An enzyme-free colorimetric assay using hybridization chain reaction amplification and split aptamers

Applications of hybridization chain reaction optical detection incorporating nanomaterials: A review

The development of powerful, simple and cost-effective signal amplifiers has significant implications for biological research and analysis. Hybridization chain reaction (HCR) has attracted increasing attention because of its enzyme-free, simple, and efficient amplification. In the HCR process, an initiator probe triggered a pair of metastable hairpins through a cross-opening process to propagate a chain reaction of hybridization events, yielding a long-nicked double-stranded nucleic acid structure. To achieve more noticeable signal amplification, nanomaterials, including graphene oxide, quantum dots, gold, silver, magnetic, and other nanoparticles, were integrated with HCR. Various types of colorimetric, fluorescence, plasmonic analyses or chemiluminescence optical sensing strategies incorporating nanomaterials have been developed to analyze various targets, such as nucleic acids, small biomolecules, proteins, and metal ions. This review summarized the recent advances of HCR technology pairing diverse nanomaterials in optical detection and discussed their challenges.

The Recent Development of Hybridization Chain Reaction Strategies in Biosensors

With the continuous development of biosensors, researchers have focused increasing attention on various signal amplification strategies to pursue superior performance for more applications. In comparison with other signal amplification strategies, hybridization chain reaction (HCR) as a powerful signal amplification technique shows its certain charm owing to nonenzymatic and isothermal features. Recently, on the basis of conventional HCR, this technique has been developed and improved rapidly, and a variety of HCR-based biosensors with excellent performance have been reported. Herein, we present a systematic and critical review on the research progress of HCR in biosensors in the last five years, including the newly developed HCR strategies such as multibranched HCR, migration HCR, localized HCR, in situ HCR, netlike HCR, and so on, as well as the combination strategies of HCR with isothermal signal amplification techniques, nanomaterials, and functional DNA molecules. By illustrating some representative works, we also summarize the advantage and challenge of HCR in biosensors, and offer a deep discussion of the latest progress and future development trends of HCR in biosensors.

Optical aptasensing of mercury(II) by using salt-induced and exonuclease I-induced gold nanoparticle aggregation under dark-field microscope observation

An optical method for determination of Hg(II) is described that exploits the aggregation of gold nanoparticles (AuNPs) under dark-field microscope (DFM) observation. This assay is based on the use of a Hg(II)-specific aptamer, AuNPs modified with complementary DNA strands, and exonuclease I (Exo I). In the absence of Hg(II), the added dsDNA prevents salt-induced aggregation of the green-colored AuNPs. If Hg(II) is added, the aptamer will capture it to form T-Hg(II)-T pairs, and the complementary strand is digested by Exo I. On addition of a solution of NaCl, the AuNPs will aggregate. This is accompanied by a color change from green to orange/red) in the dark-field image. By calculating the intensity of the orange/red dots in the dark-field image, concentration of Hg(II) can be accurately determined. The limit of detection is as low as 36 fM, and response is a linear in the 83 fM to 8.3 μM Hg(II) concentration range. Graphical abstract Schematic representation of a colorimetric assay for Hg(II) based on the use of a mercury(II)-specific aptamer, gold nanoparticles modified with complementary DNA strands, and exonuclease I.

Colorimetric human papillomavirus DNA assay based on the retardation of avidin-induced aggregation of gold nanoparticles

A colorimetric assay for human papillomavirus (HPV) DNA was developed based on the retardation of the avidin-induced aggregation of gold nanoparticles (AuNPs) by HPV DNA. Positively charged avidin acts as a coagulant for AuNP aggregation. In the presence of the target DNA, however, the aggregation of AuNPs is retarded owing to electrosteric stabilization as a result of the hybridization of the target and probe DNA. In the absence of HPV DNA, the stabilization effect caused by the biotinylated probe DNA is weak, resulting in NP aggregation and a color change from red to purple. Aggregation may be easily observed with bare eyes or spectrophotometrically at about 560 nm. The visual detection limit is 1 nM. The assay was used for the determination of HPV DNA after polymerase chain reaction (PCR) amplification without any further purification. Graphical abstract Schematic presentation of the avidin-induced aggregation of unmodified gold nanoparticles (AuNPs) which leads to a color change from red to purple. In the presence of dsDNA, however, the aggregation is remarkably retarded.

Evaluation of DNA Methyltransferase Activity and Inhibition via Isothermal Enzyme-Free Concatenated Hybridization Chain Reaction

Methyltransferase (MTase)-catalyzed DNA methylation plays a vital role in the biological epigenetic processes of key diseases and has attracted increasing attention, making the amplified detection of MTase activity of great significance in clinical disease diagnosis and treatment. Herein, we developed an isothermal, enzyme-free, and autonomous strategy for analyzing MTase activity based on concatenated hybridization chain reaction (C-HCR)-mediated Förster resonance energy transfer (FRET). In a typical C-HCR procedure without MTase (Dam), Y-shaped initiator DNA activates upstream HCR-1 to assemble a double-stranded DNA (dsDNA) copolymeric nanowire consisting of multiple tandem DNA trigger units that motivate downstream HCR-2 to successively bring a fluorophore donor/acceptor (FAM/TAMRA) pair into close proximity, leading to the generation of an amplified FRET readout signal. The target Dam MTase and auxiliary DpnI endonuclease can sequentially and specifically recognize/methylate and cleave the Y-shaped initiator oligonucleotide, respectively, and thus prohibit the C-HCR process and FRET signal generation, resulting in the construction of a signal-on sensing platform for MTase assay. Our proposed isothermal enzyme-free C-HCR amplification approach was further utilized for screening MTase inhibitors. Furthermore, the proposed C-HCR approach can be easily adapted for probing other different MTases and for screening the corresponding inhibitors just by changing the recognition sequence of Y-shaped initiator DNA through a "plug-and-play" format. It provides a versatile and robust tool for highly sensitive detection of various biotransformations and thus holds great promise in clinical assessment and diagnosis.