Of the meno presto model of prestin activity is provided in our recent publications (24,28). Briefly, the model is multistate; after chloride binding, a slow intermediate transition leads to a voltage-enabled state, which generates sensor charge movement. The delays afforded by its multistate nature underlie the model’s buy Brefeldin A frequency dependence. The only parameter that was modified to fit (by eye) the data in Fig. 4 was the model’s forward transition rate constant, k1, for Cl?binding. The kinetic diagram and description are reproduced in Fig. 2 (reproduced from our previous work (24)).RESULTS Fig. 1 C shows the group-averaged NLC determined from admittance measures (5.12 ms sampling rate) for OHCs XAV-939MedChemExpress XAV-939 recorded under 140 mM and 1 mM intracellular chloride conditions. NLC fits for the 1 mM Cl group yield Vh ??6.3 mV, Qmax ?2.2 pC, Clin ?21.84 pF, z ?0.71, and DCsa ?3.2 pF; those for the 140 mM Cl group PD-148515 biological activity yieldFIGURE 2 Kinetic model of the meno presto model. The Xsal state is bound by salicylate, but in this manuscript, salicylate is absent. The Xo state is unbound by an anion. The Xc state is bound by chloride, but the intrinsic voltage-sensor charge is not responsive to the membrane electric field. A slow, multiexponential conformational transition to the Xd state via Xn states enables voltage sensing within the electric field. Depolarization moves the positive sensor charge outward, simultaneously resulting in the compact state, C, which corresponds to cell contraction. Parameters and differential equations are provided in (24).Vh ??2.3 mV, Qmax ?3.1 pC, Clin ?24.24 pF, z ?0.80, and DCsa ?2.1 pF. Fig. 1 D shows voltage-sensor displacement currents after the offset of voltage steps extracted by subtraction of scaled difference currents evoked between the potential of ?0 and ?00 mV, in an attempt to Stattic site remove linear capacitive currents, as is required for gating/displacement current extraction (29). Clear chloride differences exist, consistent with expectations. However, because Cm plots show that substantial NLC resides at these subtraction voltages, these displacement currents are inaccurate. We and others have studied OHC/prestin displacement currents for decades (12,30?3); however, because of the shallow voltage dependence of prestin (z 0.75), extracted waveforms and estimates of Qmax using P/N subtraction holding potentials, typically 40?0 mV, were adversely affected in those studies. Extraction of the sensor charge using Eq. 2 (see Materials and Methods) overcomes this problem in determining Qmax. Fig. 1 E shows that determining Qmax with either AC analysis or this time-domain approach produces equivalent results. Fig. 3, A and B, shows group averages of both peak NLC (Cv) and linear capacitance as a function of interrogation frequency. Our success at stray capacitance compensation is borne out by the frequency independence of OHC linear capacitance provided by fits to the Cm data (Fig. 3 B). Interestingly, however, NLC shows a marked frequency dependence, with larger magnitudes as interrogating frequency decreases (Fig. 3 A). In fact, the frequency-dependent trend in Cm data suggests that NLC at frequencies lower than our lowest primary interrogating frequency of 195.3 Hz would be larger. The Boltzmann parameters Vh and z are stable across frequency (Fig. 3, C and D). To better compare our measures across cells within the two chloride conditions, we converted our measures to specific nonlinear charge (Qsp in pC/pF), thereby normalizing for su.Of the meno presto model of prestin activity is provided in our recent publications (24,28). Briefly, the model is multistate; after chloride binding, a slow intermediate transition leads to a voltage-enabled state, which generates sensor charge movement. The delays afforded by its multistate nature underlie the model’s frequency dependence. The only parameter that was modified to fit (by eye) the data in Fig. 4 was the model’s forward transition rate constant, k1, for Cl?binding. The kinetic diagram and description are reproduced in Fig. 2 (reproduced from our previous work (24)).RESULTS Fig. 1 C shows the group-averaged NLC determined from admittance measures (5.12 ms sampling rate) for OHCs recorded under 140 mM and 1 mM intracellular chloride conditions. NLC fits for the 1 mM Cl group yield Vh ??6.3 mV, Qmax ?2.2 pC, Clin ?21.84 pF, z ?0.71, and DCsa ?3.2 pF; those for the 140 mM Cl group yieldFIGURE 2 Kinetic model of the meno presto model. The Xsal state is bound by salicylate, but in this manuscript, salicylate is absent. The Xo state is unbound by an anion. The Xc state is bound by