转录频率较低的长基因依靠Set2/Rpd3S途径进行精确转录。
Infrequently transcribed long genes depend on the Set2/Rpd3S pathway for accurate transcription.
作者信息
Li Bing, Gogol Madelaine, Carey Mike, Pattenden Samantha G, Seidel Chris, Workman Jerry L
机构信息
Stowers Institute for Medical Research, Kansas City, Missouri 64110, USA.
出版信息
Genes Dev. 2007 Jun 1;21(11):1422-30. doi: 10.1101/gad.1539307.
Abstract
The presence of Set2-mediated methylation of H3K36 (K36me) correlates with transcription frequency throughout the yeast genome. K36me targets the Rpd3S complex to deacetylate transcribed regions and suppress cryptic transcription initiation at certain genes. Here, using a genome-wide approach, we report that the Set2-Rpd3S pathway is generally required for controlling acetylation at coding regions. When using acetylation as a functional readout for this pathway, we discovered that longer genes and, surprisingly, genes transcribed at lower frequency exhibit a stronger dependency. Moreover, a systematic screen using high-resolution tiling microarrays allowed us to identify a group of genes that rely on Set2-Rpd3S to suppress spurious transcripts. Interestingly, most of these genes are within the group that depend on the same pathway to maintain a hypoacetylated state at coding regions. These data highlight the importance of using the functional readout of histone codes to define the roles of specific pathways.
摘要
组蛋白H3第36位赖氨酸(H3K36)的Set2介导甲基化的存在与酵母全基因组的转录频率相关。K36me将Rpd3S复合物靶向到转录区域进行去乙酰化,并抑制某些基因处的隐蔽转录起始。在这里,我们使用全基因组方法报告,Set2-Rpd3S途径通常是控制编码区域乙酰化所必需的。当使用乙酰化作为该途径的功能读数时,我们发现较长的基因,令人惊讶的是,转录频率较低的基因表现出更强的依赖性。此外,使用高分辨率平铺微阵列进行的系统筛选使我们能够鉴定出一组依赖Set2-Rpd3S来抑制假转录本的基因。有趣的是,这些基因中的大多数都属于依赖同一途径在编码区域维持低乙酰化状态的基因组。这些数据突出了使用组蛋白密码的功能读数来定义特定途径作用的重要性。
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本文引用的文献
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