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.     

Dorsal root potentials in the cat: effects of bicuculline

Bicuculline (0.2 1 mg/kg) administered intravenously depressed dorsal root potentials (DRPs) evoked by stimulation of mixed, pure muscle or pure cutaneous nerves which was clearly concurrent with enhanced background potentials in intact cat. Administration of sodium pentobarbitone (15-30 mg/kg i.v.) reduced the ability of bicuculline to enhance background potentials and to depress evoked DRPs. In spinalized preparations, bicuculline depression of evoked DRPs by bicuculline in intact cat may not result from its action at axo-axonic GABAergic synapses alone and occlusion may also play a part. However, the role of gamma-aminobutyric acid (GABA) in primary afferent depolarization is confirmed in the spinalized preparations.     

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.     

The role of GABA and serotonin in the mediation of raphe-evoked spinal cord dorsal root potentials

The possible involvement of bulbospinal serotonergic systems in the mediation of analgesia has created a need for a better understanding of the influence this system has on neuronal mechanisms in the spinal cord. Therefore, these studies were designed to examine the effects of caudal raphe stimulation on primary afferent depolarization and to determine the role of serotonin (5-HT) and GABA in the mediation of these stimulation-produced effects. Stimulation of the raphe evoked two electrotonically conducted dorsal root potentials (DRP-1 and DRP-2) and two compound action potentials (VRP-1 and VRP-2) which were recorded from the dorsal and ventral roots, respectively. Length constant measurements indicated that DRP-1 was generated in group II and DRP-2 in group I primary afferent fibers. Histological determination of stimulation sites revealed that short-latency potentials (DRP-1 and VRP-1) were evoked from many sites within the caudal brain stem, while the long-latency potentials (DRP-2 and VRP-2) were evoked primarily from sites within the caudal raphe nuclei. The role of serotonin in mediating these evoked potentials was assessed by administering various antagonists of serotonin (cinanserin, methysergide and D-lysergic acid diethylamide). These agents consistently attenuated the long-latency potentials (DRP-2 and VRP-2) but increased the magnitude of DRP-1. The possibility of a GABAergic neuron in the descending systems projecting to primary afferent terminals was studied. Depletion of GABA by semicarbazide blocked DRP-1, but had only a modest effect of DRP-2. However, the putative GABA antagonist, bicuculline, inhibited both DRP-1, and DRP-2. These results suggest that a GABA interneuron is not involved in the bulbospinal serotonergic depolarization of primary afferent terminals. This system appears to constitute a presynaptic filter of afferent input, with the capacity to inhibit different fiber groups.     

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.     

Intra-axonal recordings in rat dorsal column axons: membrane hyperpolarization and decreased excitability precede the primary afferent depolarization

Intra-axonal recordings were obtained in the dorsal columns of the rat lumbosacral spinal cord. Dorsal root or dorsal column stimulation at levels subthreshold for the impaled axon elicited a prolonged depolarization corresponding to the primary afferent depolarization (PAD). The depolarization was preceded by a brief hyperpolarizing potential during which excitability was decreased. The hyperpolarization corresponds temporally to the extracellularly recorded DRP IV component of the dorsal root potential described by Lloyd and McIntyre, and may represent the intracellular correlate of this potential. Possible mechanisms for this hyperpolarization include electrical interactions between neuronal elements, a biphasic GABA response, or attenuation of background afferent axonal depolarization.     

The role of 5-HT, GABA and opioid peptides in presynaptic inhibition of tooth pulp input from the medial brainstem

In decerebrate or chloralose-anaesthetized cats electrical stimulation in the spinal trigeminal nucleus evoked antidromic responses in the mandibular canine tooth pulp. Conditioning stimulation in nucleus raphe magnus (NRM) and in the adjacent contralateral medullary reticular formation, nucleus reticularis gigantocellularis (NRGC) and nucleus reticularis magnocellularis (NRMC), produced a decrease in the threshold for the antidromic responses in a proportion of the tooth pulp inputs. This was interpreted as being due to depolarization of the tooth pulp afferent terminals, reflecting presynaptic inhibition. The primary afferent depolarization (PAD) of tooth pulp afferent terminals by NRM stimulation could be selectively blocked by bicuculline applied intravenously or by iontophoresis in the terminal region. Intravenous naloxone, cinanserin and methysergide had no effect on the PAD evoked from NRM, NRGC or NRMC. Thus NRM appears to exert presynaptic inhibitory control of A delta tooth pulp input to the spinal trigeminal nucleus via GABA-containing neurones.     

