Epinephrine- and norepinephrine-evoked potential changes of frog primary afferent terminals: Pharmacological characterization of α and β components

The effects of superfused epinephrine (E) and norepinephrine (NE) on the membrane potential of primary afferent fibers of the isolated frog spinal cord were studied by sucrose gap recordings from the dorsal root. In all preparations both E and NE, applied in concentrations ranging from 0.1 microM to 1.0 mM, produced a hyperpolarization of afferent terminals. In many instances this was followed by a slow depolarization and, in a small number of cords, a small depolarization preceded the increase in membrane potential. E- and NE-induced hyperpolarizations were blocked by the selective alpha 2-antagonists yohimbine and piperoxan, but not by the selective alpha 1-antagonists prazosin and corynanthine or by the beta-blockers propranolol and sotalol. The alpha 2-agonists clonidine, alpha-methylnorepinephrine and guanabenz also hyperpolarized terminals, causing a change in potential that was reduced by yohimbine and piperoxan. Taken together, these results suggest that alpha 2-receptors mediate the hyperpolarizing effects of E and NE. The beta-agonist isoproterenol evoked a slow depolarization similar to that produced by E and NE. The isoproterenol-depolarization was antagonized by propranolol. Sometimes, application of E and NE after superfusion with yohimbine produced only a depolarization of the dorsal root and this depolarization was sensitive to propranolol. It would appear therefore that the late depolarization seen after the application of E and NE is produced by activation of beta-receptors. In contrast, the alpha 1-agonist phenylephrine elicited a short latency, short duration depolarization similar to those seen preceding approximately 10% of the E- and NE-hyperpolarizations. Such short-latency depolarizations were blocked by prazosin and corynanthine. The major component of the response to both E and NE is indirectly mediated through a synaptic process: application of Mn2+, Mg2+, procaine or tetrodotoxin in concentrations sufficient to block synaptic transmission substantially reduced, but never eliminated, the actions of the catecholamines. Interneurons are probably involved because mephenesin, which reduces interneuronal transmission, significantly decreased the E and NE effects. Furthermore, interneurons which secrete excitatory amino acids and/or GABA may mediate the indirect effects of the catecholamines on afferent terminals because (-)baclofen and D.L-alpha-aminoadipate decrease, and picrotoxin and bicuculline increase, the dorsal root (DR) effects of E and NE.(ABSTRACT TRUNCATED AT 400 WORDS)     

Excitability changes of dorsal root axons following nerve injury: implications for injury-induced changes in axonal Na(+) channels

Electrophysiological recordings were obtained from rat dorsal roots in a sucrose gap chamber to study changes in Na(+) currents following nerve injury. Application of 4-aminopyridine unmasks a prominent and well-characterized depolarization (delayed depolarization) following the action potential. In our previous studies, this potential, which is only present in cutaneous afferent axons, has been shown to correlate with activation of a slow Na(+) current. The delayed depolarization in the dorsal root was reduced 1 week after sciatic nerve ligation, suggesting a reduction in the kinetically slow Na(+) currents on dorsal root axons [control: 44. 2+/-7.3% (n=5); injury: 7.3+/-4.7% (n=5), P<0.001]. The refractory period of the action potential was reduced following nerve injury, in agreement with biophysical studies indicating faster "repriming" of fast Na(+) currents on cutaneous afferent cell bodies. Dorsal root ligation near the spinal cord also results in a reduction in the delayed depolarization. These results indicate that changes in Na(+) channel organization occur on dorsal root axons following either central or peripheral target disconnection, suggesting trophic support can be derived from either the CNS or the PNS.     

