供体细胞的选择与动物克隆效率研究进展

哺乳动物体细胞克隆经过几年的发展,已取得了很大进展.已有多种细胞被采用并得到了克隆后代.但动物克隆效率仍然很低,供体细胞的选择是动物克隆中的重要步骤.供体细胞的细胞周期、细胞类型、细胞来源和分化程度等方面都可能影响动物克隆的效率.     

哺乳动物体细胞核移植中供体细胞的研究进展

在哺乳动物体细胞核移植中,供体细胞是影响其效率的主要因素之一。供体细胞的类型、细胞周期、细胞的培养代数、冷藏与冷冻处理,以及供体动物的性别、年龄等都可能影响核移植胚胎的发育。根据现有资料,简要综述了在哺乳动物体细胞核移植中有关供体细胞的研究进展。     

体细胞核移植胚胎核重编程的研究进展

尽管在多种哺乳动物种系中成功制备了体细胞克隆后代,但当前的克隆技术仍有许多亟待解决的问题。体细胞核移植胚胎大多存在许多发育异常,造成了妊娠早期高流产率和出生后高死亡率。有研究认为,克隆胚胎发育障碍的一个重要的原因是供体细胞的遗传重编程不完全。哺乳动物种系中,DNA甲基化是胚胎发育期转录调节的必需步骤,除了单拷贝基因序列外,在基因组很多的区域都可以观测到克隆胚胎的异常甲基化。此外,克隆胚胎的基因印迹也存在异常。     

供体细胞与哺乳动物体细胞核移植

哺乳动物体细胞核移植(克隆)技术在转基因动物生产、珍稀动物资源复原与保护、生物学基础研究等方面业已显示出重要的应用价值,而目前该技术还与诱导多能干细胞技术一同被认为是创制患者特异性多能干细胞,为再生医学临床"细胞治疗"提供素材的最佳手段。但是,体细胞克隆的效率仍不理想,关键机制还不清楚,严重制约了该技术的推广。因此,如何提高克隆效率已成为人们普遍关心的首要问题。在体细胞克隆技术所涉及的各环节中,供体细胞是影响克隆效率的最关键因素之一。该文从供体细胞的生物学因素和技术因素两方面进行了回顾,旨在为进一步探寻建立物种或供体细胞个性化准备方案,为提高动物克隆效率提供参考。     

哺乳动物体细胞克隆及在动物转基因中的应用

哺乳动物体细胞克隆及转基因技术,近些年发展迅速。尤其1997年‘多利’羊的诞生,对推动哺乳动物克隆及转基因技术的发展具有里程碑式的意义。本文介绍了哺乳动物体细胞克隆的方法,存在的问题和体细胞克隆的机理研究。对这些方法和研究理论进行了讨论,并探讨如何利用克隆技术进行转基因动物的制备。     

细胞核重新编程的研究进展

细胞核重新编程是哺乳动物正常胚胎和克隆胚胎发育的关键性因素,主要表现为表观遗传学上变化。在受精卵形成和发育过程中,基因组的甲基化状态和组蛋白的结合形式均发生改变;在核移植产生的克隆胚胎中,供体细胞核也会经历核膜破裂、早熟染色体凝集等变化,重新获得分化的潜能而发育为正常的克隆动物。同时存在多种因素影响重新编程的进行。现对哺乳动物细胞核重新编程的研究进展进行综述,以期为该领域进一步的探索提供借鉴。     

人-兔异种核移植构建克隆胚的实验研究

“治疗性克隆”是人类最关注的课题之一,而人体细胞核移植是治疗性克隆的基础和前提。异种核移植的方法虽已被引入人体细胞克隆胚的构建,但供体细胞的类型、培养代数及准备方法与其效率之间的关系尚有待探讨。本实验以不同培养代数和不同准备方法的人卵丘细胞、皮肤成纤维细胞和软骨细胞为供体构建了克隆胚,对其发育情况的比较表明,以卵丘细胞为供体时重构胚的体外发育率高于其余二者,差异显著（P〈0．05）;不同培养代数的成纤维细胞克隆胚和不同冷藏天数供体细胞克隆胚体外发育率无明显差异。此外,本实验还尝试用荧光原位杂交法检测所构建的异种克隆胚核遗传物质的来源,结果显示来自人体细胞。本研究表明,人一兔异种核移植构建克隆胚切实可行;体细胞的类型与核移植效率相关;供体细胞的体外培养传代对克隆胚的发育并无影响;而冷藏是一种简便有效的供体细胞准备方法;此外,用FISH方法对重构胚进行核遗传物质的鉴定切实可行。     

