Intracellular Recording from Vertebrate Myelinated Axons: Mechanism of the Depolarizing Afterpotential

Overview

Journal J Physiol

Specialty Physiology

Date 1982 Feb 1

PMID 6980272

Citations 119

Authors

E F Barrett

J N Barrett

Affiliations

Soon will be listed here.

Abstract

1. Electrophysiological techniques are described which allow intracellular recording from peripheral myelinated axons of lizards and frogs for up to several hours. The sciatic and intramuscular axons studied here have resting potentials of -60 to -80 mV and action potentials (evoked by stimulation of the proximal nerve trunk) of 50-90 mV. They show a prominent depolarizing afterpotential (d.a.p.), which is present both in isolated axons and in axons still attached to their peripheral terminals. This d.a.p. has a peak amplitude of 5-20 mV at the resting potential, and decays with a half-time of 20-100 msec.2. The peak amplitude of the d.a.p. is voltage-sensitive, increasing to up to 26 mV with membrane hyperpolarization. The d.a.p. disappears as the axon is depolarized to -60 to -45 mV, and does not appear to reverse with further depolarization.3. The d.a.p. is not reduced when bath Ca is replaced by 2-10 mm divalent Mn or Ni. The d.a.p. is not reversed when axons depleted of Cl (by prolonged exposure to Cl-deficient, SO(4)-enriched solutions) are bathed in Cl-rich solutions. These results suggest that the d.a.p. is not mediated by a conductance change specific for Ca or Cl ions. Partial substitution of tetramethylammonium for bath Na, or addition of 10(-5)m-tetrodotoxin to the normal bathing solution, reduces the amplitude of both the action potential and the d.a.p.4. The amplitude of the d.a.p. is not sensitive to bath [K] over the range 1-7.5 mm, provided that all measurements are made at the same holding potential. This result argues that the d.a.p. is not mediated by accumulation of K outside the active axon.5. Treatments expected to inhibit the Na-K exchange pump (cooling from 25 to 10 degrees C, or 0.15 mm-ouabain) do not enlarge or prolong the d.a.p., although they do abolish a slower hyperpolarizing afterpotential seen following repetitive stimulation.6. The passive voltage response of the axon to small injected pulses of depolarizing or hyperpolarizing current shows a prominent, slowly decaying component with a time course similar to that of the d.a.p. Depolarizing current reduces the input resistance of the axon, and increases the rate of decay of both the passive voltage response and the d.a.p. There is a slight conductance increase during the peak of the d.a.p., but the same conductance increase can be produced by a comparable passive depolarization.7. We conclude that the d.a.p. is due mainly to a passive capacitative current, probably resulting from discharge of the internodal axonal membrane capacitance through a resistive current pathway beneath or through the myelin sheath. We suggest that this slow capacitative discharge becomes evident as soon as most of the nodal ionic channels activated during the action potential have closed. An electrical model of the myelinated axon that incorporates the postulated internodal leakage pathway can account both for the prolonged d.a.p. recorded inside the axon, and for the potential profile recorded extra-axonally in or near the internodal periaxonal space.

Citing Articles

CD36 deletion prevents white matter injury by modulating microglia polarization through the Traf5-MAPK signal pathway.

Hou X, Qu X, Chen W, Sang X, Ye Y, Wang C J Neuroinflammation. 2024; 21(1):148.

PMID: 38840180 PMC: 11155181. DOI: 10.1186/s12974-024-03143-2.

Impact of Extracellular Current Flow on Action Potential Propagation in Myelinated Axons.

Abdollahi N, Prescott S J Neurosci. 2024; 44(26).

PMID: 38688722 PMC: 11211723. DOI: 10.1523/JNEUROSCI.0569-24.2024.

Application of near infra-red laser light increases current threshold in optic nerve consistent with increased Na-dependent transport.

Lo H, Munkongcharoen T, Muijen R, Gurung R, Umredkar A, Baker M Pflugers Arch. 2024; 476(5):847-859.

PMID: 38421407 PMC: 11033230. DOI: 10.1007/s00424-024-02932-1.

The effect of the subthreshold oscillation induced by the neurons' resonance upon the electrical stimulation-dependent instability.

Yu S, Yue W, Guo T, Liu Y, Zhang Y, Khademi S Front Neurosci. 2023; 17:1178606.

PMID: 37229430 PMC: 10203711. DOI: 10.3389/fnins.2023.1178606.

LGI3/2-ADAM23 interactions cluster Kv1 channels in myelinated axons to regulate refractory period.

Kozar-Gillan N, Velichkova A, Kanatouris G, Eshed-Eisenbach Y, Steel G, Jaegle M J Cell Biol. 2023; 222(4).