Potential changes of frog afferent terminals in response to dopamine

The actions of dopamine on the membrane potential of afferent fibers of the isolated hemisected frog spinal cord were studied by sucrose gap techniques. The most prominent effect seen after addition of dopamine to the superfusing Ringer's solution was a slow reversible hyperpolarization at concentrations as low as 0.01 microM; its amplitude and duration were dependent upon concentration and length of application. Biphasic responses with an initial dominant hyperpolarization and a much smaller, later depolarization were also noted and were particularly prominent when dopamine was applied at higher concentrations. Exposure of the cord to apomorphine, a non-selective agonist, to SKF 38393A, a D-1 selective agonist, or to LY-14186, a D-2 selective agonist, hyperpolarized the dorsal root in a manner similar to that of dopamine, but only when the former compounds were applied at higher concentrations (100 microM or greater). Apomorphine also elicited a late depolarization. The non-selective dopamine antagonists, fluphenazine and haloperidol, reversibly reduced dopamine's actions. Similar effects were produced by the selective D-2 antagonists, sulpiride and metoclopramide, which had no effect on hyperpolarizations evoked by norepinephrine. Dopamine did not appear to activate adrenergic or serotonergic receptors, for its effects were not affected by yohimbine, corynanthine, propranolol, or methysergide. The effect of dopamine appeared to result from an action of the amine on both afferent fibers and interneurons. This inference was drawn because the potential changes produced by dopamine were substantially reduced, but never eliminated, by superfusion of the cord with solutions containing Mn2+ ions, tetrodotoxin or mephenesin.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of intravenously administered gamma-aminobutyric acid on afferent fiber polarization.

(1) The effect of intravenously administered gamma-aminobutyric acid (GABA) on afferent fiber polarization in the feline spinal cord was ascertained from fluctuations induced in the DC level of dorsal root filaments. (2) A dose-related depolarization of the filament, with a concomitant reduction in the magnitude of the dorsal root potential, was observed after 50 and 100 mg/kg GABA. (3) GABA also depolarized filaments of preparations in which interneuronal activity was suppressed by pretreatment with tetrodotoxin. Since the magnitude of the depolarization induced in these preparations was equal to that observed in nonpretreated animals, it is likely that the depolarization in the latter preparations reflects a direct effect on afferent terminals or fibers rather than an action on interneurons. (4) GABA failed to depolarize filaments in animals pretreated with bicuculline. This suggests that intravenously administered GABA interacted with receptors that are identical with or similar to those involved in neurally evoked primary afferent depolarization (PAD). (5) The direct depolarization of afferent fibers by intravenous GABA and the blockade thereof by bicuculline are characteristics compatible with those of the endogenous axo-axonic transmitter operating in pathways mediating neurally evoked PAD. These data, therefore, support the involvement of GABA at this synapse in the mammalian spinal cord.     

The possibility of different effects of primary afferent depolarization on spinal reflexes]

Intensive depolarization of central primary afferent terminals evoked by strong stimulation of afferent nerves or dorsal root produces recurrent discharges which may be recorded as antidromic dorsal root reflexes. It is shown that the discharges are simultaneously propagating in the dorso-ventral direction and thus produce facilitation of spinal reflexes. The obtained results allow suggesting the existence of two types of influences of the primary afferent depolarization on the reflex transmission to the spinal cord.     

Diminished dorsal root GABA sensitivity following chronic peripheral nerve injury

The depolarizing effect of gamma-aminobutyric acid (GABA) on rat lumbar dorsal roots was studied in a sucrose gap chamber following axotomy or crush injury of the sciatic nerve or dorsal root. The mean depolarization elicited by GABA on normal dorsal roots (3.96 +/- 0.71 mV, N = 14) was significantly reduced following chronic sciatic axotomy (2.02 +/- 0.99 mV, N = 15). Chronic sciatic crush injury had no significant effect on dorsal root GABA sensitivity. The amplitudes of the dorsal root compound action potentials were the same from rats with normal and injured sciatic nerves, indicating that axons proximal to the sciatic nerve lesion did not undergo appreciable degeneration. A marked loss of dorsal root GABA sensitivity was also seen following dorsal root axotomy or crush injury (1.02 +/- 0.98 mV (N = 10) and 0.69 +/- 0.70 mV (N = 9), respectively). These results indicate that GABA sensitivity of dorsal roots is attenuated following peripheral nerve lesions in which regeneration and functional reconnection with peripheral targets are prevented. Previous work indicates that the primary afferent depolarization is reduced under similar conditions. The reduction in GABA sensitivity of dorsal root fibers described here may have a contributory role in the reduced primary afferent depolarization that follows peripheral nerve transection, which has pathophysiologic implications in chronic pain syndromes.     

