热休克因子结合在 Alu 重复序列中，通过反义机制扩展了其在应激反应中的作用。

Heat shock factor binding in Alu repeats expands its involvement in stress through an antisense mechanism.

机构信息

Genomics and Molecular Medicine, Institute of Genomics and Integrative Biology, Council of Scientific and Industrial Research (CSIR-IGIB), Delhi- India.

出版信息

Genome Biol. 2011 Nov 23;12(11):R117. doi: 10.1186/gb-2011-12-11-r117.

DOI:10.1186/gb-2011-12-11-r117

PMID:22112862

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3334603/

Abstract

BACKGROUND

Alu RNAs are present at elevated levels in stress conditions and, consequently, Alu repeats are increasingly being associated with the physiological stress response. Alu repeats are known to harbor transcription factor binding sites that modulate RNA pol II transcription and Alu RNAs act as transcriptional co-repressors through pol II binding in the promoter regions of heat shock responsive genes. An observation of a putative heat shock factor (HSF) binding site in Alu led us to explore whether, through HSF binding, these elements could further contribute to the heat shock response repertoire.

RESULTS

Alu density was significantly enriched in transcripts that are down-regulated following heat shock recovery in HeLa cells. ChIP analysis confirmed HSF binding to a consensus motif exhibiting positional conservation across various Alu subfamilies, and reporter constructs demonstrated a sequence-specific two-fold induction of these sites in response to heat shock. These motifs were over-represented in the genic regions of down-regulated transcripts in antisense oriented Alus. Affymetrix Exon arrays detected antisense signals in a significant fraction of the down-regulated transcripts, 50% of which harbored HSF sites within 5 kb. siRNA knockdown of the selected antisense transcripts led to the over-expression, following heat shock, of their corresponding down-regulated transcripts. The antisense transcripts were significantly enriched in processes related to RNA pol III transcription and the TFIIIC complex.

CONCLUSIONS

We demonstrate a non-random presence of Alu repeats harboring HSF sites in heat shock responsive transcripts. This presence underlies an antisense-mediated mechanism that represents a novel component of Alu and HSF involvement in the heat shock response.

摘要

背景

Alu RNA 在应激条件下的水平升高，因此，Alu 重复序列越来越多地与生理应激反应相关联。已知 Alu 重复序列含有转录因子结合位点，可调节 RNA pol II 转录，Alu RNA 通过结合热休克反应基因启动子区域的 pol II 作为转录共抑制因子发挥作用。在 Alu 中观察到一个假定的热休克因子 (HSF) 结合位点，促使我们探索这些元件是否可以通过 HSF 结合进一步促进热休克反应谱。

结果

在 HeLa 细胞热休克恢复后下调的转录本中，Alu 密度明显富集。ChIP 分析证实 HSF 结合到一个保守的共有基序，该基序在各种 Alu 亚家族中具有位置保守性，报告基因构建体表明这些位点在热休克后会特异性地诱导两倍。这些基序在反义取向 Alu 中下调转录本的基因区域中过度表达。Affymetrix Exon 芯片在显著比例的下调转录本中检测到反义信号，其中 50%的反义信号在 5kb 内含有 HSF 位点。选择的反义转录本的 siRNA 敲低导致其相应下调转录本在热休克后过表达。反义转录本在与 RNA pol III 转录和 TFIIIC 复合物相关的过程中显著富集。

结论

我们证明了含有 HSF 结合位点的 Alu 重复序列在热休克反应转录本中存在非随机分布。这种存在是反义介导机制的基础，该机制代表了 Alu 和 HSF 参与热休克反应的一个新组成部分。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/f176/3334603/cfd8bc39e030/gb-2011-12-11-r117-1.jpg

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J Biol Chem. 2011 Nov 4;286(44):38768-38782. doi: 10.1074/jbc.M111.234161. Epub 2011 Sep 5.

Impact of Alu repeats on the evolution of human p53 binding sites.Alu 重复序列对人类 p53 结合位点进化的影响。

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Alu repeat discovery and characterization within human genomes.人类基因组内 Alu 重复序列的发现和特征分析。

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热休克因子结合在 Alu 重复序列中，通过反义机制扩展了其在应激反应中的作用。

Heat shock factor binding in Alu repeats expands its involvement in stress through an antisense mechanism.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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