Analysis of the galanin-induced decrease in membrane excitability in mudpuppy parasympathetic neurons

Selective stimulation of GalR1 and GalR2 in rat substantia gelatinosa reveals a cellular basis for the anti- and pro-nociceptive actions of galanin

Galanin modulates spinal nociceptive processing by interacting with two receptors, GalR1 and GalR2. The underlying neurophysiological mechanisms were examined by whole-cell recording from identified neurons in the substantia gelatinosa of young adult rats. GalR1 was activated with a 'cocktail' containing the GalR1/2 agonist, AR-M 961 (0.5 microM), in the presence of the GalR2 antagonist, M871 (1.0-2.5 microM). GalR2 was activated with the selective agonist, AR-M 1896 (0.5-1.0 microM). Application of the 'GalR1 agonist cocktail' often activated an inwardly-rectifying conductance in delay firing (excitatory) and tonically firing (inhibitory) neurons. This conductance was not activated by AR-M 1896 which instead decreased or increased an outwardly-rectifying conductance at voltages positive to -70 mV. Despite this variability in its actions on current-voltage relationships, AR-M 1896 very consistently decreased membrane excitability, as measured by cumulative action potential latency in response to a depolarizing current ramp. This strong GalR2-mediated effect was seen in neurons where membrane conductance was decreased, and where membrane excitability might be predicted to increase. GalR2 was also located presynaptically, as AR-M 1896 increased the interevent interval of spontaneous EPSCs in both delay and tonic cells. By contrast, the 'GalR1 agonist cocktail' had little effect on spontaneous EPSCs, suggesting that presynaptic terminals do not express GalR1. These diverse actions of GalR1 and GalR2 activation on both inhibitory and excitatory neurons are discussed in relation to the known spinal antinociceptive and pro-nociceptive actions of galanin, to the possible association of GalR1 with the inhibitory G-protein, G(i/o) and to report that GalR2 activation suppresses Ca2+ channel currents.

Development of galanin-like immunoreactivity in the brain of the brown trout (Salmo trutta fario), with some observations on sexual dimorphism

The development of galanin-like immunoreactive (GAL-ir) cells and fibers was investigated in the brain of brown trout embryos, alevins, juveniles, and adults (some spontaneously releasing their gametes). The earliest GAL-ir neurons appeared in the preoptic region and the primordial hypothalamic lobe of 12-mm embryos. After hatching, new GAL-ir neurons appeared in the lateral, anterior, and posterior tuberal nuclei, and in late alevins, GAL-ir neurons appeared in the area postrema. In juveniles, further GAL-ir populations appeared in the nucleus subglomerulosus and magnocellular preoptic nucleus. The GAL-ir neuronal groups present in juveniles were also observed in sexually mature adults, although the area postrema of males lacked immunoreactive neurons. Moreover, spawning males exhibited GAL-ir somata in the olfactory bulb and habenula, which were never observed in adult females or in developing stages. In adults, numerous GAL-ir fibers were observed in the ventral telencephalon, preoptic area, hypothalamus, neurohypophysis, mesencephalic tegmentum, ventral rhombencephalon, and area postrema. Moderate to low GAL-ir innervation was seen in the olfactory bulbs, dorsomedial telencephalon, epithalamus, medial thalamus, optic tectum, cerebellum, and rhombencephalic alar plate. There were large differences among regions in the GAL-ir innervation establishment time. In embryos, GAL-ir fibers appeared in the preoptic area and hypothalamus, indicating early expression of galanin in hypophysiotrophic centers. The presence of galanin immunoreactivity in the olfactory, reproductive, visual, and sensory-motor centers of the brain suggest that galanin is involved in many other brain functions. Furthermore, the distribution of GAL-ir elements observed throughout trout development indicates that galaninergic system maturation continues until sexual maturity.

Galanin activates an inwardly rectifying potassium conductance and inhibits a voltage-dependent calcium conductance in mudpuppy parasympathetic neurons

Galanin-induced activation of an inwardly rectifying membrane potassium (K+) current and inhibition of barium current (IBa) were studied using whole cell voltage clamp recording techniques in parasympathetic neurons dissociated from the mudpuppy cardiac ganglion. Both activation of the K+ current and inhibition of IBa were concentration-dependent with an EC50 (or IC50) of approximately 35 nM and approximately 0.4 nM, respectively. Both actions of galanin were eliminated by pretreatment with pertussis toxin, which suggested involvement of Gi/Go protein activation. Galantide antagonized the galanin-induced activation of K+ current with an IC50 equal to 4 nM. By contrast, galantide, by itself, inhibited IBa with an EC50 equal to 16 nM. Another galanin analog, M40, primarily antagonized the galanin-induced activation of K+ current, but in some cells, M40 also acted as a weak agonist. M40, like galantide, inhibited IBa. The NH2-terminal fragment galanin-(1-16) activated the K+ current and inhibited IBa, indicating that the first 16 amino acids of the galanin peptide were sufficient for both actions. In summary, it is postulated that the effects of galanin on mudpuppy parasympathetic neurons might be mediated by activation of two different subtypes of galanin receptor, one that regulates membrane K+ conductance and a second that modulates calcium conductance.

