scholarly journals Modification of inactivation in cardiac sodium channels: ionic current studies with Anthopleurin-A toxin.

1995 ◽  
Vol 106 (4) ◽  
pp. 601-616 ◽  
Author(s):  
D A Hanck ◽  
M F Sheets
Keyword(s):  
Steady State ◽  
Sodium Channels ◽  
Time Course ◽  
Sodium Current ◽  
Ionic Current ◽  
Na Channel ◽  
Channel Activation ◽  
Time To Peak ◽  
Cardiac Purkinje Cells ◽  
Cardiac Sodium Channels

The site 3 toxin, Anthopleurin-A (Ap-A), was used to modify inactivation of sodium channels in voltage-clamped single canine cardiac Purkinje cells at approximately 12 degrees C. Although Ap-A toxin markedly prolonged decay of sodium current (INa) in response to step depolarizations, there was only a minor hyperpolarizing shift by 2.5 +/- 1.7 mV (n = 13) of the half-point of the peak conductance-voltage relationship with a slight steepening of the relationship from -8.2 +/- 0.8 mV to -7.2 +/- 0.8 mV (n = 13). Increases in Gmax were dependent on the choice of cation used as a Na substitute intracellularly and ranged between 26 +/- 15% (Cs, n = 5) to 77 +/- 19% (TMA, n = 8). Associated with Ap-A toxin modification time to peak INa occurred later, but analysis of the time course INa at multiple potentials showed that the largest effects were on inactivation with only a small effect on activation. Consistent with little change in Na channel activation by Ap-A toxin, INa tail current relaxations at very negative potentials, where the dominant process of current relaxation is deactivation, were similar in control and after toxin modification. The time course of the development of inactivation after Ap-A toxin modification was dramatically prolonged at positive potentials where Na channels open. However, it was not prolonged after Ap-A toxin at negative potentials, where channels predominately inactivate directly from closed states. Steady state voltage-dependent availability (h infinity or steady state inactivation), which predominately reflects the voltage dependence of closed-closed transitions equilibrating with closed-inactivated transitions was shifted in the depolarizing direction by only 1.9 +/- 0.8 mV (n = 8) after toxin modification. The slope factor changed from 7.2 +/- 0.8 to 9.9 +/- 0.9 mV (n = 8), consistent with a prolongation of inactivation from the open state of Ap-A toxin modified channels at more depolarized potentials. We conclude that Ap-A selectively modifies Na channel inactivation from the open state with little effect on channel activation or on inactivation from closed state(s).

scholarly journals Voltage-dependent open-state inactivation of cardiac sodium channels: gating current studies with Anthopleurin-A toxin.

1995 ◽  
Vol 106 (4) ◽  
pp. 617-640 ◽  
Author(s):  
M F Sheets ◽  
D A Hanck
Keyword(s):  
Time Course ◽  
Voltage Dependence ◽  
Na Channel ◽  
Total Charge ◽  
Na Channels ◽  
Gating Currents ◽  
Gating Charge ◽  
Cardiac Purkinje Cells ◽  
Voltage Dependent ◽  
Cardiac Sodium Channels

The gating charge and voltage dependence of the open state to the inactivated state (O-->I) transition was measured for the voltage-dependent mammalian cardiac Na channel. Using the site 3 toxin, Anthopleurin-A (Ap-A), which selectively modifies the O-->I transition (see Hanck, D. A., and M. F. Sheets. 1995. Journal of General Physiology. 106:601-616), we studied Na channel gating currents (Ig) in voltage-clamped single canine cardiac Purkinje cells at approximately 12 degrees C. Comparison of Ig recorded in response to step depolarizations before and after modification by Ap-A toxin showed that toxin-modified gating currents decayed faster and had decreased initial amplitudes. The predominate change in the charge-voltage (Q-V) relationship was a reduction in gating charge at positive potentials such that Qmax was reduced by 33%, and the difference between charge measured in Ap-A toxin and in control represented the gating charge associated with Na channels undergoing inactivation by O-->I. By comparing the time course of channel activation (represented by the gating charge measured in Ap-A toxin) and gating charge associated with the O-->I transition (difference between control and Ap-A charge), the influence of activation on the time course of inactivation could be accounted for and the inherent voltage dependence of the O-->I transition determined. The O-->I transition for cardiac Na channels had a valence of 0.75 e-. The total charge of the cardiac voltage-gated Na channel was estimated to be 5 e-. Because charge is concentrated near the opening transition for this isoform of the channel, the time constant of the O-->I transition at 0 mV could also be estimated (0.53 ms, approximately 12 degrees C). Prediction of the mean channel open time-voltage relationship based upon the magnitude and valence of the O-->C and O-->I rate constants from INa and Ig data matched data previously reported from single Na channel studies in heart at the same temperature.

