磷酸二酯键
核酸
核糖核酸
DNA
核酸外切酶
核酸结构
复式(建筑)
聚合酶
寡核苷酸
多核苷酸
化学
核酸类似物
立体化学
生物化学
核苷
组蛋白八聚体
核苷酸
初级
残留物(化学)
核酸热力学
碱基对
DNA聚合酶
胞苷
酶
核酸外切酶 III
呋喃糖
逆转录酶
组合化学
生物
A-DNA
核酸二级结构
核糖
作者
Victorio Jauregui Matos,Dhrubajyoti Datta,Jayanta Kundu,Vathan Kumar,Joel M. Harp,Adekunle Adebayo,Daniel P. Donnelly,Esau Medina,John C. Chaput,Martin Egli,Muthiah Manoharan
标识
DOI:10.1021/acschembio.5c00591
摘要
-phosphonates, solid supports, and nucleoside triphosphates. The building blocks included those containing the four canonical RNA bases A, G, U, and C as well as T and 5-methyl-C and were synthesized starting from a single common sugar intermediate derived from d-(+)-xylose. DNA and RNA duplexes with a single apioNA modification in one strand were less thermodynamically stable than unmodified DNA or RNA. The crystal structure of apioNA-modified RNA octamer showed that the apioNA residue adopts an RNA-like structure but local reorientation of the apioNA sugar and 2'-phosphate and the difference in helical rise on the 5' side of the apioNA T relative to RNA likely contribute to the destabilizing effect of apioNA residues. At the terminus of a DNA strand, this modification provides extremely high resistance against both 3'- and 5'-exonucleases even when linked to the adjacent residue by a phosphodiester moiety. Molecular modeling of a DNA duplex containing apioNA was used to rationalize the DNA duplex destabilization and the exonuclease resistance resulting from incorporation of the apioNA residue. Use of apioNA NTPs as substrates for previously engineered α-l-threofuranosyl polymerases depends on both the enzyme and the nucleobase. These data indicate that apioNAs warrant further evaluation, and the building blocks synthesized will allow incorporation of apioNA into therapeutic oligonucleotides.
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