Divalent cations reduce depolarization of primary afferent terminations by GABA

Divalent metal cations, including zinc, cadmium, cobalt, nickel, strontium, manganese, magnesium and calcium, reduced the depolarization by microelectrophoretic γ-aminobutyric acid (GABA) and piperidine-4-sulphonic acid of the central terminations of muscle group Ia primary afferent fibres in the cat spinal cord without affecting the inhibition by GABA of the firing of spinal interneurones. There thus appears to be a difference in either the interaction of GABA with recognition sites, or in the mechanism by which such interaction activates chloride ionophores, at GABA-mediated bicuculline-sensitive synapses on the central terminals of peripheral primary afferent neurones and those on neurones located within the central nervous system.     

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 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 effect of GABA on the terminations of vestibulospinal neurons in the cat spinal cord

Although GABA and piperidine-4-sulphonate depolarize Ia afferent terminations in the lumbar spinal cord by activation of bicuculline-sensitive GABA receptors, no evidence was obtained for abicuculline-sensitive alteration by either GABAmimetic of the excitability of vestibulospinal terminations. This suggests that the terminal arborizations of vestibulospinal fibers, unlike their cell bodies. are devoid of GABA receptors having properties similar to those on either central neuron cell bodies, primary afferent cell bodies or their central terminations.     

Phaclofen: a peripheral and central baclofen antagonist

Phaclofen, the phosphonic acid derivative of baclofen, reversibly antagonized the depression of the cholinergic twitch response of the guinea pig ileum and distal colon by either baclofen or GABA. When administered microelectrophoretically, phaclofen reversibly blocked the presumed presynaptic reduction by baclofen of the monosynaptic excitation of spinal interneurones by impulses in primary afferent fibres of the cat but did not block the postsynaptic depressant action of baclofen on these neurones. Phaclofen may thus be useful in determining the physiological significance of central and peripheral bicuculline-insensitive receptors with which GABA and (-)-baclofen interact.     

Specific and potassium components in the depolarization of the la afferents in the spinal cord of the cat

In the cat spinal cord, primary afferent depolarization (PAD) of group Ia fibers of extensor muscles is produced by high-frequency stimulation (100 Hz) of group I muscle flexor afferents without significant increases in extracellular potassium. On the other hand, the PAD produced by stimulation of mixed and pure cutaneous nerves correlates well with increases in potassium ions. We conclude that the PAD produced by group I muscle afferents results from the activation of specific pathways making axo-axonic synapses with the Ia fiber terminals. The PAD of Ia fibers resulting from activation of cutaneous nerves involves instead unspecific accumulation of potassium ions.     

Specific and potassium components in the depolarization of the Ia afferents in the spinal cord of the cat

In the cat spinal cord, primary afferent depolarization (PAD) of group Ia fibers of extensor muscles is produced by high-frequency stimulation (100 Hz) of group I muscle flexor afferents without significant increases in extracellular potassium. On the other hand, the PAD produced by stimulation of mixed and pure cutaneous nerves correlates well with increases in potassium ions. We conclude that the PAD produced by group I muscle afferents results from the activation of specific pathways making axo-axonic synapses with the Ia fiber terminals. The PAD of Ia fibers resulting from activation of cutaneous nerves involves instead unspecific accumulation of potassium ions.     

Modification of primary afferent depolarization in cat group Ia afferents following high frequency intra-axonal tetanization of individual afferents

Intra-axonal tetanization of a single, functionally-identified group Ia afferent from the triceps surae muscle in the anesthetized cat produces marked enhancement and slowing of the primary afferent depolarization (PAD) generated in the Ia afferent by volleys in flexor muscle group Ia afferents, plus a pronounced transmembrane hyperpolarizing undershoot (HPU) which disappears more rapidly than the enhanced PAD. These alterations are qualitatively and quantitatively similar to those found after conditioning tetani are applied to the whole muscle nerve. The occurrence of these PAD changes after intra-axonal tetanization of a single group Ia afferent appears to rule out the participation of non-specific alterations in extracellular ionic concentrations or activation of polysynaptic pathways in their genesis.     

Direct observations of synapses between GABA-immunoreactive boutons and muscle afferent terminals in lamina VI of the cat''s spinal cord

Single group Ia muscle afferent fibers in the lumbar spinal cord of the cat impaled with microelectrodes and labelled with horseradish peroxidase. Two collateral axons were prepared for combined light and electron microscopy. Arbors selected from lamina VI were processed by the postembedding immunogold technique with antiserum which specifically recognizes GABA in glutaraldehyde-fixed tissue. Twelve Ia boutons were examined through series of thin sections with the electron microscope and all of them were associated with presynaptic axon terminals which were positively labelled for GABA. Some Ia boutons received synaptic contacts from several GABAergic terminals. The present study establishes that a GABA-like substance is present in axon terminals presynaptic to Ia afferent boutons in lamina VI of the spinal cord. This evidence provides a morphological basis for presynaptic inhibition of Ia afferent input into lamina VI.     