Is there a second external lidocaine binding site on mammalian cardiac cells?

1989 ◽  
Vol 257 (1) ◽  
pp. H79-H84 ◽  
Author(s):  
L. A. Alpert ◽  
H. A. Fozzard ◽  
D. A. Hanck ◽  
J. C. Makielski
Keyword(s):  
Binding Site ◽  
Cardiac Arrhythmias ◽  
Local Anesthetics ◽  
Sodium Current ◽  
Cardiac Cells ◽  
Na Channel ◽  
Functional Difference ◽  
Na Channels ◽  
Internal Perfusion ◽  
Cardiac Purkinje Cells

Lidocaine and its permanently charged analogue QX-314 block sodium current (INa) in nerve, and by this mechanism, lidocaine produces local anesthesia. When administered clinically, lidocaine prevents cardiac arrhythmias. Nerve and skeletal muscle are much more sensitive to local anesthetics when the drugs are applied inside the cell, indicating that the binding site for local anesthetics is located on the inside of those Na channels. Using a large suction pipette for voltage clamp and internal perfusion of single cardiac Purkinje cells, we demonstrate that a charged lidocaine analogue blocks INa not only when applied from the inside but also from the outside, unlike noncardiac tissue. This functional difference in heart predicts that a second local anesthetic binding site exists outside or near the outside of cardiac Na channels and emphasizes that the cardiac Na channel is different from that in nerve.

The TTX metabolite 4,9-anhydro-TTX is a highly specific blocker of the Nav1.6 voltage-dependent sodium channel

2007 ◽  
Vol 293 (2) ◽  
pp. C783-C789 ◽  
Author(s):  
Christian Rosker ◽  
Birgit Lohberger ◽  
Doris Hofer ◽  
Bibiane Steinecker ◽  
Stefan Quasthoff ◽  
...  
Keyword(s):  
Steady State ◽  
Sodium Channels ◽  
Therapeutic Intervention ◽  
Time Course ◽  
Specific Interaction ◽  
Xenopus Laevis Oocytes ◽  
Recovery From Inactivation ◽  
Voltage Dependent ◽  
Steady State Inactivation ◽  
Invaluable Tool

The blocking efficacy of 4,9-anhydro-TTX (4,9-ah-TTX) and TTX on several isoforms of voltage-dependent sodium channels, expressed in Xenopus laevis oocytes, was tested (Nav1.2, Nav1.3, Nav1.4, Nav1.5, Nav1.6, Nav1.7, and Nav1.8). Generally, TTX was 40–231 times more effective, when compared with 4,9-ah-TTX, on a given isoform. An exception was Nav1.6, where 4,9-ah-TTX in nanomole per liter concentrations sufficed to result in substantial block, indicating that 4,9-ah-TTX acts specifically at this peculiar isoform. The IC50 values for TTX/4,9-ah-TTX were as follows (in nmol/l): 7.8 ± 1.3/1,260 ± 121 (Nav1.2), 2.8 ± 2.3/341 ± 36 (Nav1.3), 4.5 ± 1.0/988 ± 62 (Nav1.4), 1,970 ± 565/78,500 ± 11,600 (Nav1.5), 3.8 ± 1.5/7.8 ± 2.3 (Nav1.6), 5.5 ± 1.4/1,270 ± 251 (Nav1.7), and 1,330 ± 459/>30,000 (Nav1.8). Analysis of approximal half-maximal doses of both compounds revealed minor effects on voltage-dependent activation only, whereas steady-state inactivation was shifted to more negative potentials by both TTX and 4,9-ah-TTX in the case of the Nav1.6 subunit, but not in the case of other TTX-sensitive ones. TTX shifted steady-state inactivation also to more negative potentials in case of the TTX-insensitive Nav1.5 subunit, where it also exerted profound effects on the time course of recovery from inactivation. Isoform-specific interaction of toxins with ion channels is frequently observed in the case of proteinaceous toxins. Although the sensitivity of Nav1.1 to 4,9-ah-TTX is not known, here we report evidence on a highly isoform-specific TTX analog that may well turn out to be an invaluable tool in research for the identification of Nav1.6-mediated function, but also for therapeutic intervention.