细胞核重编程对克隆的影响

细胞核重编程是哺乳动物正常受精胚胎和克隆胚胎发育过程中的一个重要特性,主要是对表观遗传学特征进行重新编写,包括染色质重塑、组蛋白修饰、DNA甲基化、印记基因表达、X染色体失活等表观遗传修饰的改变。通过细胞核重编程,首先,受精卵和克隆胚胎的供体核停止其特有的基因表达程序,恢复为全能状态的基因表达程序;然后,受精胚胎和克隆胚胎的细胞再从全能状态重新进入分化状态,最终形成各种组织和器官。近年来,不少研究表明,克隆胚胎的细胞核重编程存在不同程度的表观遗传修饰异常,可能对克隆及其农业和医学应用有着重要影响。本文就正常和克隆胚胎细胞核重编程的研究进展以及克隆胚胎的细胞核重编程异常对克隆的影响作一综述,并对目前有关治疗性克隆前景的不同看法进行了讨论。     

供体细胞的不同选择和处理对重编程过程的影响

摘要: 供体细胞核移入去核的卵母细胞后, 必定要经过表观遗传修饰的重编程过程, 回到胚胎开始发育的全能状态。若重编程过程不完全, 必定会导致克隆效率降低。但是, 体细胞核的重编程能力不仅仅是在其移入去核的卵母细胞后所体现, 它在不同的供体细胞当中的潜能也是不尽相同的。并且, 对供体细胞进行不同的处理, 也会导致其重编程的能力和程度不同。文章首先阐述了供体细胞的类型、代数、周期、年龄以及物种的不同选择对其核移植后重编程过程的不同影响, 其后又通过对供体细胞的冷冻保存, 血清饥饿以及不同试剂的处理等方面对重编程过程所起到的作用作出了概况性的论述与分析     

未经休眠处理的体细胞用于异种核移植

自“多莉”诞生以来,在全世界掀起了一场体细胞克隆的浪潮,许多体细胞克隆动物,如小鼠、山羊、牛、猪等纷纷问世。围绕体细胞克隆的供体细胞周期问题,学术界存在两种不同的观点,一是Wilmut等认为体细胞必须经过休眠处理,使细胞停滞在G0/G1期,或者采用以G0/G1期为主的活体细胞作为供体,这是克隆成功的关键,这一方面的报道已有很多。第二是Cibelli等认为不必对细胞作     

我国体细胞克隆牛的研究进展

近年来,由于体细胞克隆技术在畜牧业生产、疾病治疗、生物学基础理论研究及濒危动物保护等诸多领域所蕴藏的巨大应用价值,克隆效率成为科学界研究的热点问题。本文对克隆技术的相关影响因素进行了综述,研究表明,不同细胞系影响到体细胞克隆牛效率,胎儿细胞和颗粒细胞重构胚的囊胚发育率、犊牛成活率比成年成纤维细胞高。关于卵母细胞和克隆胚胎冷冻保存的研究表明,玻璃化冷冻法可以用于克隆胚胎以及卵母细胞的冷冻保存。在此基础上,讨论了国际上哺乳动物体细胞克隆研究新进展和体细胞克隆的效率,指出体细胞克隆中亟待解决的问题。     

Expression Pattern and Localization Dynamics of Guanine Nucleotide Exchange Factor RIC8 during Mouse Oogenesis

