Revealing and Resolving the Restrained Enzymatic Cleavage of DNA Self-Assembled Monolayers on Gold: Electrochemical Quantitation and ESI-MS Confirmation.
Xiaoyi GaoMingxi GengYunchao LiXinglin WangHua-Zhong YuPublished in: Analytical chemistry (2017)
Herein, we report a combined electrochemical and ESI-MS study of the enzymatic hydrolysis efficiency of DNA self-assembled monolayers (SAMs) on gold, platform systems for understanding nucleic acid surface chemistry, and for constructing DNA-based biosensors. Our electrochemical approach is based on the comparison of the amounts of surface-tethered DNA nucleotides before and after exonuclease I (Exo I) incubation using electrostatically bound [Ru(NH3)6]3+ as redox indicators. It is surprising to reveal that the hydrolysis efficiency of ssDNA SAMs does not depend on the packing density and base sequence, and that the cleavage ends with surface-bound shorter strands (9-13 mers). The ex-situ ESI-MS observations confirmed that the hydrolysis products for ssDNA SAMs (from 24 to 56 mers) are dominated with 10-15 mer fragments, in contrast to the complete digestion in solution. Such surface-restrained hydrolysis behavior is due to the steric hindrance of the underneath electrode to the Exo I/DNA binding, which is essential for the occurrence of Exo I-catalyzed processive cleavage. More importantly, we have shown that the hydrolysis efficiency of ssDNA SAMs can be remarkably improved by adopting long alkyl linkers (locating DNA strands further away from the substrates).
Keyphrases
- ms ms
- nucleic acid
- dna binding
- circulating tumor
- cell free
- single molecule
- mass spectrometry
- anaerobic digestion
- gold nanoparticles
- multiple sclerosis
- ionic liquid
- sars cov
- transcription factor
- label free
- risk assessment
- hydrogen peroxide
- room temperature
- magnetic resonance
- molecularly imprinted
- respiratory syndrome coronavirus
- computed tomography
- circulating tumor cells
- liquid chromatography
- dna methylation
- magnetic resonance imaging
- coronavirus disease
- tandem mass spectrometry
- high resolution
- carbon nanotubes