化学
组合化学
脱羧
DNA
亲核细胞
胞嘧啶
硼烷
纳米技术
计算生物学
机制(生物学)
吡啶
同位素标记
水解
DNA测序
表观遗传学
反应机理
工作(物理)
生化工程
寡核苷酸
作者
Cong Ding,Zipeng Wang,Bingwen Li,Jiangjuan Shao,Ying Tang,Wei Yang,Xiaocheng Weng,Zhi‐Xiang Yu,Xiang Zhou,Yibin Liu
摘要
TET-assisted pyridine borane sequencing (TAPS) is a powerful method for mapping cytosine modifications, yet the underlying mechanism of conversion of 5-carboxylcytosine (5caC) to dihydrouracil (DHU) remains poorly understood. Here, through both experimental and computational studies, we show that the reaction proceeds via reduction and decarboxylation to give 5,6-dihydrocytidine as the intermediate, which is then slowly hydrolyzed to DHU as the rate-limiting step. We also found that in double-stranded DNA, the reaction can be catalyzed by an adjacent 5caC with high efficiency. The mechanistic discovery of the slow hydrolysis step by water in the conventional TAPS guided us to use more nucleophilic alkoxyamines to improve this protocol, achieving complete conversion within 1 h. This approach, when coupled with a click-chemistry pull-down, enables up to a 47-fold enrichment of 5caC-containing DNA. Our work thus provides fundamental mechanistic insights into a key epigenetic sequencing reaction and translates this knowledge into a new chemical biology tool for the selective labeling of DNA modifications.
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