The development of the dorsal root potential and the responsiveness of primary afferent fibers to gamma-aminobutyric acid in the spinal cord of rat fetuses

The development of the dorsal root potential (DRP) and the responsiveness of primary afferent fibers to gamma-aminobutyric acid (GABA) were investigated in the isolated spinal cord of rat fetuses. At embryonic day 15.5, stimulation of the lumbar dorsal root was first effective in eliciting the DRP, which was not inhibited by bicuculline. A bicuculline-sensitive component of the DRP appeared at embryonic day 17.5. GABA (10 microM to 1 mM) caused a dose-dependent depolarization of the primary afferent fibers from embryonic day 13.5. The amplitude of the depolarization gradually increased with age until embryonic day 17.5 and was maintained thereafter. If the bicuculline-sensitive DRP solely reflects GABAergic activity, it is suggested that GABAergic activity develops at embryonic day 17.5 and the development of the responsiveness of primary afferent fibers to GABA precedes the functional onset of GABAergic neurons.     

Control of Impulse Conduction in Long Range Branches of Afferents by Increases and Decreases of Primary Afferent Depolarization in the Rat

It has been shown previously that impulses in axons of the descending branches of myelinated afferents in rat dorsal columns may suffer a blockade of transmission along their course in the dorsal columns. This paper tests the effect of the mechanism of primary afferent depolarization on the orthodromic movement of impulses in descending dorsal column primary afferent axons originating in the L1 dorsal root. Orthodromic impulses were recorded in the L5 and 6 dorsal columns after stimulation of the L1 dorsal root. Twenty-seven out of 82 axons (33%) suffered a temporary transmission block if primary afferent depolarization had been induced by L5 stimulation before the L1 stimulus. The tendency to block peaked at 10–15 ms and persisted for up to 30–40 ms. The number of single unit orthodromic impulses originating from the L1 root and recorded during a search of the dorsal columns 15 mm caudal to L1 increased by a factor of 3.1 after the systemic administration of bicuculline (1 mg/kg). The number of single unit orthodromic impulses originating from the L1 root and recorded in axons descending in the dorsal columns 20 mm caudal to the root increased by a factor of 8.7 after the systemic administration of picrotoxin (5 mg/kg). It is concluded that the transmission of impulses in the long range caudally running axons from dorsal roots to dorsal columns may be blocked during primary afferent depolarization and that conduction may be restored by the administration of GABA antagonists.     

The contribution of increases in extracellular potassium to primary afferent depolarization in the bullfrog spinal cord

To assess the extent to which depolarization by accumulated K+ contributes to the generation of primary afferent depolarization (PAD), the isolated bullfrog spinal cord was superfused with K+-rich Ringer solutions and the resultant dorsal root depolarizations were recorded extracellularly. Action potential blockade (with tetrodotoxin) did not reduce the K+-induced depolarization of primary afferents, indicating that the depolarization was generated locally in the region around the afferents. In this respect superfusion with K+-rich solutions adequately models the localized K+ accumulation which occurs physiologically during afferent activity. K+-induced depolarizations were decreased in the presence of 20 mM Mg2+; this effect was due to a direct decrease in the membrane response to K+ and not to blockade of K+-induced transmitter release onto primary afferents. The depolarization caused by a K+ concentration comparable to a maximum estimate of the K+ accumulating around afferent terminals following a single afferent volley was found to account for no more than about one-third of the DRP height. However, higher K+ levels, comparable to those resulting from high frequency afferent stimulation, caused large depolarizations of primary afferents, sometimes greater than the DRP amplitude. Therefore, K+-induced depolarization may contribute more significantly to PAD evoked by high frequency afferent activity.     

