Summary
Impulse conduction at the branch point of afferent axons in dorsal root ganglion (DRG) has been studied using intracellular recording from frog DRG neurons in vitro. The least conduction interval (LCI, the minimum inter-response interval) was determined for pairs of impulses to successfully propagate through the branch point into the dorsal root. At 21°–23°C, average branch point LCI was significantly longer than for afferent fibers in the peripheral nerve. This result suggested that the branch point would limit the maximum frequency of action potentials that could conduct into the dorsal root. This was found to be the case. The maximum frequency of impulses in short trains (≤ 40 ms) which could conduct into the dorsal root without failure (363 Hz) was accurately predicted by branch point LCI and was far less than the maximum frequency predicted from the LCI of axons in the peripheral nerve (610 Hz). Branch point LCI was correlated (r = -0.78) with the natural log of peripheral axon conduction velocity (CV). However, the relationship of LCI and CV was different for different types of neurons and the shape of the somatic action potential was found to be a reliable predictor of branch point LCI. Neurons with long-duration somatic action potentials with a shoulder on the falling phase tended to have low CV and invariably had long LCI's. Neurons with brief, smooth action potentials had short LCI's regardless of CV. These cells, which appear to be the most differentiated type, have found a way to minimize branch point LCI which is virtually independent of their axonal CV. For the latter neurons, branch point LCI was correlated (r = 0.42) with the reciprocal of the hyperpolarization level, at the cell body, required to block conduction through the branch point, suggesting that the proximity of the cell body to the branch point might play a role in determining the LCI of some neurons. Over a range of 12 °C to around 35°C, branch point LCI was inversely related and maximum firing frequency directly related to temperature. At high temperatures (30°–40°C) conduction failure occurred at sites having particularly long LCI's. It is concluded that a) these axon branch points act as lowpass filters and set the maximum frequency of conducted impulses that can access the central nervous system; b) certain varieties of DRG neurons exhibit more branch point filtering action than others; and c) warming, within limits, reduces branch point filtering action.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Amberson WR (1930) The effect of temperature upon the absolute refractory period in nerve. J Physiol 69: 60–66
Barron DH, Matthews BHC (1935) Intermittent conduction in the spinal cord. J Physiol 85: 73–103
Burgess PR, Perl ER (1973) Cutaneous mechanoreceptors and nociceptors. In: Iggo A (ed) Handbook of sensory physiology, Vol II. The somatosensory system. Springer, New York
Cameron AA, Attwell D, Snow PJ (1986) The electrophysiological and morphological characteristics of feline dorsal root ganglion cells. Brain Res 362: 1–6
Chung SH, Raymond SA, Lettvin JY (1970) Multiple meaning in single visual units. Brain Behav Evol 3: 72–101
Deschenes M, Landry P (1980) Axonal branch diameter and spacing of nodes in the terminal arborization of identified thalamic and cortical neurons. Brain Res 191: 538–544
Dun FT (1955) The delay and blockage of sensory impulses in the dorsal root ganglion. J Physiol 127: 252–264
Fuortes MGF (1951) Action of strychnine on the ‘intermittent conduction’ of impulses along the dorsal columns of the spinal cord of frogs. J Physiol 112: 42P
Gabor D (1946) Theory of communication. J Inst Elect Eng 93: 429–457
Gallagher JP, Nakamura J, Shinnick-Gallagher P (1983) The effects of temperature, pH and CL-pump inhibitors on GABA responses recorded from cat dorsal root ganglia. Brain Res 267: 249–259
Grossman Y, Parnas I, Spira ME (1979) Differential conduction of action potentials at high frequency in a branching axon. J Physiol 295: 283–305
Harper AA, Lawson SN (1985) Electrical properties of rat dorsal root ganglion neurones with different peripheral nerve conduction velocities. J Physiol 359: 47–63
Ito M (1957) An analysis of potentials recorded intracellularly from the spinal ganglion cell. Jpn J Physiol 9: 20–32
Ito M, Saiga M (1959) The mode of impulse conduction through the spinal ganglion. Jpn J Physiol 9: 33–42
Ito M, Takahashi I (1960) Impulse conduction through spinal ganglion. In: Katsuki Y (ed) Electrical activity of single cells. Ikagu Shoin, Tokyo
Koerber HR, Druzinsky RE, Mendell LM (1988) Properties of somata of spinal dorsal root ganglion cells differ according to peripheral receptor innervated. J Neurophysiol 60: 1584–1596
Krnjevic K, Miledi R (1958a) Motor units in the rat diaphragm. J Physiol 140: 427–439
