Potassium Depletion and Sodium Block of Potassium Currents Under Hyperpolarization in Frog Sartorius Muscle

Overview

Journal J Physiol

Specialty Physiology

Date 1979 Sep 1

PMID 512954

Citations 65

Authors

N B Standen

P R Stanfield

Affiliations

Soon will be listed here.

Abstract

1. A three-electrode voltage clamp method was used to investigate the mechanism of the fall in resting potassium permeability which occurs under extreme hyperpolarization in frog sartorius muscle fibres. 2. Experiments were performed which show that this permeability change is due to a potential dependent block by Na+ ions present in the external solution. 3. Inward K-currents recorded on hyperpolarization turned off exponentially with time. In the presence of Na the steady-state current-voltage relation had a region of negative slope beyond -140 mV. This negative-slope region was removed when Na was replaced by TMA, Tris or Li. Increasing [Na] to 140 mM shifted the negative-slope region to less negative membrane potentials; reducing [Na] to 14 mM shifted the region to more negative potentials. 4. The time constant for the turn-off of the currents (tau) was the same in Na and TMA-containing solutions at membrane potentials positive to -140 mV. At more negative membrane potentials the tau s in Na became progressively shorter than those in TMA. Increasing [Na] to 140 mM (from 70 mM) gave smaller tau s at all potentials. 5. If fibres were hyperpolarized to -240 mV and then repolarized to -160 mV in 70 mM-Na the current recorded during the second pulse turned on with time, often reaching a value greater than that at the end of the first pulse. This behaviour was removed when Na was replaced by TMA or Tris. 6. An estimate of the steady-state relationship between the degree of block and membrane potential was obtained, and could be fitted by an expression for a potential-dependent ionic block with a very low affinity binding site for Na+ in the membrane. 7. The recovery after hyperpolarization of K-currents at the holding potential was examined in two-pulse experiments. In 70 mM-TMA recovery occurred at the same rate whether the initial hyperpolarization was to -120 or to -210 mV. In 70 mM-Na recovery after an initial pulse to -120 mV occurred at the same rate as in TMA, but recovery after a pulse to -210 mV occurred about 9 times faster. These results are consistent with depletion of K from the lumen of the T-system dominating the turn-off of K currents in TMA and in Na for the hyperpolarization to -120 mV, but a different mechanism being involved for the -120 mV pulse in Na. 8. A three-compartment model is presented which attempts to describe the depletion of K from the T-system. The model accurately predicts the time-course for the decline of inward K-currents, both in 10 and 80 mM-K solutions.

Citing Articles

External K dependence of strong inward rectifier K channel conductance is caused not by K but by competitive pore blockade by external Na.

Ishihara K J Gen Physiol. 2018; 150(7):977-989.

PMID: 29907600 PMC: 6028490. DOI: 10.1085/jgp.201711936.

Inward rectifier potassium currents in mammalian skeletal muscle fibres.

DiFranco M, Yu C, Quinonez M, Vergara J J Physiol. 2014; 593(5):1213-38.

PMID: 25545278 PMC: 4358681. DOI: 10.1113/jphysiol.2014.283648.

Huntington disease skeletal muscle is hyperexcitable owing to chloride and potassium channel dysfunction.

Waters C, Varuzhanyan G, Talmadge R, Voss A Proc Natl Acad Sci U S A. 2013; 110(22):9160-5.

PMID: 23671115 PMC: 3670332. DOI: 10.1073/pnas.1220068110.

Kir2.6 regulates the surface expression of Kir2.x inward rectifier potassium channels.

Dassau L, Conti L, Radeke C, Ptacek L, Vandenberg C J Biol Chem. 2011; 286(11):9526-41.

PMID: 21209095 PMC: 3059001. DOI: 10.1074/jbc.M110.170597.

The extracellular K+ concentration dependence of outward currents through Kir2.1 channels is regulated by extracellular Na+ and Ca2+.

Chang H, Lee J, Liu T, Suen C, Arreola J, Shieh R J Biol Chem. 2010; 285(30):23115-25.

PMID: 20495007 PMC: 2906305. DOI: 10.1074/jbc.M110.121186.