Inhibition of spinal or hypoglossal motoneurons of the newborn rat by glycine or GABA

The function of GABA or glycine during early postnatal development remains controversial as their action is reported as either excitatory or inhibitory. The present study addressed the question of the functional role of GABA or glycine on rat motoneurons shortly after birth. For this purpose, using in vitro preparations from immature rats (postnatal age, P0-P4 days), we recorded from lumbar spinal motoneurons and hypoglossal motoneurons. All data were obtained under current clamp conditions (recording with potassium methylsulphate containing electrodes) from cells at about -70 mV resting potential. On spinal motoneurons we used the glycinergic and GABAergic recurrent postsysnaptic potential (PSP) mediated by Renshaw cells to assess its impact on excitatory synaptic inputs from dorsal afferent fibres. Despite its depolarizing nature, the recurrent PSP consistently inhibited synaptic excitation of lumbar motoneurons. On hypoglossal motoneurons, exogenously applied GABA or glycine produced depolarization with decreased input resistance. This response was always associated with inhibition of cell firing induced by intracellular current pulses. Even when the membrane potential was repolarized to resting level in the presence of GABA or glycine, hypoglossal motoneurons failed to generate spikes. Conversely, similar depolarization produced by glutamate consistently facilitated spike firing. GABAergic and glycinergic synaptic potentials evoked by focal stimulation of the reticular formation inhibited firing and/or increased firing latency in the majority of hypoglossal motoneurons. These results indicate that, immediately after birth, rat motoneurons were inhibited by synaptically released or exogenously applied GABA or glycine.     

Effects of noradrenaline and 5-hydroxytryptamine on spinal la afferent terminations

When administered microelectrophoretically, noradrenaline (NA) and 5-hydroxytryptamine (5-HT) increased the thresholds of the terminal portions of extensor muscle Ia afferents stimulated extracellularly near lumbar motoneurons of anesthetized cats. This effect, and the concomitant increase in the electrical resistance of the extracellular medium near the orifices of multibarrel micropipettes, could be reversibly altered by ouabain. The results suggest further evidence is required of a direct effect of these amines at transmitter-related receptors on Ia terminations since the observed increase in threshold may be indirect, resulting from the sodium-dependent uptake of the administered amines by neurons and glia.     

Phase-dependent modulation of dorsal root potentials evoked by peripheral nerve stimulation during fictive locomotion in the cat

To help elucidate the role of presynaptic mechanisms in the control of locomotor movements, the transmission of PAD pathways was investigated by recording dorsal root potentials (DRPs) evoked by electrical stimulation of cutaneous and muscle nerves of both hindlimbs at various phases of the fictive step cycle. Fictive locomotion occurred spontaneously in decorticate cats or by stimulating the mesencephalic locomotor region (MLR) as well as in low spinal cats injected with nialamide and L-DOPA. Evoked DRPs were superimposed on a fluctuating DRP accompanying the fictive locomotor rhythm (locomotor DRP) which typically consisted of two peaks of depolarization per cycle, the largest peak occurring during the flexor phase. The amplitude of evoked DRPs was substantially modulated throughout the locomotor cycle and followed a similar modulation pattern for all stimulated nerves whether ipsilateral (i-) or contralateral (co-). The amplitude of evoked DRPs decreased at the beginning of the flexor phase, dropped to a minimum later in the flexor phase and then increased during the extensor phase where it became maximum. Results were comparable in decorticate and spinal preparations and for L6 and L7 rootlets with cutaneous and muscle nerve stimulation. It is noteworthy that the modulation pattern for a given rootlet was similar for i- and co- stimulation, even though the bilateral locomotor DRPs fluctuate out-of-phase with each other, subjecting the stimulated fibres to opposite presynaptic polarization changes. This suggests that the modulation may depend more on the presynaptic mechanisms of the receiving fibres than on those of the stimulated fibres. These results demonstrate that the transmission in spinal pathways involved in primary afferent depolarization (PAD) is phasically modulated by the activity in the spinal locomotor network. It is further suggested that the presynaptic inhibition associated with PAD evoked by movement-related sensory feedback during real locomotion could be modulated in a similar way.     

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.     

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.     

