Binary split fluorescent biosensor based on lettuce DNA aptamer for label-free and enzyme-free analysis of hepatitis B viral DNA

Abstract

Hepatitis B virus (HBV) acts as a severe public health threat, causing chronic liver diseases. Although the quantified evaluation of HBV infection can be obtained by estimating the capacity of the HBV DNA genome, it still lacks an effective and robust detection method without using enzymes or chemical labeling. Herein, we have designed a binary split fluorescent DNA aptasensor (bsFDA) by rationally splitting the lettuce aptamer into two functional DNA short chains and utilizing the HBV DNA segment complementary sequences (HDs). In this strategy, the bsFDA has been investigated to specifically recognize the HDs, forming a triplex DNA with the lettuce aptamer structure. Meanwhile, the turn-on fluorescence of bsFDA is obtained upon formation of a fluorescent complex between DFHO and the triplex DNA structure, allowing the enzyme-free, label-free, fast-responsive, and reliable fluorescence readout for detecting HDs and the potential HDs mutants. Moreover, bsFDA has been applied for spiked HDs analysis in different real matrixes, including human serum and cell lysate. The satisfactory recovery rates and reproducibility of the bsFDA reveal its potential detection efficacy for HDs analysis in biological samples. Overall, bsFDA holds great potential in developing functionalized aptasensors and realizing viral genome analysis in biological research.