通过体外筛选推导的GNRA四环RNA识别规则:与体内进化的比较。
Rules for RNA recognition of GNRA tetraloops deduced by in vitro selection: comparison with in vivo evolution.
作者信息
Costa M, Michel F
机构信息
Centre de Génétique Moléculaire du CNRS, Gif-sur-Yvette, France.
出版信息
EMBO J. 1997 Jun 2;16(11):3289-302. doi: 10.1093/emboj/16.11.3289.
Abstract
Terminal loops with a GNRA consensus sequence are a prominent feature of large self-assembling RNA molecules. In order to investigate tertiary interactions involving GNRA loops, we have devised an in vitro selection system derived from a group I ribozyme. Two selections, destined to isolate RNA sequences that would recognize two of the most widespread loops (GUGA and GAAA), yielded variants of previously identified receptors for those loops, and also some yet unrecognized, high-affinity binders with novel specificities towards members of the GNRA family. By taking advantage of available crystal structures, we have attempted to rationalize these results in terms of RNA-RNA contacts and to expose some of the structural principles that govern GNRA loop-mediated tertiary interactions; the role of loop nucleotide 2 in ensuring specific recognition by receptors is emphasized. More generally, comparison of the products of in vitro and natural selection is shown to provide insights into the mechanisms underlying the in vivo evolution of self-assembling RNA molecules.
摘要
具有GNRA共有序列的末端环是大型自组装RNA分子的一个显著特征。为了研究涉及GNRA环的三级相互作用,我们设计了一种源自I组核酶的体外筛选系统。两次筛选旨在分离能够识别两种最常见环(GUGA和GAAA)的RNA序列,结果产生了先前已鉴定的针对这些环的受体变体,以及一些尚未被识别的、对GNRA家族成员具有新特异性的高亲和力结合剂。通过利用现有的晶体结构,我们试图根据RNA-RNA接触来解释这些结果,并揭示一些支配GNRA环介导的三级相互作用的结构原理;强调了环核苷酸2在确保受体特异性识别中的作用。更普遍地说,体外选择和自然选择产物的比较显示,这有助于深入了解自组装RNA分子体内进化的潜在机制。
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