Jiang F, Patel D J, Zhang X, Zhao H, Jones R A
Cellular Biochemistry and Biophysics Program, Memorial Sloan-Kettering Cancer Center, New York, NY 10021, USA.
J Biomol NMR. 1997 Jan;9(1):55-62. doi: 10.1023/a:1018623601946.
The secondary structure of a recently identified ATP-binding RNA aptamer consists of a purine-rich 11-residue internal loop positioned opposite a single guanine bulge flanked on either side by helical stem segments. The ATP ligand targets the internal loop and bulge domains, inducing a structural transition in this RNA segment on complex formation. Specifically, 10 new slowly exchanging proton resonances in the imino, amino and sugar hydroxyl chemical shift range are observed on AMP-RNA aptamer complex formation. This paper outlines site-specific labeling approaches to identify slowly exchanging imino (guanine) and amino (guanine and adenine) protons in internal loop and bulge segments of compact RNA folds such as found in the AMP-RNA aptamer complex. One approach incorporates 15N-labeled guanine (N1 imino and N2 amino positions) and 15N-labeled adenine (N6 amino position), one residue at a time, in the AMP-binding RNA aptamer, with labeling incorporation through chemical synthesis facilitated by generating the aptamer from two separate strands. The unambiguous assignments deduced from the 15N labeling studies have been verified from an independent labeling strategy where individual guanines in the internal loop have been replaced, one at a time, by inosines and assignments were made on the basis of the large 2 ppm downfield shift of the guanine imino protons on inosine substitution. The strengths and limitations of the inosine-for-guanine substitution approach emerge from our studies on the AMP-RNA aptamer complex. The assignment of the internal loop and bulge imino and amino protons was critical in our efforts to define the solution structure of the AMP-RNA aptamer complex since these slowly exchanging protons exhibit a large number of long-range intramolecular NOEs within the RNA, as well as intermolecular NOEs to the AMP in the complex. The current application of specific 15N and inosine labeling approaches for exchangeable imino and imino proton assignments in the nonhelical segments of an RNA aptamer complex in our laboratory complements selective 2H and 13C approaches to assign nonexchangeable base and sugar protons in RNA and ligand-RNA complexes reported in the literature.
最近鉴定出的一种ATP结合RNA适体的二级结构,由一个富含嘌呤的11个残基的内环组成,该内环与一个单鸟嘌呤凸起相对,两侧为螺旋茎段。ATP配体靶向内环和凸起结构域,在复合物形成时诱导该RNA片段发生结构转变。具体而言,在AMP-RNA适体复合物形成时,在亚氨基、氨基和糖羟基化学位移范围内观察到10个新的慢交换质子共振。本文概述了位点特异性标记方法,以鉴定紧密RNA折叠的内环和凸起片段中慢交换的亚氨基(鸟嘌呤)和氨基(鸟嘌呤和腺嘌呤)质子,如在AMP-RNA适体复合物中发现的那样。一种方法是在AMP结合RNA适体中一次一个残基地掺入15N标记的鸟嘌呤(N1亚氨基和N2氨基位置)和15N标记的腺嘌呤(N6氨基位置),通过从两条单独的链生成适体来促进化学合成中的标记掺入。从15N标记研究中推断出的明确归属,已通过一种独立的标记策略得到验证,在该策略中,内环中的单个鸟嘌呤一次一个地被次黄嘌呤取代,并根据次黄嘌呤取代时鸟嘌呤亚氨基质子的2 ppm大的向下场位移进行归属。我们对AMP-RNA适体复合物的研究揭示了次黄嘌呤取代鸟嘌呤方法的优点和局限性。内环和凸起亚氨基和氨基质子的归属对于我们确定AMP-RNA适体复合物的溶液结构至关重要,因为这些慢交换质子在RNA内表现出大量的长程分子内NOE,以及与复合物中AMP的分子间NOE。我们实验室目前应用特定的15N和次黄嘌呤标记方法对RNA适体复合物非螺旋段中可交换的亚氨基和亚氨基质子进行归属,补充了文献中报道的用于在RNA和配体-RNA复合物中归属不可交换的碱基和糖质子的选择性2H和13C方法。