References

Adrian R, Freygang W . The potassium and chloride conductance of frog muscle membrane. J Physiol. 1962; 163(1):61-103. PMC: 1359689. DOI: 10.1113/jphysiol.1962.sp006959. View

GAY L, Stanfield P . Cs(+) causes a voltage-dependent block of inward K currents in resting skeletal muscle fibres. Nature. 1977; 267(5607):169-70. DOI: 10.1038/267169a0. View

HODGKIN A, Horowicz P . The influence of potassium and chloride ions on the membrane potential of single muscle fibres. J Physiol. 1959; 148:127-60. PMC: 1363113. DOI: 10.1113/jphysiol.1959.sp006278. View

Adrian R, Freygang W . Potassium conductance of frog muscle membrane under controlled voltage. J Physiol. 1962; 163:104-14. PMC: 1359690. DOI: 10.1113/jphysiol.1962.sp006960. View

FRANKENHAEUSER B, Moore L . THE EFFECT OF TEMPERATURE ON THE SODIUM AND POTASSIUM PERMEABILITY CHANGES IN MYELINATED NERVE FIBRES OF XENOPUS LAEVIS. J Physiol. 1963; 169:431-7. PMC: 1368766. DOI: 10.1113/jphysiol.1963.sp007269. View

HODGKIN A, Horowicz P . The effect of sudden changes in ionic concentrations on the membrane potential of single muscle fibres. J Physiol. 1960; 153:370-85. PMC: 1359754. DOI: 10.1113/jphysiol.1960.sp006540. View

Standen N, Stanfield P . A mechanism for the fall in resting potassium conductance of frog skeletal muscle fibres occurring under extreme hyperpolarization [proceedings]. J Physiol. 1978; 282:18P-19P. View

Ohmori H . Inactivation kinetics and steady-state current noise in the anomalous rectifier of tunicate egg cell membranes. J Physiol. 1978; 281:77-99. PMC: 1282685. DOI: 10.1113/jphysiol.1978.sp012410. View

Standen N, Stanfield P . A potential- and time-dependent blockade of inward rectification in frog skeletal muscle fibres by barium and strontium ions. J Physiol. 1978; 280:169-91. PMC: 1282654. DOI: 10.1113/jphysiol.1978.sp012379. View

10.

Hagiwara S, Miyazaki S, Moody W, Patlak J . Blocking effects of barium and hydrogen ions on the potassium current during anomalous rectification in the starfish egg. J Physiol. 1978; 279:167-85. PMC: 1282609. DOI: 10.1113/jphysiol.1978.sp012338. View

11.

Duval A, Leoty C . Ionic currents in mammalian fast skeletal muscle. J Physiol. 1978; 278:403-23. PMC: 1282357. DOI: 10.1113/jphysiol.1978.sp012312. View

12.

Standen N, Stanfield P . Potential-dependent blockade by Ba2+ of resting potassium permeability of frog sartorius [proceedings]. J Physiol. 1978; 277:70P-71P. View

13.

Hille B, Schwarz W . Potassium channels as multi-ion single-file pores. J Gen Physiol. 1978; 72(4):409-42. PMC: 2228548. DOI: 10.1085/jgp.72.4.409. View

14.

HODGKIN A, Nakajima S . The effect of diameter on the electrical constants of frog skeletal muscle fibres. J Physiol. 1972; 221(1):105-20. PMC: 1331323. DOI: 10.1113/jphysiol.1972.sp009742. View

15.

Adrian R, Peachey L . Reconstruction of the action potential of frog sartorius muscle. J Physiol. 1973; 235(1):103-31. PMC: 1350735. DOI: 10.1113/jphysiol.1973.sp010380. View

16.

Adrian R, Chandler W, HODGKIN A . Slow changes in potassium permeability in skeletal muscle. J Physiol. 1970; 208(3):645-68. PMC: 1348790. DOI: 10.1113/jphysiol.1970.sp009140. View

17.

Adrian R, Chandler W, HODGKIN A . Voltage clamp experiments in striated muscle fibres. J Physiol. 1970; 208(3):607-44. PMC: 1348789. DOI: 10.1113/jphysiol.1970.sp009139. View

18.

Stanfield P . The differential effects of tetraethylammonium and zinc ions on the resting conductance of frog skeletal muscle. J Physiol. 1970; 209(1):231-56. PMC: 1396031. DOI: 10.1113/jphysiol.1970.sp009164. View

19.

Stanfield P . The effect of the tetraethylammonium ion on the delayed currents of frog skeletal muscle. J Physiol. 1970; 209(1):209-29. PMC: 1396030. DOI: 10.1113/jphysiol.1970.sp009163. View

20.

Almers W . Potassium conductance changes in skeletal muscle and the potassium concentration in the transverse tubules. J Physiol. 1972; 225(1):33-56. PMC: 1331093. DOI: 10.1113/jphysiol.1972.sp009928. View