重编程拟南芥花粉中的表观基因组。
Reprogramming the epigenome in Arabidopsis pollen.
作者信息
Borges F, Calarco J P, Martienssen R A
机构信息
Cold Spring Harbor Laboratory, Cold Spring Harbor, New York 11724, USA.
出版信息
Cold Spring Harb Symp Quant Biol. 2012;77:1-5. doi: 10.1101/sqb.2013.77.014969. Epub 2013 Apr 25.
Abstract
Epigenetic reprogramming in Arabidopsis thaliana occurs in developing pollen. The male gametophyte is derived from haploid microspores via two postmeiotic cell divisions to give rise to the gametes (sperm cells, SC) and the vegetative cell (VC). The purification of individual cell types during pollen development coupled with genome-wide DNA methylation analysis and small RNA sequencing has revealed a dynamic regulation of the epigenome during gametogenesis. Interestingly, imprinted loci and previously identified variable epialleles are hypermethylated in the germline; however, their stability after fertilization appears to require targeted demethylation in the neighboring vegetative cell nucleus, possibly by releasing mobile small RNAs that reinforce transcriptional gene silencing and DNA methylation in the gametes. These results have led to a new model for the establishment and transgenerational maintenance of epigenetic marks in flowering plants.
摘要
拟南芥中的表观遗传重编程发生在发育中的花粉中。雄配子体通过两次减数分裂后的细胞分裂从单倍体小孢子衍生而来,产生配子(精子细胞,SC)和营养细胞(VC)。花粉发育过程中单个细胞类型的纯化,结合全基因组DNA甲基化分析和小RNA测序,揭示了配子发生过程中表观基因组的动态调控。有趣的是,印记位点和先前鉴定的可变表观等位基因在种系中高度甲基化;然而,受精后它们的稳定性似乎需要在相邻的营养细胞核中进行靶向去甲基化,可能是通过释放可移动的小RNA来加强配子中的转录基因沉默和DNA甲基化。这些结果为开花植物中表观遗传标记的建立和跨代维持提供了一个新模型。
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