裸 DNA 的物理性质影响核小体的定位，并与酵母中的转录起始和终止位点相关。

Physical properties of naked DNA influence nucleosome positioning and correlate with transcription start and termination sites in yeast.

机构信息

Institute for Research in Biomedicine and Barcelona Supercomputing Center Joint Research Program on Computational Biology, Baldiri i Reixac 10, Barcelona 08028, Spain.

出版信息

BMC Genomics. 2011 Oct 7;12:489. doi: 10.1186/1471-2164-12-489.

DOI:10.1186/1471-2164-12-489

PMID:21981773

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3224377/

Abstract

BACKGROUND

In eukaryotic organisms, DNA is packaged into chromatin structure, where most of DNA is wrapped into nucleosomes. DNA compaction and nucleosome positioning have clear functional implications, since they modulate the accessibility of genomic regions to regulatory proteins. Despite the intensive research effort focused in this area, the rules defining nucleosome positioning and the location of DNA regulatory regions still remain elusive.

RESULTS

Naked (histone-free) and nucleosomal DNA from yeast were digested by microccocal nuclease (MNase) and sequenced genome-wide. MNase cutting preferences were determined for both naked and nucleosomal DNAs. Integration of their sequencing profiles with DNA conformational descriptors derived from atomistic molecular dynamic simulations enabled us to extract the physical properties of DNA on a genomic scale and to correlate them with chromatin structure and gene regulation. The local structure of DNA around regulatory regions was found to be unusually flexible and to display a unique pattern of nucleosome positioning. Ab initio physical descriptors derived from molecular dynamics were used to develop a computational method that accurately predicts nucleosome enriched and depleted regions.

CONCLUSIONS

Our experimental and computational analyses jointly demonstrate a clear correlation between sequence-dependent physical properties of naked DNA and regulatory signals in the chromatin structure. These results demonstrate that nucleosome positioning around TSS (Transcription Start Site) and TTS (Transcription Termination Site) (at least in yeast) is strongly dependent on DNA physical properties, which can define a basal regulatory mechanism of gene expression.

摘要

背景

在真核生物中，DNA 被包装成染色质结构，其中大部分 DNA 被包裹在核小体中。DNA 压缩和核小体定位具有明显的功能意义，因为它们调节基因组区域对调节蛋白的可及性。尽管在这一领域进行了大量的研究，但定义核小体定位和 DNA 调节区域位置的规则仍然难以捉摸。

结果

从酵母中提取了裸露（无组蛋白）和核小体 DNA，并用微球菌核酸酶（MNase）进行了全基因组消化。确定了裸露和核小体 DNA 的 MNase 切割偏好性。将它们的测序图谱与来自原子分子动力学模拟的 DNA 构象描述符集成，使我们能够提取基因组规模的 DNA 物理性质，并将其与染色质结构和基因调控相关联。发现调节区域周围的 DNA 局部结构异常灵活，并显示出独特的核小体定位模式。从分子动力学中推导出的原始物理描述符被用于开发一种计算方法，该方法能够准确预测富含核小体和缺乏核小体的区域。

结论

我们的实验和计算分析联合证明了裸露 DNA 的序列依赖性物理性质与染色质结构中的调节信号之间存在明显的相关性。这些结果表明，TSS（转录起始位点）和 TTS（转录终止位点）周围的核小体定位（至少在酵母中）强烈依赖于 DNA 的物理性质，这可以定义基因表达的基本调节机制。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0804/3224377/7b7116292fb0/1471-2164-12-489-1.jpg

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裸 DNA 的物理性质影响核小体的定位，并与酵母中的转录起始和终止位点相关。

Physical properties of naked DNA influence nucleosome positioning and correlate with transcription start and termination sites in yeast.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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