formin-2, the other proteins of the formin, including mDia family play a role in asymmetric division and meiotic spindle formation in mammalian oocytes.