Targeting of G proteins to the cell cortex and their activation is one of the triggers of both asymmetric and symmetric cell division. Resistance to inhibitors of cholinesterase 8 (RIC8), a guanine nucleotide exchange factor, activates a certain subgroup of G protein α-subunits in a receptor independent manner. RIC8 controls the asymmetric cell division in Caenorhabditis elegans and Drosophila melanogaster, and symmetric cell division in cultured mammalian cells, where it regulates the mitotic spindle orientation. Although intensely studied in mitosis, the function of RIC8 in mammalian meiosis has remained unknown. Here we demonstrate that the expression and subcellular localization of RIC8 changes profoundly during mouse oogenesis. Immunofluorescence studies revealed that RIC8 expression is dependent on oocyte growth and cell cycle phase. During oocyte growth, RIC8 is abundantly present in cytoplasm of oocytes at primordial, primary and secondary preantral follicle stages. Later, upon oocyte maturation RIC8 also populates the germinal vesicle, its localization becomes cell cycle dependent, and it associates with chromatin and the meiotic spindle. After fertilization, RIC8 protein converges to the pronuclei and is also detectable at high levels in the nucleolus precursor bodies of both maternal and paternal pronucleus. During first cleavage of zygote RIC8 localizes in the mitotic spindle and cell cortex of forming blastomeres. In addition, we demonstrate that RIC8 co-localizes with its interaction partners Gα_i1/2:GDP and LGN in meiotic/mitotic spindle, cell cortex and polar bodies of maturing oocytes and zygotes. Downregulation of Ric8 by siRNA leads to interferred translocation of Gα_i1/2 to cortical region of maturing oocytes and reduction of its levels. RIC8 is also expressed at high level in female reproductive organs e.g. oviduct. Therefore we suggest a regulatory function for RIC8 in mammalian gametogenesis and fertility.     

Regulation of meiotic maturation in the mammalian oocyte: interplay between exogenous cues and the microtubule cytoskeleton.

Mammalian oocytes exhibit a series of cell cycle transitions that coordinate the penultimate events of meiosis with the onset of embryogenesis at fertilization. The execution of these cell cycle transitions, at G2/M of meiosis-I and metaphase/anaphase of meiosis I and II, involve both biosynthetic and post-translational modifications that directly modulate centrosome and microtubule behavior. Specifically, somatic cells alter the signal transduction pathways in the oocyte and influence the expression of maturation promoting factor (MPF) and cytostatic factor (CSF) activity through a microtubule-dependent mechanism. The regulation of the oocytes' cell cycle machinery by hormone-mediated somatic cell signals, involving both positive and negative stimuli, ensures that meiotic cell cycle progression is synchronized with the earliest pivotal events of mammalian reproduction.     

Meiotic cell cycle arrest in mammalian oocytes

Meiotic cell cycle in mammalian oocytes is a dynamic process that involves several stop/go channels. The cell cycle arrest in oocyte occurs at various stages such as diplotene, metaphase‐I (M‐I), metaphase‐II (M‐II), and so called metaphase‐like arrest (M‐III). Leutinizing hormone surge induces meiotic resumption from diplotene arrest in follicular microenvironment by overriding several factors responsible for the maintenance of meiotic arrest. The inhibitory factors are synthesized in oocyte or in the associated follicular somatic cells and transferred to the oocyte. The major factors include hypoxanthine, cyclic adenosine 3′, 5′‐monophosphate, cyclic guanosine 3′, 5′‐monophosphate, reactive oxygen species, protein kinase A, and protein kinase C. In the presence of active protein kinases, epidermal‐like growth factors are produced that activate mitogen‐activated protein kinase in cumulus granulosa cells. The maturation promoting factor, cytostatic factors, and spindle assembly checkpoint proteins are also involved in that maintenance of arrest at various stages of meiotic cell cycle in mammalian oocytes. In this review, we briefly summarize the role of these factors in the maintenance of meiotic cell cycle arrest in mammalian oocytes. J. Cell. Physiol. 223:592–600, 2010. © 2010 Wiley‐Liss, Inc.     

Macrophage-induced cytostasis: kinetic analysis of bromodeoxyuridine-pulsed cells

