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Study on the Functionalization and Signaling Efficiency of the Hybridization Chain Reaction Using Traditional and Single Molecular Characterizations

Chunmiao Yu, Yesheng Wang, Ruiping Wu, Zhentong Zhu, Bingling Li

2021ACS Applied Bio Materials24 citationsDOI

Abstract

As an important enzyme-free amplifier, the hybridization chain reaction (HCR) uses an ssDNA to trigger cycled displacement interactions between substrate hairpins and finally form elongated dsDNA concatamer mixtures. In many cases, to provide a signal probe or advanced function, additional oligonucleotides (named hairpin tails) have to be extended upon classic HCR hairpin substrates, but by doing so the HCR assembly efficiency and signal-to-noise ratio (SNR) may get seriously reduced. In this Article, a rational and general model that may guide the study on HCR functionalization and signaling efficiency is provided. We rationally design a four-hairpin model HCR system (4H-HCR) in which one or more hairpin substrates are appended with additional tails as a signaling probe. After HCR assembly, two adjacent tails are supposedly integrating into a full G-quadruplex structure to provide the evidence or signal for the assembly. A systematic study has been applied to reveal the relationship between the "tail-design" with assembly efficiency and SNR. A clear design rule-set guiding the optimized assembly and signal has been provided for traditional electrophoresis and G-quadruplex-enhanced fluorescence signal. Importantly, solid-state nanopore single molecular detection has been innovatively introduced and recommended as an "antirisk" and "mutual benefit" readout to traditional G-quadruplex signaling. Nanopore detection can provide a clear signal distinguished before and after the HCR reaction, especially when the traditional G-quadruplex-enhanced signal only provides low SNR. The G-quadruplex, in turn, may enhance the nanopore signal amplitude via increasing the diameter of the HCR products.

Topics & Concepts

NanoporeG-quadruplexSIGNAL (programming language)OligonucleotideRational designChain reactionNanotechnologyBiological systemBiophysicsChemistryMaterials scienceComputational biologyComputer scienceCombinatorial chemistryDNABiologyBiochemistryProgramming languagePhotochemistryAdvanced biosensing and bioanalysis techniquesNanopore and Nanochannel Transport StudiesDNA and Nucleic Acid Chemistry
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