Slow excitatory transmission in rat dorsal horn: possible mediation by peptides

Repetitive stimulation of a dorsal root elicited a slow depolarization in about half of the dorsal horn neurons examined in the rat spinal cord slice preparation. The response was markedly depressed or abolished in the presence of substance P, substance P antagonists and capsaicin. In some dorsal horn neurons a slow hyperpolarization was also observed.     

The effects of bicuculline on the isolated spinal cord of the frog

An investigation has been made of the effects of topically applied bicuculline, a reported gamma-aminobutyric acid (GABA) antagonist, on the isolated, hemisected frog spinal cord by recording ventral and dorsal root potentials and reflexes evoked by volleys to various spinal cord inputs. Bicuculline had potent excitatory effects causing depolarization, spontaneous potentials in ventral and dorsal roots, and an increased polysynaptic ventral root reflex. More importantly, the alkaloid blocked presynaptic inhibition of orthodromic reflex activity produced by preceding ventral root stimulation and primary afferent depolarization. These effects were attributed to a demonstrated antagonism of the direct depolarizing effects of GABA on dorsal root terminals by the alkaloid. These actions of bicuculline suggest that GABA may be the transmitter responsible for primary afferent depolarization and presynaptic inhibition in the amphibian.     

Reversible effects of hypoxia on neurons in mouse dorsal root ganglia in vitro

Mouse dorsal root ganglia (DRG) were isolated and maintained in a tissue chamber. Membrane potential of ‘A-type’ neurons was recorded with intracellular electrodes. When the supply of oxygen was reduced, cells depolarized by a few mV and then maintained a stable membrane potential or partially repolarized. During depolarization the action potential was reduced in amplitude and the hyperpolarizing afterpotential was depressed. Reoxygenation within 15–88 min was followed by a brief period of hyperpolarization and then complete recovery. In about 60% of the cells, invasion of the cell soma by impulses triggered by dorsal root (DR) stimulation failed during hypoxia while action potentials could still be evoked by stimulation of the peripheral nerve and by direct intracellular stimuli. Conduction from DR into the peripheral nerve stump was unchanged indicating that the blockade of DR-evoked impulse conduction occurred at the bifurcation of the axon. Results with paired pulse stimulation indicated that impulses passing the axon bifurcation leave a long lasting ( 25 ms) post-spike subnormal period. In DRG cells treated with tetraethylammonium (TEA) the calcium-mediated ‘shoulder’ of the action potential was curtailed during oxygen withdrawal. In contrast to CNS neurons, DRG cells did not show early hypoxic hyperpolarization, nor the delayed hypoxic spreading depression-like depolarization. The findings support the suggestion that the reversible depression of synaptic potentials in the CNS during the early phase of hypoxia is caused by a combination of conduction failure at axon branch points and curtailment of voltage calcium currents of presynaptic terminals, both effects resulting in reduced transmitter output.     

Negative potentials evoked by nucleus reticularis gigantocellularis in the spinal trigeminal tract of the cat

In cats that were precollicularly decerebrated, bilateral elactrical stimulation of the nucleus reticularis gigantocellularis (NRGC) evoked negative potentials in the spinal trigeminal tract at the level of the subnucleus oralis of the spinal trigeminal nuclear complex. These negative potentials exhibited two types of configurations that differed in the slope of the rising and declining phase, duration, and amplitude of the negative wave. They were also found to develop as a function of the reticular stimulus parameters. Thus, they possessed electrophysiologic characteristics similar to the dorsal root potentials induced by comparable reticular activation in the spinal cord. The time course of the NRGC-evoked negative potential paralleled the inhibition of dental pulp-elicited responses in the subnucleus oralis, promoted by the same reticular stimulation. As the dorsal root potential is generally taken to be a manifestation of primary afferent depolarization, it is suggested, by extrapolation, that the NRGC may, at least in part, suppress the transmission of nociceptive signals from the dental pulp by a depolarization of the pulpal afferent fibers.     