chloride, but the intrinsic voltage-sensor charge is not responsive to the membrane electric field. A slow, multiexponential conformational transition to the Xd state via Xn states enables voltage sensing within the electric field. Depolarization moves the positive sensor charge outward, simultaneously resulting in the compact state, C, which corresponds to cell contraction. Parameters and differential equations are provided in (24).Vh ??2.3 mV, Qmax ?3.1 pC, Clin ?24.24 pF, z ?0.80, and DCsa ?2.1 pF. Fig. 1 D shows voltage-sensor displacement currents after the offset of voltage steps extracted by subtraction of scaled difference currents evoked between the potential of ?0 and ?00 mV, in an attempt to remove linear capacitive currents, as is required for gating/displacement current extraction (29). Clear chloride differences exist, consistent with expectations. However, because Cm plots show that substantial NLC resides at these subtraction voltages, these displacement currents are inaccurate. We and others have studied OHC/prestin displacement currents for decades (12,30?3); however, because of the shallow voltage dependence of prestin (z 0.75), extracted waveforms and estimates of Qmax using P/N subtraction holding potentials, typically 40?0 mV, were adversely affected in those studies. Extraction of the sensor charge using Eq. 2 (see Materials and Methods) overcomes this problem in determining Qmax. Fig. 1 E shows that determining Qmax with either AC analysis or this time-domain approach produces equivalent results. Fig. 3, A and B, shows group averages of both peak NLC (Cv) and linear capacitance as a function of interrogation frequency. Our success at stray capacitance compensation is borne out by the frequency independence of OHC linear capacitance provided by fits to the Cm data (Fig. 3 B). Interestingly, however, NLC shows a marked frequency dependence, with larger magnitudes as interrogating frequency decreases (Fig. 3 A). In fact, the frequency-dependent trend in Cm data suggests that NLC at frequencies lower than our lowest primary interrogating frequency of 195.3 Hz would be larger. The Boltzmann parameters Vh and z are stable across frequency (Fig. 3, C and D). To better compare our measures across cells within the two chloride conditions, we converted our measures to specific nonlinear charge (Qsp in pC/pF), thereby normalizing for su.Of the meno presto model of prestin activity is provided in our recent publications (24,28). Briefly, the model is multistate; after chloride binding, a slow intermediate transition leads to a voltage-enabled state, which generates sensor charge movement. The delays afforded by its multistate nature underlie the model’s frequency dependence. The only parameter that was modified to fit (by eye) the data in Fig. 4 was the model’s forward transition rate constant, k1, for Cl?binding. The kinetic diagram and description are reproduced in Fig. 2 (reproduced from our previous work (24)).RESULTS Fig. 1 C shows the group-averaged NLC determined from admittance measures (5.12 ms sampling rate) for OHCs recorded under 140 mM and 1 mM intracellular chloride conditions. NLC fits for the 1 mM Cl group yield Vh ??6.3 mV, Qmax ?2.2 pC, Clin ?21.84 pF, z ?0.71, and DCsa ?3.2 pF; those for the 140 mM Cl group yieldFIGURE 2 Kinetic model of the meno presto model. The Xsal state is bound by salicylate, but in this manuscript, salicylate is absent. The Xo state is unbound by an anion. The Xc state is bound by chloride, but the intrinsic voltage-sensor charge is not responsive to the membrane electric field. A slow, multiexponential conformational transition to the Xd state via Xn states enables voltage sensing within the electric field. Depolarization moves the positive sensor charge outward, simultaneously resulting in the compact state, C, which corresponds to cell contraction. Parameters and differential equations are provided in (24).Vh ??2.3 mV, Qmax ?3.1 pC, Clin ?24.24 pF, z ?0.80, and DCsa ?2.1 pF. Fig. 1 D shows voltage-sensor displacement currents after the offset of voltage steps extracted by subtraction of scaled difference currents evoked between the potential of ?0 and ?00 mV, in an attempt to remove linear capacitive currents, as is required for gating/displacement current extraction (29). Clear chloride differences exist, consistent with expectations. However, because Cm plots show that substantial NLC resides at these subtraction voltages, these displacement currents are inaccurate. We and others have studied OHC/prestin displacement currents for decades (12,30?3); however, because of the shallow voltage dependence of prestin (z 0.75), extracted waveforms and estimates