Genome Plasticity Laboratory, Department of Cancer Biology, The Scripps Research Institute, Scripps Florida, 130 Scripps Way #2C1, Jupiter, Florida 33458, USA.
EMBO Rep. 2010 Jul;11(7):555-60. doi: 10.1038/embor.2010.79. Epub 2010 May 28.
During meiosis, paternal and maternal homologous chromosomes recombine at specific recombination sites named hotspots. What renders 2% of the mammalian genomes permissive to meiotic recombination by allowing Spo11 endonuclease to initiate double-strand breaks is largely unknown. Work in yeast has shown that chromatin accessibility seems to be important for this activity. Here, we define nucleosome profiles and dynamics at four mouse recombination hotspots by purifying highly enriched fractions of meiotic cells. We found that nucleosome occupancy is generally stable during meiosis progression. Interestingly, the cores of recombination hotspots have largely open chromatin structure, and the localization of the few nucleosomes present in these cores correlates precisely with the crossover-free zones in recombinogenic domains. Collectively, these high-resolution studies suggest that nucleosome occupancy seems to direct, at least in part, how meiotic recombination events are processed.
在减数分裂过程中,父本和母本同源染色体在特定的重组热点处发生重组。是什么使得 2%的哺乳动物基因组能够通过允许 Spo11 内切酶启动双链断裂而允许减数分裂重组,这在很大程度上是未知的。酵母的研究表明,染色质可及性似乎对这种活性很重要。在这里,我们通过纯化高度富集的减数分裂细胞分数,来定义四个小鼠重组热点的核小体图谱和动力学。我们发现核小体占据在减数分裂过程中通常是稳定的。有趣的是,重组热点的核心区域具有很大的开放染色质结构,而这些核心区域中存在的少数核小体的定位与重组区域中的无交叉自由区精确相关。总的来说,这些高分辨率研究表明,核小体占据似乎至少部分地指导了减数分裂重组事件的处理。