The effect of tumoricidal macrophages on the cell cycle progression of six different cell lines was studied using an anti-bromodeoxyuridine (BrdUrd) monoclonal antibody to follow the traverse of BrdUrd-labeled cells. Exponentially growing cultured mammalian cells, from six different cell lines, were prepulsed with BrdUrd before exposure to tumoricidal macrophages. The cultured cells were then analyzed as a function of time for DNA content (by propidium iodide staining) and for BrdUrd incorporation (using a fluoresceinisothiocyanate [FITC]-conjugated anti-BrdUrd monoclonal antibody). The position of the cells in cycle and the progression of the BrdUrd-labeled cohort was followed using flow cytometry. The cell lines examined were: Colon 26, BALB/c-3T3, ST3T3 (a spontaneously transformed, tumorigenic clone of 3T3), WCHE5 (a clone of whole Chinese hamster embryo cells), RIF (a radiation-induced fibrosarcoma), and A101D (a human melanoma). The bivariate distributions showed that for all six cell lines the BrdUrd-labeled cohort in the control cultures progressed around the cell cycle during the first 12 h of culture, as the cells exponentially increased. In contrast, when each cell line was incubated with tumoricidal macrophages, the BrdUrd-labeled cohort did not progress through cell cycle but remained in S phase throughout the 12-h culture period. There was also no evidence for progression of cells out of G1. The data show that cells were arrested in every phase of cell cycle. This study suggests that cytostasis, as manifested by the termination of progression in all phases of the cell cycle, is a universal phenomenon induced by tumoricidal macrophages.     

哺乳动物卵母细胞成熟和受精中细胞骨架重组和作用

卵母细胞成熟和受精是动物生殖过程的核心环节。细胞骨架是遍布于卵母细胞胞质中的一种复杂的蛋白质纤维网络,研究表明,卵母细胞成熟和受精过程中伴随着广泛的胞质骨架重组。哺乳动物卵母细胞和早期胚胎中细胞骨架具有其独特的分布和功能,使卵母细胞和胚胎呈现出不同的变化特点。微丝、微管的分布变化与卵母细胞成熟和受精中遗传物质的重组密切相关。近年来,对哺乳动物不同物种间卵母细胞和胚胎中细胞骨架成分的研究取得了很大的进展,结合这些研究成果,对哺乳动物卵母细胞成熟和受精过程中细胞骨架的重组、分布和作用进行了介绍。同时,对多种信号转导途径参与卵母细胞成熟和受精中细胞骨架系统的调控也作了探讨。     

The C.elegans MAPK phosphatase LIP-1 is required for the G(2)/M meiotic arrest of developing oocytes

In the Caenorhabditis elegans hermaphrodite germline, spatially restricted mitogen-activated protein kinase (MAPK) signalling controls the meiotic cell cycle. First, the MAPK signal is necessary for the germ cells to progress through pachytene of meiotic prophase I. As the germ cells exit pachytene and enter diplotene/diakinesis, MAPK is inactivated and the developing oocytes arrest in diakinesis (G(2)/M arrest). During oocyte maturation, a signal from the sperm reactivates MAPK to promote M phase entry. Here, we show that the MAPK phosphatase LIP-1 dephosphorylates MAPK as germ cells exit pachytene in order to maintain MAPK in an inactive state during oocyte development. Germ cells lacking LIP-1 fail to arrest the cell cycle at the G(2)/M boundary, and they enter a mitotic cell cycle without fertilization. LIP-1 thus coordinates oocyte cell cycle progression and maturation with ovulation and fertilization.     

Regulation of the meiosis-inhibited protein kinase, a p38(MAPK) isoform, during meiosis and following fertilization of seastar oocytes

A p38(MAPK) homolog Mipk (meiosis-inhibited protein kinase) was cloned from seastar oocytes. This 40-kDa protein shares approximately 65% amino acid identity with mammalian p38-alpha isoforms. Mipk was one of the major tyrosine-phosphorylated proteins in immature oocytes arrested at the G(2)/M transition of meiosis I. The tyrosine phosphorylation of Mipk was increased in response to anisomycin, heat, and osmotic shock of oocytes. During 1-methyladenine-induced oocyte maturation, Mipk underwent tyrosine dephosphorylation and remained dephosphorylated in mature oocytes and during the early mitotic cell divisions until approximately 12 h after fertilization. At the time of differentiation and acquisition of G phases in the developing embryos, Mipk was rephosphorylated on tyrosine. In oocytes that were microinjected with Mipk antisense oligonucleotides and subsequently were allowed to mature and become fertilized, differentiation was blocked. Because MipK antisense oligonucleotides and a dominant-negative (K62R)Mipk when microinjected into immature oocytes failed to induce germinal vesicle breakdown, inhibition of Mipk function was not sufficient by itself to cause oocyte maturation. These findings point to a putative role for Mipk in cell cycle control as a G-phase-promoting factor.