Krnjevic K, Miledi R (1958b) Failure of neuromuscular propagation in rats. J Physiol 140: 440–461
Krnjevic K, Miledi R (1959) Presynaptic failure of neuromuscular propagation in rats. J Physiol 149: 1–22
Lee KH, Chung K, Chung JM, Coggeshall RE (1986) Correlation of cell body size, axon size and signal conduction velocity for individually labelled dorsal root ganglion cells in the cat. J Comp Neurol 243: 335–346
Levy RA (1980) Presynaptic control of input to the central nervous system. Can J Physiol Pharmacol 58: 751–766
Lieberman AR (1976) Sensory ganglia. In: Landon DN (ed) The peripheral nerve. Halsted, New York
Luscher HR, Ruenzel PW, Henneman E (1983) Effects of impulse frequency, PTP, and temperature on responses elicited in large populations of motoneurons by impulses in single Ia fibers. J Neurophysiol 50: 1045–1058
Malan A, Wilson TL, Reeves RB (1976) Intracellular pH in cold blooded vertebrates as a function of body temperature. Resp Physiol 28: 29–47
Mellon D Jr, Kennedy D (1964) Impulse origin and propagation in a bipolar sensory neuron. J Gen Physiol 47: 487–499
Moore JW, Joyner RW, Brill MH, Waxman SD, Najar-Joa M (1978) Simulations of conduction in uniform myelinated fibres: relative sensitivity to changes in nodal and internodal parameters. Biophys J 21: 147–160
Moore JW, Westerfield M (1983) Action potential propagation and threshold parameters in inhomogeneous regions of squid axons. J Physiol 336: 285–300
Paintal AS (1965) Effects of temperature on conduction in single vagal and saphenous myelinated nerve fibres of the cat. J Physiol 180: 20–49
Paintal AS (1966) The influence of diameter of medullated nerve fibers of cats on the rising and falling phases of the spike and its recovery. J Physiol 184: 791–811
Parnas I, Segev I (1979) A mathematical model for conduction of action potentials along bifurcating axons. J Physiol 295: 323–343
Proske U, Stuart GJ (1985) The initial burst of impulses in responses of toad muscle spindles during stretch. J Physiol 368: 1–18
Rall W (1959) Branching dendritic trees and motoneuron membrane resistivity. Exp Neurol 1: 491–527
Rasminsky M (1973) The effects of temperature on conduction in demyelinated single nerve fibers. Arch Neurol 28: 29–47
Revenko SV, Timin YN, Khodorov BI (1973) Special features of the conduction of nerve impulses from the myelinized part of the axon into the nonmyelinated terminal. Biophysics 18: 1140–1145
Rose RD, Koerber HR, Sedivec MJ, Mendell LM (1986) Somal action potential duration differs in identified primary afferents. Neurosci Lett 63: 259–264
Shimada K, Yai H (1960) Some properties of cutaneous mechanosensory units in toads. Jpn J Physiol 10: 555–570
Spencer PS, Raine CS, Wisniewski H (1973) Axon diameter and myelin thickness — unusual relationships in dorsal root ganglia. Anat Rec 176: 225–244
Stoney SD Jr (1985) Unequal branch point filtering action in different types of dorsal root ganglion neurons of frogs. Neurosci Lett 59: 15–20
Stoney SD Jr (1987) Differential effects of potassium and calcium channel blockers on action potentials of frog dorsal root ganglion neurons. Soc Neurosci Abstr 13: 780
Stoney SD Jr, Hershberger E (1984) Cooling and antiepileptic drugs depress impulse conduction at branch points of single myelinated afferent fibers. Soc Neurosci Abstr 10: 109
Svaetichin G (1951) Analysis of action potentials recorded from single spinal ganglion cells. Acta Physiol Scand 24: 23–57
Swadlow HA, Kocsis JD, Waxman SG (1980) Modulation of impulse conduction along the axonal tree. Ann Rev Biophys Bioeng 9: 143–179
Tasaki I (1953) Nervous transmission. Thomas, Springfield IL
Wall PD, Lettvin JY, McCulloch WS, Pitts WH (1956) Factors limiting the maximum impulse transmitting ability of an afferent system of nerve fibers. In: Cherry C (ed) Information theory. Third London symposium. Butterworths, London
Waxman SG (1975) Integrative properties and design principles of axons. Int Rev Neurobiol 18: 1–40
Waxman SG, Brill MH (1978) Conduction through demyelinated plaques in multiple sclerosis: computer simulations of facilitation by short internodes. J Neurol Neurosurg Psychiat 41: 408–416
Westerfield M, Joyner RW, Moore JW (1977) Temperature-sensitive conduction failure at axon branch points. J Neurophysiol 41: 1–8
Wilhelm GB, Coggeshall RE (1981) An electron microscopic analysis of dorsal root in the frog. J Comp Neurol 196: 421–429
Yoshida S, Matsuda Y, Samejima A (1978) Tetrodotoxin-resistant sodium and calcium components of action potentials in dorsal root ganglion cells of the adult mouse. J Neurophysiol 41: 1096–1106
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Stoney, S.D. Limitations on impulse conduction at the branch point of afferent axons in frog dorsal root ganglion. Exp Brain Res 80, 512–524 (1990). https://doi.org/10.1007/BF00227992
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00227992