Ill equation as in Fig. 7A. The IC50s (at 0.2 Hz

August 28, 2017

Ill equation as in Fig. 7A. The IC50s (at 0.2 Hz) of acacetin in inhibiting hKv4.3 currents were 7.9 mM for WT, 44.5 mM for T366, 25.8 mM for T367A, 17.6 mM for V392A, 16.2 mM for I395A, and 19.1 mM for V399A, respectively. These results suggest that T366 and T367 in the P-loop helix, V392, I395, and V399 in the S-6 segment are the molecular determinants 25033180 of channel blocking by acacetin (Fig. 7B).Figure 5. Use- and MedChemExpress MC-LR frequency-dependent inhibition of hKv4.3 current by acacetin. A. hKv4.3 current traces recorded in a representative cell with a 200-ms pulse at 3.3 Hz before (control) and after application 3 mM acacetin. B. Mean percentage values of usedependent inhibition of hKv4.3 current (at +50 mV) by 3 mM acacetin at 0.2, 1, 2, and 3.3 Hz. C. Concentration-response relationship curves of acacetin for inhibiting hKv4.3 current at 20th pulse were fitted to Hill equation to obtain IC50 (n = 7?5 experiments for each concentration or frequency) at frequencies of 0.2?.3 Hz. doi:10.1371/journal.pone.0057864.gDiscussionThe present study demonstrates that the natural flavone acacetin inhibits hKv4.3 SMER-28 chemical information channels stably expressed in HEK 293 cells in a use- and frequency-dependent manner by binding to not only the open state of the channels, but also the closed channels. The effect of acacetin for blocking hKv4.3 current was enhanced as the stimulus frequency was increased from 0.2 Hz (IC50 = 7.9 mM) to 3.3 Hz (IC50 = 3.2 mM). The efficacy at 0.2 Hz is close to that for inhibiting human atrial Ito (IC50 = 9.3 mM) [16]. In addition to the use- and frequency-dependent effect, the open channel blocking property of acacetin was reflected in the reduced time to peak of the current activation and the decreased time constant of Kv4.3 current inactivation. This indicates that acacetinAcacetin Blocks hKv4.3 ChannelsFigure 6. Effects of acacetin on WT and mutant hKv4.3 currents. A. Current traces recorded in HEK 293 cells expressing WT, T366A, T367A, V392A, I395A, and V399A hKv4.3 channels, respectively, with a 300-ms voltage step to +50 mV from a holding potential of 280 mV before (control) and after 30 mM acacetin treatment for 5 min. The arrows indicate the current inhibition levels. B. Mean percent inhibition of WT and mutant hKv4.3 currents by 30 mM acacetin (n = 12 for control, n = 5? for each mutant; *P,0.05, **P,0.01 vs. WT). doi:10.1371/journal.pone.0057864.gFigure 7. Molecular determinants of hKv4.3 channel block by acacetin. A. Concentration-response relationship curves were fitted to the Hill equation to obtain the IC50s of acacetin for inhibiting WT and mutant hKv4.3 channels as shown in the inset (n = 5?2 for each concentration). B. Schematic graph showing the putative binding sites of acacetin at T366, T367 in the P-loop helix and V392, I395, and V399 in the S6-segment of Kv4.3 channels. doi:10.1371/journal.pone.0057864.gmay quickly bind to the channels when they open. The open channel property of acacetin is further supported by the slowed recovery of hKv4.3 channels from inactivation and the positive shift of g/gmax of the channel activation. This is different from the Kv4.3 blocker allitridi that also binds to the open state of the channel, but does not show a slowed recovery from inactivation and use- and frequency-dependent effect [23], which may be related to that acacetin is not a pure open channel blocker for hKv4.3 channels. Acacetin also inhibits the closed channels, which is reflected in the remarkable suppression of the current activat.Ill equation as in Fig. 7A. The IC50s (at 0.2 Hz) of acacetin in inhibiting hKv4.3 currents were 7.9 mM for WT, 44.5 mM for T366, 25.8 mM for T367A, 17.6 mM for V392A, 16.2 mM for I395A, and 19.1 mM for V399A, respectively. These results suggest that T366 and T367 in the P-loop helix, V392, I395, and V399 in the S-6 segment are the molecular determinants 25033180 of channel blocking by acacetin (Fig. 7B).Figure 5. Use- and frequency-dependent inhibition of hKv4.3 current by acacetin. A. hKv4.3 current traces recorded in a representative cell with a 200-ms pulse at 3.3 Hz before (control) and after application 3 mM acacetin. B. Mean percentage values of usedependent inhibition of hKv4.3 current (at +50 mV) by 3 mM acacetin at 0.2, 1, 2, and 3.3 Hz. C. Concentration-response relationship curves of acacetin for inhibiting hKv4.3 current at 20th pulse were fitted to Hill equation to obtain IC50 (n = 7?5 experiments for each concentration or frequency) at frequencies of 0.2?.3 Hz. doi:10.1371/journal.pone.0057864.gDiscussionThe present study demonstrates that the natural flavone acacetin inhibits hKv4.3 channels stably expressed in HEK 293 cells in a use- and frequency-dependent manner by binding to not only the open state of the channels, but also the closed channels. The effect of acacetin for blocking hKv4.3 current was enhanced as the stimulus frequency was increased from 0.2 Hz (IC50 = 7.9 mM) to 3.3 Hz (IC50 = 3.2 mM). The efficacy at 0.2 Hz is close to that for inhibiting human atrial Ito (IC50 = 9.3 mM) [16]. In addition to the use- and frequency-dependent effect, the open channel blocking property of acacetin was reflected in the reduced time to peak of the current activation and the decreased time constant of Kv4.3 current inactivation. This indicates that acacetinAcacetin Blocks hKv4.3 ChannelsFigure 6. Effects of acacetin on WT and mutant hKv4.3 currents. A. Current traces recorded in HEK 293 cells expressing WT, T366A, T367A, V392A, I395A, and V399A hKv4.3 channels, respectively, with a 300-ms voltage step to +50 mV from a holding potential of 280 mV before (control) and after 30 mM acacetin treatment for 5 min. The arrows indicate the current inhibition levels. B. Mean percent inhibition of WT and mutant hKv4.3 currents by 30 mM acacetin (n = 12 for control, n = 5? for each mutant; *P,0.05, **P,0.01 vs. WT). doi:10.1371/journal.pone.0057864.gFigure 7. Molecular determinants of hKv4.3 channel block by acacetin. A. Concentration-response relationship curves were fitted to the Hill equation to obtain the IC50s of acacetin for inhibiting WT and mutant hKv4.3 channels as shown in the inset (n = 5?2 for each concentration). B. Schematic graph showing the putative binding sites of acacetin at T366, T367 in the P-loop helix and V392, I395, and V399 in the S6-segment of Kv4.3 channels. doi:10.1371/journal.pone.0057864.gmay quickly bind to the channels when they open. The open channel property of acacetin is further supported by the slowed recovery of hKv4.3 channels from inactivation and the positive shift of g/gmax of the channel activation. This is different from the Kv4.3 blocker allitridi that also binds to the open state of the channel, but does not show a slowed recovery from inactivation and use- and frequency-dependent effect [23], which may be related to that acacetin is not a pure open channel blocker for hKv4.3 channels. Acacetin also inhibits the closed channels, which is reflected in the remarkable suppression of the current activat.