Trachman Robert J, Demeshkina Natalia A, Lau Matthew W L, Panchapakesan Shanker Shyam S, Jeng Sunny C Y, Unrau Peter J, Ferré-D'Amaré Adrian R
Biochemistry and Biophysics Center, National Heart, Lung and Blood Institute, Bethesda, Maryland, USA.
Department of Molecular Biology and Biochemistry, Simon Fraser University, Burnaby, British Columbia, Canada.
Nat Chem Biol. 2017 Jul;13(7):807-813. doi: 10.1038/nchembio.2392. Epub 2017 May 29.
Genetically encoded fluorescent protein tags have revolutionized proteome studies, whereas the lack of intrinsically fluorescent RNAs has hindered transcriptome exploration. Among several RNA-fluorophore complexes that potentially address this problem, RNA Mango has an exceptionally high affinity for its thiazole orange (TO)-derived fluorophore, TO1-Biotin (K ∼3 nM), and, in complex with related ligands, it is one of the most redshifted fluorescent macromolecular tags known. To elucidate how this small aptamer exhibits such properties, which make it well suited for studying low-copy cellular RNAs, we determined its 1.7-Å-resolution co-crystal structure. Unexpectedly, the entire ligand, including TO, biotin and the linker connecting them, abuts one of the near-planar faces of the three-tiered G-quadruplex. The two heterocycles of TO are held in place by two loop adenines and form a 45° angle with respect to each other. Minimizing this angle would increase quantum yield and further improve this tool for in vivo RNA visualization.
基因编码的荧光蛋白标签彻底改变了蛋白质组研究,而缺乏内在荧光的RNA则阻碍了转录组的探索。在几种可能解决这一问题的RNA-荧光团复合物中,RNA芒果对其噻唑橙(TO)衍生的荧光团TO1-生物素具有极高的亲和力(K ∼3 nM),并且与相关配体结合时,它是已知的红移程度最高的荧光大分子标签之一。为了阐明这种小适体如何展现出这些使其非常适合研究低拷贝细胞RNA的特性,我们确定了其分辨率为1.7 Å的共晶体结构。出乎意料的是,整个配体,包括TO、生物素以及连接它们的接头,邻接三层G-四链体的一个近平面表面。TO的两个杂环由两个环腺嘌呤固定在位,并且彼此形成45°角。减小这个角度将提高量子产率,并进一步改进这个用于体内RNA可视化的工具。