The presynaptic effects of valproic acid in the isolated frog spinal cord

The effects of the anticonvulsant valproic acid (n-dipropylacetate, DPA) on frog primary afferent fibers was examined with sucrose gap recordings from the dorsal roots. Addition of DPA to the superfusate consistently reduced the amplitude and duration of the dorsal root potential. In contrast, DPA augmented the depolarization of dorsal roots produced by GABA, β-alanine and taurine. It also decreased afferent fiber ‘desensitization’ to GABA. DPA depressed the ability of K⁺ and the excitatory amino acids glutamate and aspartate to depolarize afferent fibers. In addition, the compounds decreased the amount of K⁺ released by tetanic stimulation of the dorsal root.

The K⁺-evoked release of tritiated GABA from cord slices was initially reduced by exposure to DPA, but was then unaffected after a longer application of the anticonvulsant. On the other hand, the high affinity uptake of tritiated GABA and glycine were almost totally blocked by the addition of DPA to the incubating medium.

In sum, DPA has complex effects on neuronal membranes. Some of these effects may serve to explain the anticonvulsant actions of this drug.     

Depolarization of primary afferents during real scratching in the cat

Changes in depolarization of primary afferents and their correlation with afferent impulsation and limb movement were studied in the lumbar spinal cord during real scratching of decerebrated cats. Two components in rhythmic dorsal root potential were observed. First--centrally evoked, retained during fictitive scratching after immobilization; second--evoked by afferent discharge, coming to the spinal cord during the scratching phase of the limb movement.     

Metabolic and ionic dependence of neuronal responses evoked by serotonin in the rat sensory ganglia

The membrane potential and conductance alterations of rat dorsal root ganglion neurons evoked by serotonin applied in bath or from a micropipette under pressure have been studied by intracellular technique. Serotonin application evoked depolarization with a decrease in membrane conductance and hyperpolarization with an increase in its conductance. A part of depolarization responses mediated by 5-HT2 receptor activation were independent of intracellular AMP concentration and associated with blockade of M-current channels. The other part of depolarizing and all hyperpolarizing responses mediated by 5-HT1A receptor activation were depressed by pertussis toxin and considerably modulated by intracellular AMP alterations. These responses were shown to be associated with disturbances in the function of AMP-dependent potassium ionic channels.     

Changes in the segmental reactions in the decerebrate cat during scratching and locomotion

Experiments on decerebrate cats have shown that N1 component potential of dorsal surface and dorsal root potential elicited by electrical stimulation of paw plantar surface tonically decrease during locomotion and scratching. Phase changes occur against a background of tonic changes in the rhythm of limb movements. The dynamics of the observed changes correlates well with that of primary afferent depolarization during these movements. It is concluded that presynaptic inhibition underlies the changes in segmental reactions.     

Depression of afferent-induced primary afferent depolarization at the lumbar spinal cord following concussive head injury

Afferent-induced primary afferent depolarization (PAD) was depressed for 2-5 min following concussive head injury in the cat, as assessed by dorsal root potentials and augmentation of antidromic dorsal root potentials, both evoked by stimulation of adjacent dorsal roots. These changes in PAD were abolished by spinal cord transection but not affected by midpontine transection. Spontaneous dorsal root potentials, resting amplitudes of antidromic dorsal root potentials and reductions of antidromic dorsal root potentials following tetanic root stimulation were not substantially altered by injury. These findings suggest that concussive head injury depresses spinal interneuronal transmission by neurally mediated processes involving the bulbar brainstem.     

