人类微小RNA靶向具有富含AT的3'非翻译区的功能独特的基因群体。

Human microRNAs target a functionally distinct population of genes with AT-rich 3' UTRs.

作者信息

Robins Harlan, Press William H

机构信息

Institute for Advanced Study, Einstein Drive, Princeton, NJ 08540, USA.

出版信息

Proc Natl Acad Sci U S A. 2005 Oct 25;102(43):15557-62. doi: 10.1073/pnas.0507443102. Epub 2005 Oct 17.

DOI:10.1073/pnas.0507443102

PMID:16230613

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1257391/

Abstract

While investigating microRNA targets, we have found that human genes divide into two roughly equal populations, based on the fraction of A plus T bases in their 3' UTRs. Using the Gene Ontology database, we find significant functional differences between the two gene populations, with AT-rich genes implicated in transcription and translation processes, and GC-rich genes implicated in signal transduction and posttranslational protein modification. Better understanding of the background distribution of nucleotides in 3' UTRs may allow improved prediction of microRNA-targeted genes in humans. We predict at least 1,200 KnownGene transcripts to be regulated by microRNAs. The large majority of these microRNA targets are in the AT-rich 3' UTR population. However, notwithstanding this preference for AT-rich targets, microRNA targets are found preferentially to be regulatory genes themselves, including both transcription factors and posttranslational modifiers. These results suggest that some processes involving mRNA, of which microRNA regulation may be just one, require AT-richness of 3' UTRs for functionality. A relationship, not simply one-to-one, between these 3' UTR populations and large-scale genomic isochores is described.

摘要

在研究微小RNA靶标时，我们发现，根据人类基因3'非翻译区（3'UTR）中A+T碱基的比例，可将其大致分为数量相等的两个群体。利用基因本体论数据库，我们发现这两个基因群体之间存在显著的功能差异，富含AT的基因与转录和翻译过程有关，而富含GC的基因与信号转导和翻译后蛋白质修饰有关。更好地了解3'UTR中核苷酸的背景分布，可能有助于改进对人类微小RNA靶向基因的预测。我们预测至少有1200个已知基因转录本受微小RNA调控。这些微小RNA靶标的绝大多数都在富含AT的3'UTR群体中。然而，尽管对富含AT的靶标有这种偏好，但微小RNA靶标本身优先被发现是调控基因，包括转录因子和翻译后修饰因子。这些结果表明，一些涉及mRNA的过程（微小RNA调控可能只是其中之一）需要3'UTR富含AT才能发挥功能。本文描述了这些3'UTR群体与大规模基因组等密度区之间的关系，这种关系并非简单的一一对应。

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