Thompson J , Begenisich T .

DE016960 NIDCR NIH HHS, R01 DE016960 NIDCR NIH HHS

	Figure 1. Open-state block of BK channels by the BP in K+ solutions. (Top inset) Time course of raw BK channel currents recorded in 100 µM Ca2+ in the absence (black) and presence (red) of 2 µM BP at the potentials indicated. Calibration: 0.4 nA, 50 msec. Zero-current level indicated by dashed line. (Main) Voltage dependence of BK channel activation (■) and fraction of channels not blocked by the BP (○) in 100 µM Ca2+. (Inset) Raw current recorded at + 60 mV from a holding potential of −80 mV in the absence (black) and presence (red) of 2 µM BP. Calibration: 2 nA, 50 msec. Zero-current level indicated by dashed line. (Boxed inset) Magnified view of the currents after repolarization to −80 mV, with the peak current in the BP scaled to match that of the control record. Calibration: 1 nA, 25 msec.
	Figure 2. Open-state block of BK channels by TBA in K+ solutions. (Top insets) Time course of raw BK channel currents recorded in 100 µM Ca2+ in the absence (black) and presence (red) of 10 mM TBA at the potentials indicated. Calibration: 0.4 nA, 50 msec. The zero-current level is indicated by the dashed line. (Main) Voltage dependence of BK channel activation in 100 µM Ca2+ (■) and in 10 µM Ca2+ (□). Also shown is the voltage dependence of the fraction of channels not blocked by 10 mM TBA in 100 µM Ca2+ (•) and in 10 µM Ca2+ (○). Solid lines, fits of the Boltzmann equation to the data; dashed lines, spline fits to the data.
	Figure 3. State-independent block of BK channels by TBA in Rb+ solutions. (A; insets) Time course of raw BK channel currents recorded in 100 µM Ca2+ in the absence (black) and presence (red) of 10 mM TBA at the potentials indicated. The voltage level before depolarization was −100 mV, and after the depolarization it was −80 mV (see Materials and methods). Calibration: 0.12 nA, 50 msec. Zero-current level indicated by dashed line. (Main) Steady-state current–voltage relation before (■), during (•), and after (□) the application of 10 mM TBA in Rb+ solutions. (B) Voltage dependence of BK channel activation (■) and fraction of channel not blocked by TBA (○) in 100 µM Ca2+.
	Figure 4. State-independent block of BK channels by TBA in Rb+ solutions. Pooled data. Voltage dependence of BK channel activation (■) and fraction of channels not blocked by TBA (○) in 100 µM Ca2+. Mean data shown with standard error limits if larger than symbol. Data from six to nine experiments, except n = 3 at −90 mV.
	Figure 5. Time course of BP block of BK channels in K+ and Rb+ solutions. Raw currents at the indicated potentials in the absence (black) and presence (red) of 2 µM BP recorded in 100 µM Ca2+ in K+ (left; calibration: 1.2 nA, 50 msec) and Rb+ (right; calibration: 0.25 nA, 50 msec) solutions. The holding potential for the K+ solutions was −80 mV. For the Rb+ solutions, the voltage level before depolarization was −100 mV, and after the depolarization it was −80 mV. The tail currents upon repolarization have been truncated for clarity.
	Figure 6. State-independent block of BK channels by BP in Rb+ solutions. (A; insets) Time course of raw BK channel currents recorded in 100 µM Ca2+ in the absence (black) and presence (red) of 2 µM BP at the potentials indicated. Calibration: 0.1 nA, 50 msec. (Main) Steady-state current–voltage relation before (■), during (•), and after (□) application of 2 µM BP in Rb+ solutions. (B) Voltage dependence of BK channel activation (■) and fraction of channels not blocked by BP (○) in 100 µM Ca2+. (Inset) BK currents in response to repolarization to −80 mV from +40 mV in the absence (black) and presence (red; average of four records) of 2 µM BP, with the peak current in the BP scaled to match that of the control record. Calibration: 0.2 nA, 10 msec.
	Figure 7. State-independent block of BK channels by BP in Rb+ solutions. Pooled data. Voltage dependence of BK channel activation (■) and fraction of channels not blocked by 2 µM BP (○) in 100 µM Ca2+. Mean values from four experiments shown with standard error limits if larger than symbol. (Inset) Voltage dependence of the time constant of deactivation in the absence (■) and presence (○) of the BP. Mean values from three experiments shown with standard error limits if larger than symbol.
	Figure 8. Open-state block of Shaker K channels by the BP in K+ and Rb+ solutions. (A) Block of Shaker channels by 2 µM BP in K+ solutions. (Top inset) Currents recorded at −40 mV from a holding potential of −100 mV in the absence (black) and presence (red) of 2 µM BP. Calibration: 0.2 nA, 100 msec. (Main) Voltage dependence of Shaker channel activation (■) and fraction of channels not blocked by 2 µM BP (○). (Inset) Shaker channel currents in response to repolarization to −100 mV (from +20 mV) in the absence (black) and presence (red) of 2 µM BP, with the peak current in the BP scaled to match that of the control record. Calibration: 0.75 nA, 20 msec. (B) Block of Shaker channels by 2 µM BP in Rb+ solutions. (Top inset) Currents recorded at −40 mV from a holding potential of −100 mV in the absence (black) and presence (red) of 2 µM BP. Calibration: 0.4 nA, 100 msec. (Main) Voltage dependence of Shaker channel activation (■) and fraction of channels not blocked by 0.5 µM BP (○). Mean values from three experiments shown with standard error limits if larger than symbol. (Inset) Shaker channel currents in response to repolarization to −120 mV (from +20 mV) in the absence (black) and presence (red) of 2 µM BP, with the peak current in the BP scaled to match that of the control record. Calibration: 1.2 nA, 20 msec. Dashed line in all insets represents the zero-current level.

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