The effects of naloxone, morphine and methionine enkephalinamide on Ia afferent terminations in the cat spinal cord

Naloxone, morphine, Met5-enkephalinamide (MENKA) and procaine were administered microelectrophoretically near extracellularly stimulated extensor muscle group Ia afferent fibres and terminations in the lumbar spinal cord of cats anaesthetized with pentobarbitone sodium. Observations were made of effects on the electrical threshold, on the depolarizing action of GABA or piperidine-4-sulphonate (P4S), and on bicuculline-sensitive primary afferent depolarization (PAD) generated by tetanic stimulation of flexor muscle low threshold afferents. All 4 agents reversibly elevated the threshold of Ia fibres in the dorsal column and Ia terminations in the ventral horn. The depolarizations of terminations by GABA or P4S were also reduced, an effect, which for all except MENKA, probably accounted for a concomitant reduction in PAD. In the absence of a consistent effect on either threshold or depolarization by GABAmimetics, MENKA reversibly diminished PAD, an action blocked by naloxone. Intravenously administered naloxone, in doses known to enhance spinal monosynaptic excitation in the cat, had no effect on GABAergic PAD and little or no effect on Ia termination threshold. The results are discussed in relation to a naloxone-sensitive effect of MENKA which reduces transmitter release from GABAergic axo-axonic synapses on Ia terminals, but which does not account for the enhancement of spinal reflexes by naloxone.     

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.     

Olfactory ensheathing cell grafts have minimal influence on regeneration at the dorsal root entry zone following rhizotomy

The effectiveness of grafts of olfactory ensheathing cells (OECs) as a means of promoting functional reconnection of regenerating primary afferent fibers was investigated following dorsal root injury. Adult rats were subjected to dorsal root section and reanastomosis and at the same operation a suspension of purified OECs was injected at the dorsal root entry zone and/or into the sectioned dorsal root. Regeneration of dorsal root fibers was then assessed after a survival period ranging from 1 to 6 months. In 11 animals, electrophysiology was used to look for evidence of functional reconnection of regenerating dorsal root fibers. However, electrical stimulation of lesioned dorsal roots failed to evoke detectable cord dorsum or field potentials within the spinal cord of any of the animals examined, indicating that reconnection of regenerating fibers with spinal cord neurones had not occurred. In a further 11 rats, immunocytochemical labeling and biotin dextran tracing of afferent fibers in the lesioned roots was used to determine whether regenerating fibers were able to grow into the spinal cord in the presence of an OEC graft. Although a few afferent fibers could be seen to extend for a limited distance into the spinal cord, similar minimal in-growth was seen in control animals that had not been injected with OECs. We therefore conclude that OEC grafts are of little or no advantage in promoting the in-growth of regenerating afferent fibers at the dorsal root entry zone following rhizotomy.     

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)     

Spinal entry route for ventral root afferent fibers in the cat

Twelve anesthetized and paralyzed cats were used to study the spinal entry routes of ventral root afferent fibers. In all animals, the spinal cord was transected at two different levels, L5 and S2. The L5 through S2 dorsal roots were cut bilaterally, making spinal cord segments L5-S2 neurally isolated from the body except for the L5-S2 ventral roots. From this preparation, a powerful excitation of the discharge rate of motor neurons and dorsal horn cells within the isolated spinal segments was observed after intraarterial injection of bradykinin (50 micrograms in 0.5 ml saline). This excitation of the spinal neurons can be considered the most convincing evidence of the potential physiologic role of the ventral root afferent fibers entering the spinal cord directly through the ventral root, because the apparent route of neuronal input from the periphery is through the ventral roots. However, additional control experiments conducted in the present study showed that the excitation persisted even after cutting all ventral roots within the isolated spinal segments, indicating that excitation was not mediated by the ventral roots. Furthermore, direct application of bradykinin on the dorsal surface of the spinal cord also increased the motoneuronal discharge rate, suggesting that excitation of spinal neurons produced by intraarterial injection of bradykinin is due to a direct action of bradykinin on the spinal cord. Thus, we provided an alternate explanation for the most convincing evidence indicating that physiologically important ventral root afferent fibers enter the spinal cord directly through the ventral root. Based on existing experimental evidence, it is likely that the majority of physiologically active ventral root afferent fibers travel distally toward the dorsal root ganglion and then enter the spinal cord through the dorsal root.     

Ultrastructural study of glutamate- and GABA-immunoreactive terminals contacting the primary afferent fibers in frog spinal cord. A double postembedding immunocytochemical study

The in vitro HRP application to the dorsal root of the frog spinal cord produced an intensive staining of primary afferent fibers. A double postembedding GABA and glutamate immunocytochemical study revealed GABA- or glutamate-immunopositive presynaptic boutons establishing axo-axonic synapses onto HRP-stained primary afferent fibers in the spinal cord intermedial zone.     

