Recently, a few Na+-specific RNA-cleaving DNAzymes were reported, where nucleobases are likely to play critical roles in catalysis. The NaA43 and NaH1 DNAzymes share the same 16-nt Na+-binding motif, but differ in one or two nucleotides in a small catalytic loop. Nevertheless, they display an opposite pH-dependency, implicating distinct catalytic mechanisms. In this work, rational mutation studies locate a catalytic adenine residue, A22, in NaH1, while previous studies found a guanine (G23) to be important for the catalysis of NaA43. Mutation with pKa-perturbed analogs, such as 2-aminopurine (∼3.8), 2,6-diaminopurine (∼5.6) and hypoxanthine (∼8.7) affected the overall reaction rate. Therefore, we propose that the N1 position of G23 (pKa ∼6.6) in NaA43 functions as a general base, while that of A22 (pKa ∼6.3) in NaH1 as a general acid. Further experiments with base analogs and a phosphorothioate-modified substrate suggest that the exocyclic amine in A22 and both of the non-bridging oxygens at the scissile phosphate are important for catalysis for NaH1. This is an interesting example where single point mutations can change the mechanism of cleavage from general base to general acid, and it can also explain this Na+-dependent DNAzyme scaffold being sensitive to a broad range of metal ions and molecules.
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机译:近来,报道了一些Na +特异性的RNA裂解DNA酶,其中核碱基可能在催化中起关键作用。 NaA43和NaH1 DNA酶具有相同的16-nt Na + 结合基序,但是在一个小的催化环中一个或两个核苷酸不同。然而,它们显示出相反的pH依赖性,涉及不同的催化机理。在这项工作中,合理的突变研究在NaH1中定位了一个催化腺嘌呤残基A22,而先前的研究发现鸟嘌呤(G23)对于NaA43的催化很重要。用pKa干扰的类似物(例如2-氨基嘌呤(〜3.8),2,6-二氨基嘌呤(〜5.6)和次黄嘌呤(〜8.7))进行突变会影响总反应速率。因此,我们建议NaA43中G23的N1位置(pKa〜6.6)起一般碱的作用,而NaH1中A22的N1位置(pKa〜6.3)起一般酸的作用。用碱类似物和硫代磷酸酯修饰的底物进行的进一步实验表明,A22中的环外胺和易裂磷酸盐处的两个非桥连氧对于催化NaH1至关重要。这是一个有趣的例子,其中单点突变可以将切割机理从一般碱基改变为一般酸,并且也可以解释这种依赖Na + 的DNAzyme支架对多种金属离子敏感和分子。
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