of Qmax using P/N subtraction holding potentials, typically 40?0 mV, were adversely affected in those studies. Extraction of the sensor charge using Eq. 2 (see Materials and Methods) overcomes this problem in determining Qmax. Fig. 1 E shows that determining Qmax with either AC analysis or this time-domain approach produces equivalent results. Fig. 3, A and B, shows group averages of both peak NLC (Cv) and linear capacitance as a function of interrogation frequency. Our success at stray capacitance compensation is borne out by the frequency independence of OHC linear capacitance provided by fits to the Cm data (Fig. 3 B). Interestingly, however, NLC shows a marked frequency dependence, with larger magnitudes as interrogating frequency decreases (Fig. 3 A). In fact, the frequency-dependent trend in Cm data suggests that NLC at frequencies lower than our lowest primary interrogating frequency of 195.3 Hz would be larger. The Boltzmann parameters Vh and z are stable across frequency (Fig. 3, C and D). To better compare our measures across cells within the two chloride conditions, we converted our measures to specific nonlinear charge (Qsp in pC/pF), thereby normalizing for su.Of the meno presto model of prestin activity is provided in our recent publications (24,28). Briefly, the model is multistate; after chloride binding, a slow intermediate transition leads to a voltage-enabled state, which generates sensor charge movement. The delays afforded by its multistate nature underlie the model’s frequency dependence. The only parameter that was modified to fit (by eye) the data in Fig. 4 was the model’s forward transition rate constant, k1, for Cl?binding. The kinetic diagram and description are reproduced in Fig. 2 (reproduced from our previous work (24)).RESULTS Fig. 1 C shows the group-averaged NLC determined from admittance measures (5.12 ms sampling rate) for OHCs recorded under 140 mM and 1 mM intracellular chloride conditions. NLC fits for the 1 mM Cl group yield Vh ??6.3 mV, Qmax ?2.2 pC, Clin ?21.84 pF, z ?0.71, and DCsa ?3.2 pF; those for the 140 mM Cl group yieldFIGURE 2 Kinetic model of the meno presto model. The Xsal state is bound by salicylate, but in this manuscript, salicylate is absent. The Xo state is unbound by an anion. The Xc state is bound by chloride, but the intrinsic voltage-sensor charge is not responsive to the membrane electric field. A slow, multiexponential conformational transition to the Xd state via Xn states enables voltage sensing within the electric field. Depolarization moves the positive sensor charge outward, simultaneously resulting in the compact state, C, which corresponds to cell contraction. Parameters and differential equations are provided in (24).Vh ??2.3 mV, Qmax ?3.1 pC, Clin ?24.24 pF, z ?0.80, and DCsa ?2.1 pF. Fig. 1 D shows voltage-sensor displacement currents after the offset of voltage steps extracted by subtraction of scaled difference currents evoked between the potential of ?0 and ?00 mV, in an attempt to remove linear capacitive currents, as is required for gating/displacement current extraction (29). Clear chloride differences exist, consistent with expectations. However, because Cm plots show that substantial NLC resides at these subtraction voltages, these displacement currents are inaccurate. We and others have studied OHC/prestin displacement currents for decades (12,30?3); however, because of the shallow voltage dependence of prestin (z 0.75), extracted waveforms and estimates of Qmax using P/N subtraction holding potentials, typically 40?0 mV, were adversely affected in those studies. Extraction of the sensor charge using Eq. 2 (see Materials and Methods) overcomes this problem in determining Qmax. Fig. 1 E shows that determining Qmax with either AC analysis or this time-domain approach produces equivalent results. Fig. 3, A and B, shows group averages of both peak NLC (Cv) and linear capacitance as a function of interrogation frequency. Our success at stray capacitance compensation is borne out by the frequency independence of OHC linear capacitance provided by fits to the Cm data (Fig. 3 B). Interestingly, however, NLC shows a marked frequency dependence, with larger magnitudes as interrogating frequency decreases (Fig. 3 A). In fact, the frequency-dependent trend in Cm data suggests that NLC at frequencies lower than our lowest primary interrogating frequency of 195.3 Hz would be larger. The Boltzmann parameters Vh and z are stable across frequency (Fig. 3, C and D). To better compare our measures across cells within the two chloride conditions, we converted our measures to specific nonlinear charge (Qsp in pC/pF), thereby normalizing for su.