Saldigones A-C(1,3,4),three new isoprenylated flavonoids with diverse flavanone,pterocarpan,and isoflavanone architec-tures,were characterized from the roots of Salvia digitaloides,together with a known isoprenylated ...Saldigones A-C(1,3,4),three new isoprenylated flavonoids with diverse flavanone,pterocarpan,and isoflavanone architec-tures,were characterized from the roots of Salvia digitaloides,together with a known isoprenylated flavanone(2).Notably,it’s the first report of isoprenylated flavonoids from Salvia species.The structures of these isolates were elucidated by extensive spectroscopic analysis.All of the compounds were evaluated for their activities on Cav3.1 low voltage-gated Ca^(2+)channel(LVGCC),of which 2 strongly and dose-dependently inhibited Cav3.1 peak current.展开更多
T-type calcium channels exhibit fast voltage-dependent inactivation, for which the underlying struc- ture-function relationship still remains unclear. To investigate the roles of S4 segments in volt- age-dependent ina...T-type calcium channels exhibit fast voltage-dependent inactivation, for which the underlying struc- ture-function relationship still remains unclear. To investigate the roles of S4 segments in volt- age-dependent inactivation of T-type calcium channels, we created S4 replacement chimeras between Cav3.1 calcium channels (fast voltage-dependent inactivation) and Cav1.2 calcium channels (little voltage-dependent inactivation) by replacing S4s in Cav3.1 with the corresponding regions in Cav1.2. Wild type and chimeric channels were expressed in Xenopus oocytes and channel currents were re- corded with two-electrode voltage-clamp. We showed that replacing S4 region in domain I shifted voltage-dependence for inactivation of Cav3.1 to the left, and the V0.5 inact and kinact value were signifi- cantly changed. However replacing S4s in domains II―IV had no effects on the voltage-dependent in- activation properties. These results suggest that the roles of S4 segments in domains I―IV are different, and S4 in domain I is likely to be involved in voltage-dependent inactivation process. Its movement during membrane depolarization may trigger a conformational change in the inactivation gate.展开更多
基金the Foundation of Supported by National Natural Science Foundation of China(32070392 and 32070393)the Second Tibetan Plateau Scientific Expedition and Research(STEP)program(2019QZKK0502-0303).
文摘Saldigones A-C(1,3,4),three new isoprenylated flavonoids with diverse flavanone,pterocarpan,and isoflavanone architec-tures,were characterized from the roots of Salvia digitaloides,together with a known isoprenylated flavanone(2).Notably,it’s the first report of isoprenylated flavonoids from Salvia species.The structures of these isolates were elucidated by extensive spectroscopic analysis.All of the compounds were evaluated for their activities on Cav3.1 low voltage-gated Ca^(2+)channel(LVGCC),of which 2 strongly and dose-dependently inhibited Cav3.1 peak current.
文摘T-type calcium channels exhibit fast voltage-dependent inactivation, for which the underlying struc- ture-function relationship still remains unclear. To investigate the roles of S4 segments in volt- age-dependent inactivation of T-type calcium channels, we created S4 replacement chimeras between Cav3.1 calcium channels (fast voltage-dependent inactivation) and Cav1.2 calcium channels (little voltage-dependent inactivation) by replacing S4s in Cav3.1 with the corresponding regions in Cav1.2. Wild type and chimeric channels were expressed in Xenopus oocytes and channel currents were re- corded with two-electrode voltage-clamp. We showed that replacing S4 region in domain I shifted voltage-dependence for inactivation of Cav3.1 to the left, and the V0.5 inact and kinact value were signifi- cantly changed. However replacing S4s in domains II―IV had no effects on the voltage-dependent in- activation properties. These results suggest that the roles of S4 segments in domains I―IV are different, and S4 in domain I is likely to be involved in voltage-dependent inactivation process. Its movement during membrane depolarization may trigger a conformational change in the inactivation gate.
基金supported by grants from The National Natural Science Foundation of China(31371974,31071714)The Open Fund of Tianjin Key Laboratory of Animal and Plant Resistance~~