Co‐localized neuropeptide Y and GABA have complementary presynaptic effects on sensory synaptic transmission

We have examined the morphological relationship of neuropeptide Y (NPY) and GABAergic neurons in the lamprey spinal cord, and the physiological effects of NPY and GABA_B receptor agonists on afferent synaptic transmission. NPY-containing fibres and cell bodies were identified in the dorsal root entry zone. NPY immunoreactive (–ir) fibres made close appositions with primary afferent axons. Co-localization of NPY and GABA-ir was found in the dorsal horn and dorsal column. Fifty-two per cent of NPY-ir profiles showed immunoreactivity to GABA at the ultrastructural level. Electron microscopic analysis showed that NPY-immunoreactivity was present throughout the axoplasm, including over dense core vesicles, whereas GABA-immunoreactivity was mainly found over small synaptic vesicles. Synthetic lamprey NPY, and the related peptide, peptide YY, reduced the amplitude of monosynaptic afferent EPSPs in spinobulbar neurons. NPY had no significant effect on the postsynaptic input resistance or membrane potential, the electrical component of the synaptic potential, or the response to glutamate, but it could reduce the duration of presynaptic action potentials, suggesting that it was acting presynaptically. NPY also reduced the excitability of the spinobulbar neurons, suggesting at least one postsynaptic effect. Because NPY and GABA colocalize, we compared the effects of NPY and the GABA_B agonist baclofen. Both presynaptically reduced EPSP amplitudes, baclofen having a larger effect and a faster onset and recovery than NPY. The GABA_B antagonist phaclofen reduced the effect of baclofen, but not that of NPY. We conclude that NPY and GABA are colocalized in terminals in the dorsal spinal cord of the lamprey, and that they have complementary actions in modulating sensory inputs.     

GABAergic synaptic transmission modulates swimming in the ascidian larva

To examine the role of the amino acid GABA in the locomotion of basal chordates, we investigated the pharmacology of swimming and the morphology of GABA-immunopositive neurones in tadpole larvae of the ascidians Ciona intestinalis and Ciona savignyi. We verified that electrical recording from the tail reflects alternating muscle activity during swimming by correlating electrical signals with tail beats using high-speed video recording. GABA reversibly reduced swimming periods to single tail twitches, while picrotoxin increased the frequency and duration of electrical activity associated with spontaneous swimming periods. Immunocytochemistry for GABA revealed extensive labelling throughout the larval central nervous system. Two strongly labelled regions on either side of the sensory vesicle were connected by an arc of labelled fibres, from which fibre tracts extended caudally into the visceral ganglion. Fibre tracts extended ventrally from a third, more medial region in the posterior sensory vesicle. Two rows of immunoreactive cell bodies in the visceral ganglion extended neurites into the nerve cord, where varicosities were seen. Thus, presumed GABAergic neurones form a network that could release GABA during swimming that is involved in modulating the time course and frequency of periods of spontaneous swimming. GABAergic and motor neurones in the visceral ganglion could interact at the level of their cell bodies and/or through the presumed GABAergic fibres that enter the nerve cord. The larval swimming network appears to possess some of the properties of spinal networks in vertebrates, while at the same time possibly showing a type of peripheral innervation resembling that in some protostomes.     

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.     

Actions of ATP on the soma of bullfrog primary afferent neurons and its modulating action on the GABA-induced response

Adenosine 5′-triphosphate (ATP) produced a long-lasting depolarization inbullfrog spinal ganglion cells. Since the ATP-induced slow depolarization was associated with an increase in membrane resistance and a reverse in polarity (about—90mV) which was most likely brought about by an inactivation of membrane potassium conductance. In some cells, a rapid and transient depolarization followed by the long-lasting depolarization was produced by ATP and it was markedly reduced in sodium-free solution. ATP reversibly augmented the GABA-induced depolarization which was caused by ionophoresis of GABA. These observations were confirmed using a voltage clamp method. Dose-response analysis of the action of ATP on the GABA-induced response suggests that the facilitatory action of ATP on the GABA response is effected on the GABA receptor channel complexes without changing the GABA affinity.     

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.     

Strychnine sensitive inhibition in the dorsal horn of mammalian spinal cord

Using an in-vitro mammalian spinal cord preparation 3 pharmacologically distinct phases of inhibition have been demonstrated in the dorsal horn. An early picrotoxin-sensitive inhibition was followed by an intermediate strychnine-sensitive phase and a late phase resistant to both strychnine and picrotoxin. The picrotoxin-sensitive inhibition was accompanied by an increase in excitability of the afferent fibres which was prolonged by strychnine, suggesting the presence of glycine mediated inhibition of GABA primary afferent depolarization.