scholarly journals Comparison of Tetrodotoxin and Procaine in Internally Perfused Squid Giant Axons

1967 ◽  
Vol 50 (5) ◽  
pp. 1413-1428 ◽  
Author(s):  
Toshio Narahashi ◽  
Nels C. Anderson ◽  
John W. Moore
Keyword(s):  
Steady State ◽  
Action Potential ◽  
Ionic Current ◽  
Transient Current ◽  
Resting Potential ◽  
Giant Axons ◽  
Time To Peak ◽  
Sucrose Gap ◽  
High Concentrations ◽  
Very High

Squid giant axons were internally perfused with tetrodotoxin and procaine, and excitability and electrical properties were studied by means of current-clamp and sucrose-gap voltage-clamp methods. Internally perfused tetrodotoxin was virtually without effect on the resting potential, the action potential, the early transient membrane ionic current, and the late steady-state membrane ionic current even at very high concentrations (1,000–10,000 nM) for a long period of time (up to 36 min). Externally applied tetrodotoxin at a concentration of 100 nM blocked the action potential and the early transient current in 2–3 min. Internally perfused procaine at concentrations of 1–10 mM reversibly depressed or blocked the action potential with an accompanying hyperpolarization of 2–4 mv, and inhibited both the early transient and late steady-state currents to the same extent. The time to peak early transient current was increased. The present results and the insolubility of tetrodotoxin in lipids have led to the conclusion that the gate controlling the flow of sodium ions through channels is located on the outer surface of the nerve membrane.

scholarly journals Activation of squid axon K+ channels. Ionic and gating current studies.

1985 ◽  
Vol 85 (4) ◽  
pp. 539-554 ◽  
Author(s):  
M M White ◽  
F Bezanilla
Keyword(s):  
Steady State ◽  
General Scheme ◽  
Channel Gating ◽  
K Channel ◽  
Na Channel ◽  
Activation Process ◽  
Gating Current ◽  
Gating Currents ◽  
Similar Time ◽  
Channel Activation

We have used data obtained from measurements of ionic and gating currents to study the process of K+ channel activation in squid giant axons. A marked improvement in the recording of K+ channel gating currents (IKg) was obtained by total replacement of Cl- in the external solution by NO-3, which eliminates approximately 50% of the Na+ channel gating current with no effect on IKg. The midpoint of the steady state charge-voltage (Qrel - V) relationship is approximately 40 mV hyperpolarized to that of the steady state activation (fo - V) curve, which is an indication that the channel has many nonconducting states. Ionic and gating currents have similar time constants for both ON and OFF pulses. This eliminates any Hodgkin-Huxley nx scheme for K+ channel activation. An interrupted pulse paradigm shows that the last step in the activation process is not rate limiting. IKg shows a nonartifactual rising phase, which indicates that the first step is either the slowest step in the activation sequence or is voltage independent. These data are consistent with the following general scheme for K+ channel activation: (formula; see text)

Effects of Halothane and Isoflurane on Fast and Slow Inactivation of Human Heart hH1a Sodium Channels

1999 ◽  
Vol 90 (6) ◽  
pp. 1671-1683. ◽  
Author(s):  
Anna Stadnicka ◽  
Wai-Meng Kwok ◽  
Hali A. Hartmann ◽  
Zeljko J. Bosnjak
Keyword(s):  
Steady State ◽  
Heterologous Expression ◽  
Sodium Channel ◽  
Sodium Channels ◽  
Human Heart ◽  
Sodium Current ◽  
Volatile Anesthetic ◽  
Slow Inactivation ◽  
Fast Inactivation ◽  
Cardiac Sodium Channel

