It is a great challenge to discover novel chemical reactions suitable for biological analysis in a living system.The development of novel protein thiol blocking agents is a crucial need for exploring protein thiol fun...It is a great challenge to discover novel chemical reactions suitable for biological analysis in a living system.The development of novel protein thiol blocking agents is a crucial need for exploring protein thiol functions in protein refolding,signal transduction,and redox regulation.We are always keen on seeking novel chemical reactions applied to endogenous biological macromolecules or protein thiol sensing,blocking,and labeling.In the present work,we have successfully developed a novel agent to block protein thiol by enhanced electron-withdrawing inductive effects.This sensing and blocking process was detailedly monitored by UV-vis,fluorescent spectra,and SDS-Page gel separation.The spectral studies demonstrated that the agent could react ultrafastly with thiol within seconds atμM level.Furthermore,fluorescent imaging in cells and in vivo was further used for the validation of its ability to sensing and blocking thiol,providing evidence of downregulated protein thiols in Parkinson's disease.The enhanced electronwithdrawing inductive effect strategy in this work may provide a general guideline for designing protein thiol agent.展开更多
Biological synthesis of quantum dots (QDs) as an environmental-friendly and facile preparation method has attracted increasing interests. However, it is difficult to distinguish the roles ofbio-thiols in QDs synthes...Biological synthesis of quantum dots (QDs) as an environmental-friendly and facile preparation method has attracted increasing interests. However, it is difficult to distinguish the roles ofbio-thiols in QDs synthesis process because of the complex nature in organisms. In this work, the CdSe QDs synthesis conditions in organisms were reconstructed by using a simplified in vitro approach to uncover the roles of two small bio-thiols in the QDs formation. CdSe QDs were synthesized with glutathione (GSH) and L-cysteine (Cys) respectively. Compared with Cys at the same molar concentration, the CdSe QDs synthesized by GSH had a larger and broader particle size distribution with improved optical properties and crystal structure. Furthermore, quantum chemical calculations indicate that the stronger Cd^2+ binding capacity ofGSH contributed a lot to the CdSe QDs formation despite ofthe greater capability Cys for selenite reduction. This work clearly demonstrates the different roles of small thiols in the Cd2^+- stabilization in the environment and biomimetic QDs synthesis process.展开更多
基金supported by the Natural Science Foundation of China(22376216,21778026,21701074,21976209 and 22204127)the program of the Youth Innovation Promotion Association,CAS(2019217)+3 种基金Taishan Scholar Project Special Funding(TS20190962)the Shenzhen Science and Technology Program(JCYJ20210324142612032)the Guangdong Basic and Applied Basic Research Foundation(2021A1515110906)the Natural Science Basic Research Program of Shaanxi(No.2022JQ-106).
文摘It is a great challenge to discover novel chemical reactions suitable for biological analysis in a living system.The development of novel protein thiol blocking agents is a crucial need for exploring protein thiol functions in protein refolding,signal transduction,and redox regulation.We are always keen on seeking novel chemical reactions applied to endogenous biological macromolecules or protein thiol sensing,blocking,and labeling.In the present work,we have successfully developed a novel agent to block protein thiol by enhanced electron-withdrawing inductive effects.This sensing and blocking process was detailedly monitored by UV-vis,fluorescent spectra,and SDS-Page gel separation.The spectral studies demonstrated that the agent could react ultrafastly with thiol within seconds atμM level.Furthermore,fluorescent imaging in cells and in vivo was further used for the validation of its ability to sensing and blocking thiol,providing evidence of downregulated protein thiols in Parkinson's disease.The enhanced electronwithdrawing inductive effect strategy in this work may provide a general guideline for designing protein thiol agent.
基金Project supported by the National Natural Science Foundation of China(No.21704032)the Natural Science Foundation of Hubei Province(No.2018CFB454)the Hubei Superior and Distinctive Discipline Group of “Mechatronics and Automobiles”(No.XKQ2019038)~~
基金Acknowledgements The work was supported by the National Natural Science Foundation of China (Grant No. 21590812), and the Collaborative Innovation Center of Suzhou Nano Science and Technology.
文摘Biological synthesis of quantum dots (QDs) as an environmental-friendly and facile preparation method has attracted increasing interests. However, it is difficult to distinguish the roles ofbio-thiols in QDs synthesis process because of the complex nature in organisms. In this work, the CdSe QDs synthesis conditions in organisms were reconstructed by using a simplified in vitro approach to uncover the roles of two small bio-thiols in the QDs formation. CdSe QDs were synthesized with glutathione (GSH) and L-cysteine (Cys) respectively. Compared with Cys at the same molar concentration, the CdSe QDs synthesized by GSH had a larger and broader particle size distribution with improved optical properties and crystal structure. Furthermore, quantum chemical calculations indicate that the stronger Cd^2+ binding capacity ofGSH contributed a lot to the CdSe QDs formation despite ofthe greater capability Cys for selenite reduction. This work clearly demonstrates the different roles of small thiols in the Cd2^+- stabilization in the environment and biomimetic QDs synthesis process.
