Knitt D S, Narlikar G J, Herschlag D
Department of Biochemistry, Stanford University, California 94305.
Biochemistry. 1994 Nov 22;33(46):13864-79. doi: 10.1021/bi00250a041.
Phylogenetic conservation among > 100 group I introns and previous in vitro studies have implicated a G.U pair as defining the 5'-splice site for exon ligation. The U residue defines the 3' end of the 5' exon, and the complementary G residue is part of the internal guide sequence (IGS) that base pairs to the 5' exon. We now quantitate the effect of this pair on individual reaction steps using the L-21ScaI ribozyme, which is derived from the group I intron of Tetrahymena thermophila pre-rRNA. The following results indicate that interactions with this G.U pair contribute to the binding of the 5'-exon, the positioning of the 5'-splice site with respect to the catalytic site, and the chemical step. The oligonucleotide, CCCUCU, binds to the ribozyme approximately 20-fold stronger than CCCUCC despite the fact that the U-containing oligonucleotide forms an approximately 5-fold less stable duplex with an oligonucleotide analog of the IGS, GGAGGG. This and two independent experimental observations indicate that the G.U pair contributes approximately 100-fold (3 kcal/mol, 50 degrees C) to tertiary interactions that allow the P1 duplex, which is formed between the 5'-exon and the IGS, to dock into the ribozyme's core. The approximately 50-80-fold increase in miscleavage of 5'-exon analogs upon replacement of the 3'-terminal U of CCCUCU with C or upon removal of the 3'-terminal U suggests that the tertiary interactions with the G.U pair not only contribute to docking but also ensure correct positioning of the 5'-splice site with respect to the catalytic site, thereby minimizing the selection of incorrect splice sites. Comparison of the rates of the chemical cleavage step with G.U vs G.C suggests that the G.U pair contributes approximately 10-fold to the chemical step. It was previously suggested that the 2'-hydroxyl of this U residue helps stabilize the 3'-oxyanion leaving group in the chemical transition state via an intramolecular hydrogen bond. Relative reactivities of oligonucleotide substrates with ribose and deoxyribose U and C are consistent with a model based on a recent X-ray crystallographic structure in which the exocyclic amino group of G helps orient the 2'-hydroxyl of U via a bridging water molecule, thereby strengthening the hydrogen bond donated from the 2'-hydroxyl group to the neighboring incipient 3'-oxyanion. Finally, kinetic and thermodynamic evidence for the formation of a G.C+ wobble pair is presented.(ABSTRACT TRUNCATED AT 400 WORDS)
超过100个I类内含子之间的系统发育保守性以及先前的体外研究表明,G.U碱基对决定了外显子连接的5'剪接位点。U残基定义了5'外显子的3'末端,互补的G残基是与5'外显子碱基配对的内部引导序列(IGS)的一部分。我们现在使用源自嗜热四膜虫前体rRNA的I类内含子的L-21ScaI核酶来定量该碱基对对各个反应步骤的影响。以下结果表明,与该G.U碱基对的相互作用有助于5'外显子的结合、5'剪接位点相对于催化位点的定位以及化学反应步骤。尽管含U的寡核苷酸与IGS的寡核苷酸类似物GGAGGG形成的双链体稳定性低约5倍,但寡核苷酸CCCUCU与核酶的结合力比CCCUCC强约20倍。这一结果以及另外两个独立的实验观察结果表明,G.U碱基对对三级相互作用的贡献约为100倍(在50℃时为3千卡/摩尔),使得5'外显子与IGS之间形成的P1双链体能够对接至核酶的核心。当用C取代CCCUCU的3'末端U或去除3'末端U时,5'外显子类似物的错切割增加约50 - 80倍,这表明与G.U碱基对的三级相互作用不仅有助于对接,还能确保5'剪接位点相对于催化位点的正确定位,从而减少对错误剪接位点的选择。比较G.U与G.C时化学切割步骤的速率表明,G.U碱基对对化学反应步骤的贡献约为10倍。先前有人提出,该U残基的2'-羟基通过分子内氢键有助于稳定化学过渡态中的3'-氧阴离子离去基团。寡核苷酸底物中核糖和脱氧核糖的U与C的相对反应活性与基于最近X射线晶体结构的模型一致,在该模型中,G的环外氨基通过桥连水分子帮助使U的2'-羟基定向,从而加强从2'-羟基基团向相邻的初始3'-氧阴离子提供的氢键。最后,给出了形成G.C +摆动碱基对的动力学和热力学证据。(摘要截断于400字)