Background Cloning and heterologous expression of ion channels allow biophysical and molecular studies of the mechanisms of volatile anesthetic interactions with human heart sodium channels. Volatile anesthetics may influence the development of arrhythmias arising from cardiac sodium channel dysfunction. For that reason, understanding the mechanisms of interactions between these anesthetics and cardiac sodium channels is important. This study evaluated the mechanisms of volatile anesthetic actions on the cloned human cardiac sodium channel (hH1a) alpha subunit. Methods Inward sodium currents were recorded from human embryonic kidney (HEK293) cells stably expressing hH1a channels. The effects of halothane and isoflurane on current and channel properties were evaluated using the whole cell voltage-clamp technique. Results Halothane at 0.47 and 1.1 mM and isoflurane at 0.54 and 1.13 mM suppressed the sodium current in a dose- and voltage-dependent manner. Steady state activation was not affected, but current decay was accelerated. The voltage dependence of steady state fast and slow inactivations was shifted toward more hyperpolarized potentials. The slope factor of slow but not fast inactivation curves was reduced significantly. Halothane increased the time constant of recovery from fast inactivation. The recovery from slow inactivation was not affected significantly by either anesthetic. Conclusions In a heterologous expression system, halothane and isoflurane interact with the hH1a channels and suppress the sodium current. The mechanisms involve acceleration of the transition from the open to the inactivated state, stabilization of the fast and slow inactivated states, and prolongation of the inactivated state by delayed recovery from the fast inactivated to the resting state.

scholarly journals The sodium current underlying action potentials in guinea pig hippocampal CA1 neurons.

1988 ◽  
Vol 91 (3) ◽  
pp. 373-398 ◽  
Author(s):  
P Sah ◽  
A J Gibb ◽  
P W Gage
Keyword(s):  
Action Potentials ◽  
Time Course ◽  
Sodium Current ◽  
Hippocampal Slices ◽  
Resting Potential ◽  
Equilibrium Potential ◽  
Sodium Currents ◽  
Time To Peak ◽  
Ca1 Region ◽  
Inward Currents

Neurons were acutely dissociated from the CA1 region of hippocampal slices from guinea pigs. Whole-cell recording techniques were used to record and control membrane potential. When the electrode contained KF, the average resting potential was about -40 mV and action potentials in cells at -80 mV (current-clamped) had an amplitude greater than 100 mV. Cells were voltage-clamped at 22-24 degrees C with electrodes containing CsF. Inward currents generated with depolarizing voltage pulses reversed close to the sodium equilibrium potential and could be completely blocked with tetrodotoxin (1 microM). The amplitude of these sodium currents was maximal at about -20 mV and the amplitude of the tail currents was linear with potential, which indicates that the channels were ohmic. The sodium conductance increased with depolarization in a range from -60 to 0 mV with an average half-maximum at about -40 mV. The decay of the currents was not exponential at potentials more positive than -20 mV. The time to peak and half-decay time of the currents varied with potential and temperature. Half of the channels were inactivated at a potential of -75 mV and inactivation was essentially complete at -40 to -30 mV. Recovery from inactivation was not exponential and the rate varied with potential. At lower temperatures, the amplitude of sodium currents decreased, their time course became longer, and half-maximal inactivation shifted to more negative potentials. In a small fraction of cells studied, sodium currents were much more rapid but the voltage dependence of activation and inactivation was very similar.

scholarly journals Simulation of Na channel inactivation by thiazine dyes.

1982 ◽  
Vol 80 (5) ◽  
pp. 641-662 ◽  
Author(s):  
C M Armstrong ◽  
R S Croop
Keyword(s):  
Time Course ◽  
Sodium Current ◽  
Na Channel ◽  
Equilibration Time ◽  
Na Channels ◽  
Dye Molecules ◽  
Gating Current ◽  
Thiazine Dyes ◽  
Opening And Closing ◽  
Dye Molecule

Some dyes of the methylene blue family serve as artificial inactivators of the sodium channels when present inside squid axons at a concentration of approximately 0.1 mM. The dyes restore a semblance of inactivation after normal inactivation has been destroyed by pronase. In fibers that inactivate normally, the dyes hasten the decay of sodium current. Many dye-blocked channels conduct transiently on exit of the dye molecule after repolarization to the holding potential. In contrast, normally inactivated channels do not conduct during recovery from inactivation. Kinetic evidence shows that inactivation of a dye-blocked channel is unlikely or impossible, which suggests that dye molecules compete with inactivation "particles" for the same site. In the absence of tetrodotoxin, the dyes do not affect the ON gating current unless the interpulse interval is very short. If sufficient equilibration time is allowed during a pulse, the initial amplitude of the OFF gating current is reduced to near zero. This suggests that a dye molecule is a Na channel completely blocks that channel's gating current, even the fraction that is resistant to normal inactivation. Dyes block INa and Ig with the same time course. This provides the strongest evidence to date that virtually all of recorded "gating current" is associated with Na channels. Tetrodotoxin greatly slows dissociation of dye molecules from Na channels and reduced gating current during both opening and closing of the channels.

scholarly journals Cardiac sodium channels (hH1) are intrinsically more sensitive to block by lidocaine than are skeletal muscle (mu 1) channels.

