Membrane tension plays a crucial role in various fundamental cellular processes,with one notable example being the T cell-mediated elimination of tumor cells through perforin-induced membrane perforation by amplifying...Membrane tension plays a crucial role in various fundamental cellular processes,with one notable example being the T cell-mediated elimination of tumor cells through perforin-induced membrane perforation by amplifying cellular force.However,the mechanisms governing the regulation of biomolecular activities at the cell interface by membrane tension remain elusive.In this study,we investigated the correlation between membrane tension and poration activity of melittin,a prototypical pore-forming peptide,using dynamic giant unilamellar vesicle leakage assays combined with flickering tension analysis,molecular dynamics simulations,and live cell assays.The results demonstrate that an increase in membrane tension enhances the activity of melittin,particularly near its critical pore-forming concentration.Moreover,peptide actions such as binding,insertion,and aggregation in the membrane further influence the evolution of membrane tension.Live cell experiments reveal that artificially enhancing membrane tension effectively enhances melittin’s ability to induce pore formation and disrupt membranes,resulting in up to a ten-fold increase in A549 cell mortality when exposed to a concentration of 2.0-μg·mL^(-1)melittin.Our findings elucidate the relationship between membrane tension and the mechanism of action as well as pore-forming efficiency of melittin,while providing a practical mechanical approach for regulating functional activity of molecules at the cell-membrane interface.展开更多
The vesicle structures of egg yolks phosphatidylcholine/didodecyldimethylammonium bromide (1 : 1, mass ratio) deposited on mica were studied by atomic force microscopy (AFM) both in aqueous phase and air. In aque...The vesicle structures of egg yolks phosphatidylcholine/didodecyldimethylammonium bromide (1 : 1, mass ratio) deposited on mica were studied by atomic force microscopy (AFM) both in aqueous phase and air. In aqueous phase both bilayer and domelike vesicles with a mean diameter of 45 nm were observed, whereas in air the structure was more complicated depending on the initial concentration of vesicles. Vesicles with the original size could only be visualized at very low concentration with a mean diameter of 55 nm, which is a little larger than the result obtained in aqueous phase. At higher concentrations, fused large aggregates and multiple bilayer with a thickness ca. 4 nm of each bilayer were dominated. A plausible adsorption mechanism was proposed based on the experimental results.展开更多
基金supported by the National Natural Science Foundation of China(Grant Nos.12274307,32230063,21774092,and 12347102)the Basic and Applied Basic Research Foundation of Guangdong Province,China(Grant No.2023A1515011610).
文摘Membrane tension plays a crucial role in various fundamental cellular processes,with one notable example being the T cell-mediated elimination of tumor cells through perforin-induced membrane perforation by amplifying cellular force.However,the mechanisms governing the regulation of biomolecular activities at the cell interface by membrane tension remain elusive.In this study,we investigated the correlation between membrane tension and poration activity of melittin,a prototypical pore-forming peptide,using dynamic giant unilamellar vesicle leakage assays combined with flickering tension analysis,molecular dynamics simulations,and live cell assays.The results demonstrate that an increase in membrane tension enhances the activity of melittin,particularly near its critical pore-forming concentration.Moreover,peptide actions such as binding,insertion,and aggregation in the membrane further influence the evolution of membrane tension.Live cell experiments reveal that artificially enhancing membrane tension effectively enhances melittin’s ability to induce pore formation and disrupt membranes,resulting in up to a ten-fold increase in A549 cell mortality when exposed to a concentration of 2.0-μg·mL^(-1)melittin.Our findings elucidate the relationship between membrane tension and the mechanism of action as well as pore-forming efficiency of melittin,while providing a practical mechanical approach for regulating functional activity of molecules at the cell-membrane interface.
基金Project supported by the National Natural Science Foundation of China (No. 20573079), The authors are grateful to Prof. Daiwen PANG and Dr. Zhexue LU of Department of Chemistry of Wuhan University, Wuhan, for their kindly help in the AFM measurements.
文摘The vesicle structures of egg yolks phosphatidylcholine/didodecyldimethylammonium bromide (1 : 1, mass ratio) deposited on mica were studied by atomic force microscopy (AFM) both in aqueous phase and air. In aqueous phase both bilayer and domelike vesicles with a mean diameter of 45 nm were observed, whereas in air the structure was more complicated depending on the initial concentration of vesicles. Vesicles with the original size could only be visualized at very low concentration with a mean diameter of 55 nm, which is a little larger than the result obtained in aqueous phase. At higher concentrations, fused large aggregates and multiple bilayer with a thickness ca. 4 nm of each bilayer were dominated. A plausible adsorption mechanism was proposed based on the experimental results.
