机构地区:[1]College of Chemistry, Sichuan University [2]Department of Laboratory Medicine, West China Hospital, Sichuan University and Collaborative Innovation Center
出 处:《Chinese Chemical Letters》2018年第3期531-534,共4页中国化学快报(英文版)
基 金:financially supported by the National Natural Science Foundation of China(No. 21475091);the Science andTechnology Department of Sichuan Province(No. 2015GZ0301)
摘 要:G-quadruplex ligands have been accepted as potential therapeutic agents for anticancer treatment. Thioflavin T (ThT), a highly selective G-quadruplex ligand, can bind G-quadruplex with a fluorescent light-up signal change and high specificity against DNA duplex. However, there are still different opinions that ThT induces/stabilizes G-quadruplex foldings/topologies in human telomere sequence. Here, a sensitive single-molecule nanopore technology was utilized to analyze the interactions between human telomeric DNA (Tel DNA) and ThT. Both translocation time and current blockade were measured to investigate the translocation behaviors. Furthermore, the effects of metal ion (K~ and Na~) and pH on the translocation behaviors were studied. Based on the single-molecule level analysis, there are some conclusions: (1) In the electrolyte solution containing 50 mmol/L I(Cl and 450 mmol/L NaCl, ThT can bind strongly with Tel DNA but nearly does not change the G-quadruplex form; (2) in the presence of high concentration K~, the ThT binding induces the structural change of hybrid G-quadruplex into antiparallel topology with an enhanced structural stability; (3) In either alkaline or acidic buffer, G-quadruplex form will change in certain degree. All above conclusions are helpful to deeply understand the interaction behaviors between Tel DNA and ThT. This nanopore platform, investigating G-quadruplex ligands at the single-molecule level, has great potential for the design of new drugs and sensors.G-quadruplex ligands have been accepted as potential therapeutic agents for anticancer treatment. Thioflavin T (ThT), a highly selective G-quadruplex ligand, can bind G-quadruplex with a fluorescent light-up signal change and high specificity against DNA duplex. However, there are still different opinions that ThT induces/stabilizes G-quadruplex foldings/topologies in human telomere sequence. Here, a sensitive single-molecule nanopore technology was utilized to analyze the interactions between human telomeric DNA (Tel DNA) and ThT. Both translocation time and current blockade were measured to investigate the translocation behaviors. Furthermore, the effects of metal ion (K~ and Na~) and pH on the translocation behaviors were studied. Based on the single-molecule level analysis, there are some conclusions: (1) In the electrolyte solution containing 50 mmol/L I(Cl and 450 mmol/L NaCl, ThT can bind strongly with Tel DNA but nearly does not change the G-quadruplex form; (2) in the presence of high concentration K~, the ThT binding induces the structural change of hybrid G-quadruplex into antiparallel topology with an enhanced structural stability; (3) In either alkaline or acidic buffer, G-quadruplex form will change in certain degree. All above conclusions are helpful to deeply understand the interaction behaviors between Tel DNA and ThT. This nanopore platform, investigating G-quadruplex ligands at the single-molecule level, has great potential for the design of new drugs and sensors.
关 键 词:α-Hemolysin nanopore Interaction Human telomere sequence Thioflavin T G-Quadruplex ligand
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