The anti-botulism triterpenoid toosendanin elicits calcium increase and exocytosis in rat sensory neurons.

Toosendanin, a triterpenoid from Melia toosendan Sieb et Zucc, has been found before to be an effective anti-botulism agent, with a bi-phasic effect at both motor nerve endings and central synapse: an initial facilitation followed by prolonged depression. Initial facilitation may be due to activation of voltage-dependent calcium channels plus inhibition of potassium channels, but the depression is not fully understood. Toosendanin has no effect on intracellular calcium or secretion in the non-excitable pancreatic acinar cells, ruling out general toosendanin inhibition of exocytosis. In this study, toosendanin effects on sensory neurons isolated from rat nodose ganglia were investigated. It was found that toosendanin stimulated increases in cytosolic calcium and neuronal exocytosis dose dependently. Experiments with membrane potential indicator bis-(1,3-dibutylbarbituric acid)trimethine oxonol found that toosendanin hyperpolarized capsaicin-insensitive but depolarized capsaicin-sensitive neurons; high potassium-induced calcium increase was much smaller in hyperpolarizing neurons than in depolarizing neurons, whereas no difference was found for potassium-induced depolarization in these two types of neurons. In neurons showing spontaneous calcium oscillations, toosendanin increased the oscillatory amplitude but not frequency. Toosendanin-induced calcium increase was decreased in calcium-free buffer, by nifedipine, and by transient receptor potential vanilloid 1 (TRPV1) antagonist capsazepine. Simultaneous measurements of cytosolic and endoplasmic reticulum (ER) calcium showed an increase in cytosolic but a decrease in ER calcium, indicating that toosendanin triggered ER calcium release. These data together indicate that toosendanin modulates sensory neurons, but had opposite effects on membrane potential depending on the presence or absence of capsaicin receptor/TRPV 1 channel.

Leptin and CCK modulate complementary background conductances to depolarize cultured nodose neurons.

We have previously reported that intraceliac infusion of leptin induces a reduction of meal size that depends on intact vagal afferents. This effect of leptin is enhanced in the presence of cholecystokinin (CCK). The mechanisms by which leptin and CCK activate vagal afferent neurons are not known. In the present study, we have begun to address this question by using patch-clamp electrophysiological techniques to examine the mechanisms by which leptin and CCK activate cultured vagal afferents from adult rat nodose ganglia. We found that leptin depolarized 41 (60%) of 68 neurons. The magnitude of membrane depolarization was dependent on leptin concentration and occurred in both capsaicin-sensitive and capsaicin-insensitive neurons. We also found that a majority (16 of 22; 73%) of nodose neurons activated by leptin were also sensitive to CCK. CCK-induced depolarization was primarily associated with the increase of an inward current (11 of 12), whereas leptin induced multiple changes in background conductances through a decrease in an outward current (7 of 13), an increase in an inward current (3 of 13), or both (3 of 13). However, further isolation of background currents by recording in solutions that contained only sodium or only potassium revealed that both leptin and CCK were capable of increasing a sodium-dependent conductance or inhibiting a potassium-dependent conductance. Our results support the hypothesis that vagal afferents are a point of convergence and integration of leptin and CCK signaling for control of food intake and suggest multiple ionic mechanisms by which leptin and CCK activate vagal afferent neurons.

Putative role of epithelial sodium channels (ENaC) in the afferent limb of cardio renal reflexes in rats.