Vagal afferent innervation of the atria of the rat heart reconstructed with confocal microscopy

We have used confocal microscopy to analyze the vagal afferent innervation of the rat heart. Afferents were labeled by injecting 1,1'-dioleyl-3,3,3',3'-tetramethylindocarbocyanine methanesulfonate (DiI) into the nodose ganglia of animals with prior supranodose de-efferentations, autonomic ganglia were stained with Fluoro-gold, and tissues were examined in whole mounts. Distinctively different fiber specializations were observed in the epi-, myo-, and endocardium: Afferents to the epicardium formed complexes associated with cardiac ganglia. These ganglia consisted of four major ganglionated plexuses, two on each atrium, at junctions of the major vessels with the atria. Ganglionic locations and sizes (left > right) were consistent across animals. In addition to principal neurons (PNs), significant numbers of small intensely fluorescent (SIF) cells were located in each of these plexuses, and vagal afferents provided dense pericellular varicose endings around the SIF cells in each ganglionic plexus, with few if any terminations on PNs. In the myocardium, vagal afferents formed close contacts with cardiac muscles, including conduction fibers. In the endocardium, vagal fibers formed "flower-spray" and "end-net" terminals in connective tissue. With three-dimensional reconstruction of confocal optical sections, a novel polymorphism was seen: Some fibers had one or more collaterals ending as endocardial flower sprays and other collaterals ending as myocardial intramuscular endings. Some unipolar or pseudounipolar neurons within each cardiac ganglionic plexus were retrogradely labeled from the nodose ganglia. In conclusion, vagal afferents form a heterogeneity of differentiated endings in the heart, including structured elements which may mediate chemoreceptor function, stretch reception, and local cardiac reflexes.

Effect of vibrissae deprivation on follicle innervation, neuropeptide synthesis in the trigeminal ganglion, and S1 barrel cortex plasticity

Deprivation of vibrissae from an early age causes plasticity in S1 barrel cortex. This method of deprivation is most likely to induce plasticity by altering the balance of primary afferent activity from the deprived and spared vibrissae. To study whether or not induction or expression of this type of plasticity might be affected by follicle nerve injury caused by the deprivation technique, three different methods of detecting nerve injury were used: counting axon numbers in the distal follicle nerve, quantifying morphological changes in axons, and measuring neuropeptide expression in the trigeminal ganglion cells. First, nerves innervating follicles chronically deprived of vibrissae from birth had the same number of myelinated and unmyelinated axons as nerves from normally reared animals. Second, axons innervating deprived follicles showed no morphological changes in myelination or mitochondria characteristic of damaged nerves. Third, the corresponding nerve cell bodies in the trigeminal ganglion did not show upregulation of galanin or neuropeptide Y expression. In contrast, animals receiving mild injury of the follicle nerve endings (by cauterization of the follicle) showed profound changes in axonal myelination and mitochondria and increases in neuropeptide expression. These results imply that vibrissae deprivation does not act by inducing injury of the follicular nerve, suggesting that changes in the balance of follicle nerve activity are the cause of cortical plasticity. Consistent with this notion, a fourth experiment demonstrated that trimming the vibrissae induces cortical plasticity comparable to that induced by complete vibrissae removal.

Vasodilatation and smooth muscle membrane potential changes in arterioles from the guinea-pig small intestine

1. Dilatation of arterioles isolated from the guinea-pig small intestine was evoked by stimulation of a submucous ganglion and the application of acetylcholine, vasoactive intestinal peptide, galanin or dynorphin A. Changes in arteriole diameter and smooth muscle membrane potential were recorded simultaneously. 2. Ganglion stimulation caused vasodilatation and smooth muscle hyperpolarization that varied in both amplitude and time course from one arteriole to another. Vasodilatation could occur without hyperpolarization. 3. Vasodilatation caused by acetylcholine was accompanied by a rapidly developing hyperpolarization that began to decline before the maximum vasodilator effect had developed. 4. Vasoactive intestinal peptide caused dilatation without any change in smooth muscle membrane potential. 5. Galanin and dynorphin caused dilatation and a hyperpolarization of similar time course to the dilatation. 6. In 48% of arterioles tested the dilatation appeared to be mediated solely by acetylcholine. In 31% there was a cholinergic component, but no evidence for the involvement of acetylcholine in the remaining 21%. When the non-cholinergic dilatation occurred without a hyperpolarization we conclude that it was due to vasoactive intestinal peptide; otherwise it may have been due to either galanin or dynorphin.