1995 ◽  
Vol 106 (6) ◽  
pp. 1193-1209 ◽  
Author(s):  
H B Nuss ◽  
G F Tomaselli ◽  
E Marbán
Keyword(s):  
Skeletal Muscle ◽  
Local Anesthetics ◽  
Time Course ◽  
Large Fraction ◽  
Expression System ◽  
Na Channel ◽  
Na Channels ◽  
Na Current ◽  
Unexpected Findings ◽  
Cardiac Sodium Channels

When lidocaine is given systemically, cardiac Na channels are blocked preferentially over those in skeletal muscle and nerve. This apparent increased affinity is commonly assumed to arise solely from the fact that cardiac Na channels spend a large fraction of their time in the inactivated state, which exhibits a high affinity for local anesthetics. The oocyte expression system was used to compare systematically the sensitivities of skeletal (mu 1-beta 1) and cardiac (hH1-beta 1) Na channels to block by lidocaine, under conditions in which the only difference was the choice of alpha subunit. To check for differences in tonic block, Na currents were elicited after 3 min of exposure to various lidocaine concentrations at -100 mV, a potential at which both hH1-beta 1 and mu 1-beta 1 channels were fully reprimed. Surprisingly, hH1-beta 1 Na channels were threefold more sensitive to rested-state block by lidocaine (402 +/- 36 microM, n = 4-22) than were mu 1-beta 1 Na channels (1,168 +/- 34 microM, n = 7-19). In contrast, the inactivated state binding affinities determined at partially depolarized holding potentials (h infinity approximately 0.2) were similar (Kd = 16 +/- 1 microM, n = 3-9 for hH1-beta 1 and 12 +/- 2 microM, n = 4-11 for mu 1-beta 1). Lidocaine produced more use-dependent block of peak hH1-beta 1 Na current elicited by trains of short-(10 ms) or long- (1 s) duration step depolarizations (0.5 Hz, -20 mV) than of mu 1-beta 1 Na current. During exposure to lidocaine, hH1-beta 1 channels recover from inactivation at -100 mV after a prolonged delay (20 ms), while mu 1-beta 1 channels begin repriming immediately. The overall time course of recovery from inactivation in the presence of lidocaine is much slower in hH1-beta 1 than in mu 1-beta 1 channels. These unexpected findings suggest that structural differences in the alpha subunits impart intrinsically different lidocaine sensitivities to the two isoforms. The differences in steady state affinities and in repriming kinetics are both in the correct direction to help explain the increased potency of cardiac Na channel block by local anesthetics.

Effect of intracellular and extracellular acidosis on sodium current in ventricular myocytes

1995 ◽  
Vol 268 (4) ◽  
pp. H1749-H1756 ◽  
Author(s):  
C. L. Watson ◽  
M. R. Gold
Keyword(s):  
Steady State ◽  
Time Course ◽  
Ventricular Myocytes ◽  
Sodium Current ◽  
Essential Element ◽  
Neonatal Rat ◽  
Cardiac Conduction ◽  
Inactivation Kinetics ◽  
Extracellular Acidosis ◽  
Steady State Inactivation

Conduction slowing is an essential element in the generation of ischemic ventricular arrhythmias and is determined in part by the inward Na+ current (INa). Because intracellular acidosis is an early consequence of ischemia, we hypothesized that lowering intracellular pH (pHi) would reduce or kinetically modulate INa and thus affect cardiac conduction. To test this hypothesis, the whole cell patch-clamp method was used to measure INa in neonatal rat ventricular myocytes exposed to varying extracellular pH (pHo 6.4–7.4), while perfusing the cells with acidic solutions (pHi 6.2–7.2). With simultaneous acidification of pHo and pHi there was a progressive increase in time to peak current, a 31% decrease in peak INa (298 +/- 18 to 206 +/- 16 pA/pF), and a complex slowing of inactivation kinetics. At the most extreme levels of acidification, there was a 5-mV hyperpolarizing shift in steady-state inactivation and a 6-mV depolarizing shift in activation. Independent changes of pHo and pHi indicate that the reduction of peak INa is a function of pHo. However, steady-state inactivation is modulated by pHi. The time course of activation and inactivation appears to depend on both pHo and pHi. We conclude that both intracellular and extracellular acidosis are significant but distinct modulators of INa amplitude and kinetics in cardiac myocytes.

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