Recent studies suggest a role of ion channels of the DEG/ENaC family for mechanosensation in different species and in baroreceptor reflex control in rats. We tested the hypothesis that ENaC within the cardiac sensory network are mandatory for mechanosensation. Experiments were performed in male Sprague-Dawley rats, isolated nodose ganglion cells with cardiac afferents and isolated vagus nerves. Epicardial delivery of the amiloride analogue benzamil intended to specifically inhibit ENaC presumably located on cardiac sensory afferents indeed blunted the mechanosensitive (i. e., sympathoinhibition by intravenous volume loading [-32% and -42% in treated groups vs. -67% in controls; n = 7 each; p < 0.05]) as well as-though to a lesser extent-the 5-HT(3)-mediated chemosensitive cardiorenal reflex in vivo in a dose-dependent manner. Using patch clamp technique, however, it turned out that neither amiloride nor benzamil influenced mechanically induced currents in ganglion nodosum cells in vitro, stimulated by hypoosmotic stress. The unspecific stretch activated ion channel blocker gadolinium completely abolished mechanically induced currents, indicating respective cells were mechanosensitive. In isolated vagus nerves benzamil impaired action potentials obtained by electrical stimulation (C-spike amplitude [-33%]; latency [+12%]; n = 8; p < 0.05). Our findings at least cast doubt on ENaC exclusively playing a specific role as mechanotransducers within the cardiac sensory network. Other ion channels might be involved. Furthermore the observed findings in vivo could also be due to unspecific disturbance of afferent signal conduction.

Effects of artemisinin on action potentials from C-type nodose ganglion neurons.

AIM: To investigate the effects of artemisinin (Art) on the action potentials (AP) recorded from identified C-type nodose neurons and study its anti-arrhythmic and anesthetic mechanisms. METHODS: Neonatal and adult rats were selected for the preparation of isolated nodose ganglia neurons (NGN) and nodose ganglion-vagus slice preparation. Somatic AP were recorded from both isolated and slice NGN using whole-cell patch technique. Conduction velocity (CV) was measured using slice preparation. The effects of Art on AP were evaluated with the reference to ketamine. RESULTS: Effects of Art on AP were that: (1) AP depolarizing profiles were inhibited without changing resting membrane potential (RMP). The peak of AP (AP(peak)) and upstroke velocity (UV(APD50) and UV(max)) decreased markedly (P<0.01). (2) The duration of AP at the point of half repolarization (APD(50)) was obviously prolonged (P<0.01). (3) Art also slowed down AP repolarization profiles (downstroke velocity, DV(APD50), and DV(max)) and the peak of after-hyperpolarization (AHP(peak)) was less negative. (4) Total inward and outward currents over the course of AP were significantly reduced in the presence of Art. (5) CV did not changed by Art. (6) The effects of Art on AP were concentration-dependent and resembled with those of ketamine except for CV. CONCLUSION: Art inhibited both depolarization and repolarization of AP, suggesting that the effects of Art were probably, due to the blockade of Na+ and K+ ion channels.

CART in the dorsal vagal complex: sources of immunoreactivity and effects on Fos expression and food intake.

CART-peptide (CARTp) has been shown to suppress food intake, particularly when injected into the 4th ventricle of rats, and the presence of CART in nodose ganglia suggested a role in satiation. Based on retrograde tracing from the DVC combined with CART immunohistochemistry and supranodose vagotomy, we found that CART immunoreactivity in varicose fibers of the dorsal vagal complex originates from vagal afferents, sparse projections from the medullary reticular formation and the arcuate/retrochiasmatic nucleus of the hypothalamus, and most likely also from local CART neurons in the area postrema and NTS. In the nodose ganglia, 17% of neurons with projections to the stomach and 41% to the duodenum express CART-IR. CART-IR vagal afferents significantly contribute to the rich fiber plexus in mainly the commissural NTS and the adjacent area postrema. Injections of CARTp into the 4th ventricle strongly suppressed sucrose drinking and stimulated expression of c-Fos in the NTS. Injections of CARTp directly into various subnuclei of the NTS were less effective in suppressing food intake. The findings suggest that the critical site for CART's suppression of food intake is not in the termination zone of CART-containing vagal afferents in the commissural NTS, and that CART release from vagal afferent terminals plays a minor role in satiation. The functional role of CART in vagal afferents and the site of food intake suppression by 4th ventricular CARTp remain to be determined.