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.     

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.     

Effect of ammonium acetate on depolarization processes in the central terminals of primary afferents]

Experiments on cats determined that ammonium acetate injected intravenously (2-4 mM/kg) supressed the processes of primary afferent depolarization (PAD) which are thought to be responsible for the presynaptic inhibition of spinal reflexes. The supression was transient and proceeded in paralle to depression of postsynaptic inhibition of monosynaptic reflexes. Ammonium acetate slightly decreased the amplitude of the negative postsynaptic potentials recorded form the dorsal surface of lumbar cord in response to stimulation of hind limb afferent nerves and increased polysynaptic reflex discharges in appropriate ventral roots. These findings make it unlikely that the ammonium depression of PAD is a result of impairment of interneuronal activity. A suggestion is made that ammonium depression of PAD results from diminition of the EMF for synaptic currents producing PAD.     

Recurrent potentials in human peripheral sensory nerve: possible evidence of primary afferent depolarization of the spinal cord.

To study slowly conducted components of the orthodromic compound sensory action potential (CSAP), the response evoked at the lateral malleolus in the sural nerve was recorded through near-nerve needles at two to four sites along the nerve at midcalf. When 500 to 2000 responses were averaged at high gain, components with latencies of 30 to 80 ms were often recorded. In contrast to the main component and late components with latencies of less than 15 to 20 ms, the latencies of these extremely late components diminished the closer to the spinal cord that they were recorded. This suggested that the components were conducted antidromically from proximal to distal. This assumption was supported by abolishing the components by local anesthesia of the nerve proximal to the recording electrodes. These antidromic potentials therefore appear to be due to recurrent discharges in the sural nerve. Recurrent discharges were recorded from 65% of 60 subjects (18 normal subjects and 42 patients with peripheral or central nervous system disorders). The latencies of the recurrent discharges allowed conduction to and back from the spinal cord. Although the origin of these potentials remains unknown, we suggest that they are due to dorsal root reflexes within the spinal cord. In this case, the responses may be a direct expression of primary afferent depolarization (PAD) seen in presynaptic inhibition, and may be of value in further studies on the physiology and pathophysiology of presynaptic inhibition of cutaneous fibers in man.     

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.     

Functions of primary afferents and responses of extracellular K+ during spinal epileptiform seizures.

Paroxysmal activity in ventral roots induced by penicillin in decapitate cat spinal cords is associated with waves of depolarization of primary afferent fiber terminals. These paroxysmal depolarizations can be detected as spontaneously occurring negative dorsal root potentials (DRPs) and are associated with antidromic discharge of nerve impulses in dorsal root fibers; they can also be detected by testing the excitability of afferent nerve terminals by focal stimulation. Negative DRPs evoked by afferent nerve volleys are altered in waveform but not in amplitude during seizures induced by penicillin, although they are blocked by the administration of picrotoxin. While blocking afferent-evoked DRPs, picrotoxin does not interfere with paroxysmal DRP'S, INDICATING DIFFERENCES IN THE GENERATION OF THE Two phenomena, which nevertheless have some link in common, for the paroxysmal waves occlude the evoked DRP. Such occlusion would appear as blockade, if DRPs were recorded by condenser-coupled amplifiers. In the presence of pentobarbital penicillin suppresses evoked DRPs, but under such circumstances seizure activity is not observed. Extracellular potassium activity within spinal gray matter transiently increases during seizure activity. Such increments of potassium activity are maximal in the ventral horns. This and several other observations suggest that in decapitate spinal cords systemically administered penicillin induces seizures which originate in the ventral gray matter. Accumulation of excess potassium may be the cause of paroxysmal depolarization of afferent nerve terminals. Excess potassium while not playing a principal role in initiating seizures, may influence the course of seizures by depolarizing afferent terminals. Such depolarization probably enhances tonic background release of transmitter substance, may modify the effect of synaptic input, and may favor synchronization of waves of neural excitability through extrasynaptic mechanisms.     

Neurochemical and ionic mechanisms of dorsal root potentials in the spinal cord of the immature rat

Dorsal root potentials (DRP) recorded from spinal cord of 7-14-days old rats have two waves of depolarization. The fast wave of DRP is GABA-ergic in nature and the slow wave is evoked mainly by increasing of extracellular K+-ion concentration near the primary afferent terminals. The possible mechanisms of increasing extracellular K+-ion concentration evoked by dorsal root stimulation are discussed.