Protective effect of galanin on behavioral deficits in experimental traumatic brain injury

The magnitude of behavioral deficits in traumatic brain injury (TBI) has been shown to be partly related to alterations in the balance between excitatory and inhibitory neurotransmitter release. Previous studies have demonstrated that extracellular excitatory neurotransmitter concentrations dramatically increase following experimental TBI. We examined the effects of a neuromodulatory peptide, galanin (GAL), on behavioral morbidity, as measured by sensory motor and memory performance tasks, associated with experimental TBI in the rat. A single intraventricular injection of GAL (1.0 micrograms, n = 8 or 10.0 micrograms, n = 10) or cerebrospinal fluid (CSF) vehicle (n = 10) was administered 5 minutes prior to central fluid percussion TBI in rats. Performance on sensory motor tasks was assessed prior to injury and for 5 days after TBI with beam-balance, beam-walking, and rotarod tasks. Memory performance was assessed on days 11-15 after TBI with the Morris water maze. TBI produced significant motor and memory deficits in the CSF-treated group. GAL-treated rats had significantly less magnitude of deficits compared to CSF-treated rats on beam-balance, beam-walking, and rotarod performance. The 1.0 micrograms GAL dose produced slightly greater protection than the 10.0 micrograms GAL dose. Neither GAL dose affected body weight loss or Morris water maze performance. These results suggest that the physiologic effects of GAL may reduce certain components of TBI morbidity, possibly by modulating neuronal excitability.

Bethanechol-induced responses in mudpuppy parasympathetic neurons

The effect of bethanechol on membrane potential and excitability was determined in mudpuppy parasympathetic postganglionic neurons. Bethanechol induced a large amplitude hyperpolarization, which was followed by a smaller amplitude depolarization, in 115 out of 135 cells tested. In approximately 20% of these cells, a brief depolarization preceded the hyperpolarization. During the bethanechol-induced hyperpolarization, the membrane input resistance decreased markedly, whereas the input resistance was increased during the subsequent depolarization. The hyperpolarization and depolarization were blocked by atropine and were unaffected by d-tubocurarine, thus, both appeared to be mediated by muscarinic receptors. The bethanechol-induced hyperpolarization was inhibited by the M2 muscarinic receptor antagonist AF-DX 116, whereas the bethanechol-induced depolarization was unaffected. Both a nonselective increase in membrane conductance and a decrease in membrane potassium conductance appeared to be involved in the generation of the bethanechol-induced depolarization. Evidence for the first mechanism was obtained in barium-treated cells in which bethanechol initiated a rapid onset depolarization, which was reversed at membrane potentials near 0 mV. Evidence for the second mechanism was obtained when the hyperpolarization was inhibited by AF-DX 116. In AF-DX 116-treated cells, the membrane input resistance was increased during most of the bethanechol-induced depolarization. Mudpuppy neurons initiate repetitive action potential activity in response to long depolarizing current pulses. Following application of bethanechol, with the hyperpolarization negated electrotonically, the number of action potentials produced by a depolarizing current pulse was greater than that produced prior to application of bethanechol. It is suggested that activation of muscarinic receptors on mudpuppy cardiac neurons influences multiple conductance systems and determines the excitability of these neurons.

Immunocytochemical localization of a galanin-like peptidergic system in the brain of two urodele and two anuran species (Amphibia)

Galanin-like immunoreactivity was localized in the brain of Urodela (Ambystoma, Pleurodeles) and Anura (Bufo, Xenopus) by immunocytochemistry with anti-porcine galanin antiserum. In the four species, immunoreactive perikarya were observed in the telencephalon (striatum, amygdala), diencephalon preoptic area mainly along the anterodorsal wall of the preoptic recessus, suprachiasmatic nucleus, lateral hypothalamus, ventral and dorsal infundibular nuclei, paraventricular organ, and rhombencephalon (nucleus of the solitary tract). Galaninergic fibres extended in similar regions and in the medial septum, ventral telencephalon, ventral hypothalamus, median eminence, and various mesencephalic and rhombencephalic regions. Contacts with the cerebrospinal fluid cavity occurred along the preoptic recessus (Ambystoma) and the ventral infundibular wall (all species). Fibres were scarce in the neurohypophysis. The distal and intermediate lobes of the pituitary were virtually devoid of immunoreactivity. The galaninergic system appeared more developed in adult amphibia than in young animals, suggesting the stimulating influence of sex steroids on the expression of galanin as previously described in Anguilla. The extensive distribution of the galanin-like immunoreactive neurons in amphibian brains suggests that this peptide may act as a neuromodulatur and/or neurotransmitter.