Enkephalins modulate excitatory synaptic transmission in the superficial dorsal horn by acting at μ-opioid receptor sites

The effect of opioids on synaptic potentials of dorsal horn (DH) neurons has been investigated in a rat spinal cord DH slice-dorsal root ganglion (DRG) in vitro preparation. Conventional intracellular recording from DH and DRG neurons using 3 M potassium acetate-filled electrodes was employed. Dorsal roots were electrically isolated from the spinal cord slice and stimulated with pulses of different intensity and duration to evoke afferent action potentials monitored intracellularly from DRG neurons. Low-intensity single-shock stimulation of the dorsal roots (8–20 V pulses of 0.02–0.05 ms duration) activated large primary afferents and elicited excitatory postsynaptic potentials (EPSP) in all of the neurons tested. High-intensity stimulation of the dorsal roots (over 35 V pulses of 0.5 ms duration), sufficient to excite small myelinated and unmyelinated primary afferents resulted in a large and prolonged depolarization of DH neurons associated with firing of action potentials. Bath application (d-Ala², N-Me-Phe⁴,Gly⁵-ol)-enkephalin (DAGO), (d-Ala², d-Leu⁵)-enkephalinamide (DADLEA), or (d-Ala², d-Met⁵)-enkephalinamide (DADMEA) produced dose-dependent, reversible hyperpolarization in about 75% of the neurons tested. The hyperpolarization was associated with a fall in neuronal input resistance. In addition, opioids depressed the synaptic transmission in all of the neurons examined. This depressant effect of opioids was independent from their effects on resting membrane potential. Delta specific receptor opioid agonists (d-Pen^2.5)-enkephalin (DPDPE) and (d-Pen², l-Pen⁵)-enkephalin (DPLPE), were completely ineffective in producing an effect on neuronal membrane or synaptic transmission. All opioid effects were antagonized by naloxone.     

GABAergic terminals are presynaptic to primary afferent terminals in the substantia gelatinosa of the rat spinal cord

Multiple, dorsal rhizotomies were performed unilaterally at lumbar levels L1–L4 in adult rats. Following 24–48 h degeneration periods and fixation by intracardiac perfusions, spinal cord were removed and transversely cut into 150 μm thick sections. These sections were incubated in immunocytochemical reagents for the peroxidase-labeling of glutamic acid decarboxylase (GAD), the enzyme that synthesizes the neurotransmitter γ-aminobutyric acid (GABA). The sections were then prepared for electron microscopic examination, while other sections were processed for light microscopic, GAD immunocytochemistry and for Fink-Heimer staining of degenerating axons and axon terminals.Thirty-six hours following dorsal rhizotomies, the sections that were prepared for the light microscopic study of terminal degeneration showed large numbers of degenerating profiles in the ipsilateral substantia gelatinosa while degenerating profiles were virtually absent contralaterally. In electron microscopic preparations, degenerating primary afferent terminals were commonly observed at the centers of rosettes where they formed synaptic contacts with other axon terminals and with surrounding dendrites. Several types of synaptic relationships were observed in the rosettes which involved both GAD-positive and degenerating primary afferent terminals. Such synaptic relationships included those in which: (a) a single GAD-positive terminal was presynaptic to the central, primary afferent terminal, (b) two different GAD-positive terminals formed synapses with opposite sides of the same central, primary afferent terminal and were also closely apposed to the surrounding dendrites of the rosette, and (c) a GAD-positive terminal was presynaptic to a primary afferent terminal and both types of terminals were presynaptic to the same dendrite of the rosette.The synaptic relationships described in this study are discussed with respect to their possible functional roles in such GABA-mediated phenomena as: (a) primary afferent depolarization, (b) the dorsal root reflex and (c) primary afferent hyperpolarization. Our observations support the concept that GABAergic axon terminals are involved in the synaptic circuits which produce presynaptic inhibition and presynaptic facilitation of the primary afferent input to the dorsal spinal cord. Collectively the observed synaptic relationships could provide a morphological substrate that is compatible with an inhibitory surround system in the substantia gelatinosa.