Identifying 5-Hydroxymethylcytosine without Sequence Specificity Using MOF-Derived MnOxSy Nanoflowers for Boosting Electrochemiluminescence.

Abstract

It is universally recognized that the quantification of DNA hydroxymethylation at random gene sequences still remains challenging. Herein, the highly sensitive identifying strategy of 5-hydroxymethylcytosine (5-hmC) without sequence specificity was achieved with a novel electrochemiluminescence (ECL) biosensor, which deftly integrated metal-organic framework (MOF)-derived amorphous MnOxSy nanoflowers (MnOxSy NFs) as a bifunctional co-reaction accelerator and cross-shaped DNA tracks as a well-regulated signal switch. Specifically, the target recognition process of 5-hmC was performed through specific chemical modification, where the hydroxymethyl sites were first aminated and then labeled with a 5'-carboxyl-functioned DNA walker, thus forming the target labeled DNA walker (5-ghmC-walker). Subsequently, the cross-shaped DNA tracks were ingeniously designed to endow the 5-ghmC-walker with continuous mechanical motion due to the long periodic linear alignment structure and well-regulated highly ordered interfaces. Furthermore, as a bifunctional co-reaction accelerator synthesized by in situ Mn-MOF template-sacrificing strategy, the MnOxSy NFs could promote the reduction of both dissolved O2 and S2O82-, remarkably boosting the ECL intensity of a peroxydisulfate (S2O82-) solution by 5.2 times compared to the pure S2O82- solution. Benefiting from specific target recognition and a dual-pathway strategy for boosting ECL, the proposed ECL platform can quantify 5-hmC with a wide linear range of 1 fM-1 nM and a low detection limit of 0.29 fM. This simple, highly sensitive strategy without sequence specificity provides a powerful platform for 5-hmC detection in the epigenetic study and disease pathogenesis.