嗜热四膜虫端粒酶RNA茎环IV的结构
Structure of stem-loop IV of Tetrahymena telomerase RNA.
作者信息
Chen Yu, Fender Jessica, Legassie Jason D, Jarstfer Michael B, Bryan Tracy M, Varani Gabriele
机构信息
Department of Chemistry, University of Washington, Seattle, 98185-1700, USA.
出版信息
EMBO J. 2006 Jul 12;25(13):3156-66. doi: 10.1038/sj.emboj.7601195. Epub 2006 Jun 15.
Abstract
Conserved domains within the RNA component of telomerase provide the template for reverse transcription, recruit protein components to the holoenzyme and are required for enzymatic activity. Among the functionally essential domains in ciliate telomerase RNA is stem-loop IV, which strongly stimulates telomerase activity and processivity even when provided in trans. The NMR structure of Tetrahymena thermophila stem-loop IV shows a highly structured distal stem-loop linked to a conformationally flexible template-proximal region by a bulge that severely kinks the entire RNA. Through extensive structure-function studies, we identify residues that contribute to both these structural features and to enzymatic activity, with no apparent effect on the binding of TERT protein. We propose that the bending induced by the GA bulge and the flexibility of the template-proximal region allow positioning of the prestructured apical loop during the catalytic cycle.
摘要
端粒酶RNA组分中的保守结构域为逆转录提供模板,将蛋白质组分招募至全酶,并且是酶活性所必需的。在纤毛虫端粒酶RNA的功能必需结构域中,茎环IV即使以反式提供时也能强烈刺激端粒酶活性和持续合成能力。嗜热四膜虫茎环IV的核磁共振结构显示,一个高度结构化的远端茎环通过一个使整个RNA严重扭结的凸起与一个构象灵活的模板近端区域相连。通过广泛的结构-功能研究,我们确定了对这两种结构特征和酶活性都有贡献的残基,而对TERT蛋白的结合没有明显影响。我们提出,GA凸起引起的弯曲和模板近端区域的灵活性允许在催化循环期间对预结构化的顶端环进行定位。
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