Your search keyword '"Zekun YANG"' showing total 3 results

1. Nanopore-based DNA-probe sequence-evolution method unveiling characteristics of protein-DNA binding phenomena in a nanoscale confined space

Author

Pengcheng Gao, Xiaoding Lou, Fan Xia, Ruizuo Hou, Zekun Yang, Juntao Zhang, Benmei Wei, and Nannan Liu

Subjects

Binding Sites, Base Sequence, Hybridization probe, Proteins, Nanotechnology, Sequence (biology), DNA, Space (mathematics), Analytical Chemistry, chemistry.chemical_compound, Nanopore, Nanopores, chemistry, Biophysics, Binding site, DNA Probes, Nanoscopic scale, Confined space

Abstract

Almost all of the important functions of DNA are realized by proteins which interact with specific DNA, which actually happens in a limited space. However, most of the studies about the protein–DNA binding are in an unconfined space. Here, we propose a new method, nanopore-based DNA-probe sequence-evolution (NDPSE), which includes up to 6 different DNA-probe systems successively designed in a nanoscale confined space which unveil the more realistic characteristics of protein–DNA binding phenomena. There are several features; for example, first, the edge-hindrance and core-hindrance contribute differently for the binding events, and second, there is an equilibrium between protein–DNA binding and DNA–DNA hybridization.

Published

2015

2. Regulation of DNA self-assembly and DNA hybridization by chiral molecules with corresponding biosensor applications

Author

Benmei Wei, Xiaoding Lou, Juntao Zhang, Nannan Liu, Zekun Yang, Xiaowen Ou, Ruixue Duan, and Fan Xia

Subjects

Chemistry, Stereochemistry, Surface Properties, DNA–DNA hybridization, Nucleic Acid Hybridization, Stereoisomerism, Biosensing Techniques, DNA, Electrochemical Techniques, Analytical Chemistry, Methylene Blue, chemistry.chemical_compound, Covalent bond, Limit of Detection, Nucleic acid, Biophysics, Molecule, Self-assembly, Cysteine, Gold, Chirality (chemistry), Biosensor

Abstract

Chirality is one of the fundamental biochemical properties in a living system, and a lot of biological and physiological processes are greatly influenced by the chirality of molecules. Inspired by this phenomenon, we study the covalent assembly of DNA on chiral molecule modified surfaces and further discuss the hybridization of DNA on chiral surfaces with nucleic acids. Take methylene blue (MB) modified DNA as a model molecule, we show that the peak current of the L-NIBC (NIBC, N-isobutyryl-L(D)-cysteine) modified gold surface (L-surface) is larger than the D-surface because of a stronger interaction between short-chain DNA and the L-surface; however, the D-surface has a higher hybridization efficiency than the L-surface. Moreover, we apply this result to actual application by choosing an electrochemical DNA (E-DNA) sensor as a potential platform. Furthermore, we further amplify the difference of hybridization efficiency using the supersandwich assay. More importantly, our findings are successfully employed to program the sensitivity and limit of detection.

Published

2015

3. Nanopore-Based DNA-Probe Sequence-Evolution Method Unveiling Characteristics of Protein--DNA Binding Phenomena in a Nanoscale Confined Space.

Author

Nannan Liu, Zekun Yang, Xiaoding Lou, Benmei Wei, Juntao Zhang, Pengcheng Gao, Ruizuo Hou, and Fan Xia

Subjects

*NANOPORES, *DEOXYRIBONUCLEOTIDES, *RNA probes, *NUCLEIC acid probes, *COMPLEMENTARY RNA

Abstract

Almost all of the important functions of DNA are realized by proteins which interact with specific DNA, which actually happens in a limited space. However, most of the studies about the protein-DNA binding are in an unconfined space. Here, we propose a new method, nanopore-based DNA-probe sequence-evolution (NDPSE), which includes up to 6 different DNA-probe systems successively designed in a nanoscale confined space which unveil the more realistic characteristics of protein-DNA binding phenomena. There are several features; for example, first, the edge-hindrance and core-hindrance contribute differently for the binding events, and second, there is an equilibrium between protein-DNA binding and DNA-DNA hybridization. [ABSTRACT FROM AUTHOR]

Published

2015