PMID: 36828548 PMC: 9997507. DOI: 10.1083/jcb.202211031.

References

Tasaki I . Properties of myelinated fibers in frog sciatic nerve and in spinal cord as examined with micro-electrodes. Jpn J Physiol. 1952; 3(1):73-94. DOI: 10.2170/jjphysiol.3.73. View

Chiu S, Ritchie J, Rogart R, Stagg D . A quantitative description of membrane currents in rabbit myelinated nerve. J Physiol. 1979; 292:149-66. PMC: 1280850. DOI: 10.1113/jphysiol.1979.sp012843. View

Raymond S . Effects of nerve impulses on threshold of frog sciatic nerve fibres. J Physiol. 1979; 290(2):273-303. PMC: 1278835. DOI: 10.1113/jphysiol.1979.sp012771. View

WOODBURY J . Direct membrane resting and action potentials from single myelinated nerve fibers. J Cell Comp Physiol. 1952; 39(2):323-39. DOI: 10.1002/jcp.1030390210. View

Fuchs P, Getting P . Ionic basis of presynaptic inhibitory potentials at crayfish claw opener. J Neurophysiol. 1980; 43(6):1547-57. DOI: 10.1152/jn.1980.43.6.1547. View

Conti F, Hille B, Neumcke B, Nonner W, Stampfli R . Measurement of the conductance of the sodium channel from current fluctuations at the node of Ranvier. J Physiol. 1976; 262(3):699-727. PMC: 1307668. DOI: 10.1113/jphysiol.1976.sp011616. View

Rahamimoff R, Yaari Y . Delayed release of transmitter at the frog neuromuscular junction. J Physiol. 1973; 228(1):241-57. PMC: 1331238. DOI: 10.1113/jphysiol.1973.sp010084. View

Swadlow H, Waxman S . Variations in conduction velocity and excitability following single and multiple impulses of visual callosal axons in the rabbit. Exp Neurol. 1976; 53(1):128-50. DOI: 10.1016/0014-4886(76)90288-0. View

Barrett E, Barret J . Separation of two voltage-sensitive potassium currents, and demonstration of a tetrodotoxin-resistant calcium current in frog motoneurones. J Physiol. 1976; 255(3):737-74. PMC: 1309277. DOI: 10.1113/jphysiol.1976.sp011306. View

10.

HUXLEY A, Stampfli R . Direct determination of membrane resting potential and action potential in single myelinated nerve fibers. J Physiol. 1951; 112(3-4):476-95. PMC: 1393015. DOI: 10.1113/jphysiol.1951.sp004545. View

11.

Dudel J . Recording of action potentials and polarization of a single crayfish motor axon through a sucrose-gap capillary suction electrode. Pflugers Arch. 1973; 338(3):187-99. DOI: 10.1007/BF00587386. View

12.

Arhem P . Effects of some heavy metal ions on the ionic currents of myelinated fibres from Xenopus laevis. J Physiol. 1980; 306:219-31. PMC: 1283002. DOI: 10.1113/jphysiol.1980.sp013393. View

13.

Stampfli R . [The structure and function of isolated myelinated nerve fibers]. Ergeb Physiol. 1952; 47:70-165. View

14.

Miyamoto M . The actions of cholinergic drugs on motor nerve terminals. Pharmacol Rev. 1977; 29(3):221-47. View

15.

Hardy W . Propagation speed in myelinated nerve. I. Experimental dependence on external Na and on temperature. Biophys J. 1973; 13(10):1054-70. PMC: 1484345. DOI: 10.1016/S0006-3495(73)86045-X. View

16.

Tasaki I . New measurements of the capacity and the resistance of the myelin sheath and the nodal membrane of the isolated frog nerve fiber. Am J Physiol. 1955; 181(3):639-50. DOI: 10.1152/ajplegacy.1955.181.3.639. View

17.

Hudspeth A, Poo M, Stuart A . Passive signal propagation and membrane properties in median photoreceptors of the giant barnacle. J Physiol. 1977; 272(1):25-43. PMC: 1353591. DOI: 10.1113/jphysiol.1977.sp012032. View

18.

. An extreme supernormal period in cerebellar parallel fibres. J Physiol. 1972; 222(2):357-71. PMC: 1331386. DOI: 10.1113/jphysiol.1972.sp009802. View

19.

Magleby K . The effect of repetitive stimulation on facilitation of transmitter release at the frog neuromuscular junction. J Physiol. 1973; 234(2):327-52. PMC: 1350631. DOI: 10.1113/jphysiol.1973.sp010348. View

20.

Krishnan N, Singer M . Penetration of peroxidase into peripheral nerve fibers. Am J Anat. 1973; 136(1):1-14. DOI: 10.1002/aja.1001360102. View