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核移植后体细胞异染色质中组蛋白变体MacroH2A的快速消除。

Rapid elimination of the histone variant MacroH2A from somatic cell heterochromatin after nuclear transfer.

作者信息

Chang Ching-Chien, Gao Shaorong, Sung Li-Ying, Corry Gareth N, Ma Yinghong, Nagy Zsolt Peter, Tian X Cindy, Rasmussen Theodore P

机构信息

Center for Regenerative Biology, University of Connecticut, Storrs, Connecticut 06269-4243, USA.

出版信息

Cell Reprogram. 2010 Feb;12(1):43-53. doi: 10.1089/cell.2009.0043.

DOI:10.1089/cell.2009.0043
PMID:20132012
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2998967/
Abstract

Oocytes contain a maternal store of the histone variant MacroH2A, which is eliminated from zygotes shortly after fertilization. Preimplantation embryos then execute three cell divisions without MacroH2A before the onset of embryonic MacroH2A expression at the 16-cell stage. During subsequent development, MacroH2A is expressed in most cells, where it is assembled into facultative heterochromatin. Because differentiated cells contain heterochromatin rich in MacroH2A, we investigated the fate of MacroH2A during somatic cell nuclear transfer (SCNT). The results show that MacroH2A is rapidly eliminated from the chromosomes of transplanted somatic cell nuclei by a process in which MacroH2A is first stripped from chromosomes, and then degraded. Furthermore, MacroH2A is eliminated from transplanted nuclei by a mechanism requiring intact microtubules and nuclear envelope break down. Preimplantation SCNT embryos express endogenous MacroH2A once they reach the morula stage, similar to the timing observed in embryos produced by natural fertilization. We also show that the ability to reprogram somatic cell heterochromatin by SCNT is tied to the developmental stage of recipient cell cytoplasm because enucleated zygotes fail to support depletion of MacroH2A from transplanted somatic nuclei. Together, the results indicate that nuclear reprogramming by SCNT utilizes the same chromatin remodeling mechanisms that act upon the genome immediately after fertilization.

摘要

卵母细胞中含有组蛋白变体MacroH2A的母体储存库,受精后不久该变体就会从合子中消除。在植入前胚胎发育过程中,在16细胞阶段胚胎MacroH2A表达开始之前,胚胎会进行三次细胞分裂,期间没有MacroH2A。在随后的发育过程中,MacroH2A在大多数细胞中表达,并组装成兼性异染色质。由于分化细胞含有富含MacroH2A的异染色质,我们研究了体细胞核移植(SCNT)过程中MacroH2A的命运。结果表明,MacroH2A通过一个过程从移植的体细胞核染色体中迅速消除,该过程先是MacroH2A从染色体上剥离,然后降解。此外,MacroH2A通过一种需要完整微管和核膜破裂的机制从移植的细胞核中消除。植入前的SCNT胚胎一旦达到桑椹胚阶段就会表达内源性MacroH2A,这与自然受精产生的胚胎中观察到的时间相似。我们还表明,通过SCNT对体细胞异染色质进行重编程的能力与受体细胞质的发育阶段相关,因为去核合子无法支持移植的体细胞核中MacroH2A的消耗。总之,这些结果表明,SCNT进行的核重编程利用了与受精后立即作用于基因组的相同染色质重塑机制。

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