The role of the gastric afferent vagal nerve in ghrelin-induced feeding and growth hormone secretion in rats.

BACKGROUND & AIMS: Visceral sensory information is transmitted to the brain through the afferent vagus nerve. Ghrelin, a peptide primarily produced in the stomach, stimulates both feeding and growth hormone (GH) secretion. How stomach-derived ghrelin exerts these central actions is still unknown. Here we determined the role of the gastric afferent vagal nerve in ghrelin's functions. METHODS: Food intake and GH secretion were examined after an administration of ghrelin intravenously (IV) to rats with vagotomy or perivagal application of capsaicin, a specific afferent neurotoxin. We investigated Fos expression in neuropeptide Y (NPY)-producing and growth hormone-releasing hormone (GHRH)-producing neurons by immunohistochemistry after administration IV of ghrelin to these rats. The presence of the ghrelin receptor in vagal afferent neurons was assessed by using reverse-transcription polymerase chain reaction and in situ hybridization histochemistry. A binding study on the vagus nerve by (125)I-ghrelin was performed to determine the transport of the ghrelin receptor from vagus afferent neurons to the periphery. We recorded the electric discharge of gastric vagal afferent induced by ghrelin and compared it with that by cholecystokinin (CCK), an anorectic gut peptide. RESULTS: Blockade of the gastric vagal afferent abolished ghrelin-induced feeding, GH secretion, and activation of NPY-producing and GHRH-producing neurons. Ghrelin receptors were synthesized in vagal afferent neurons and transported to the afferent terminals. Ghrelin suppressed firing of the vagal afferent, whereas CCK stimulated it. CONCLUSIONS: This study indicated that the gastric vagal afferent is the major pathway conveying ghrelin's signals for starvation and GH secretion to the brain.

Diinosine pentaphosphate: an antagonist which discriminates between recombinant P2X(3) and P2X(2/3) receptors and between two P2X receptors in rat sensory neurones.

1. We have compared the antagonist activity of trinitrophenyl-ATP (TNP-ATP) and diinosine pentaphosphate (Ip(5)I) on recombinant P2X receptors expressed in Xenopus oocytes with their actions at native P2X receptors in sensory neurones from dorsal root and nodose ganglia. 2. Slowly-desensitizing responses to alpha,beta-methylene ATP (alpha,beta-meATP) recorded from oocytes expressing P2X(2/3) receptors were inhibited by TNP-ATP at sub-micromolar concentrations. However, Ip(5)I at concentrations up to 30 microM was without effect. 3. Nodose ganglion neurones responded to alpha,beta-meATP with slowly-desensitizing inward currents. These were inhibited by TNP-ATP (IC(50), 20 nM), but not by Ip(5)I at concentrations up to 30 microM. 4. In DRG neurones that responded to ATP with a rapidly-desensitizing inward current, the response was inhibited by TNP-ATP with an IC(50) of 0.8 nM. These responses were also inhibited by Ip(5)I with an IC(50) of 0.1 microM. Both antagonists are known to inhibit homomeric P2X(3) receptors. 5. Some DRG neurones responded to alpha,beta-meATP with a biphasic inward current, consisting of transient and sustained components. While the transient current was abolished by 1 microM Ip(5)I, the sustained component remained unaffected. 6. In conclusion, Ip(5)I is a potent antagonist at homomeric P2X(3) receptors but not at heteromeric P2X(2/3) receptors, and therefore should be a useful tool for elucidating the subunit composition of native P2X receptors.

Pore dilation of neuronal P2X receptor channels.

P2X receptors are ligand-gated ion channels activated by the binding of extracellular adenosine 5'-triphosphate (ATP). Brief (< 1 s) applications of ATP to nodose ganglion neurons or to cells transfected with P2X2 or P2X4 receptor cDNAs induce the opening of a channel selectively permeable to small cations within milliseconds. We now show that, during longer ATP application (10-60 s), the channel also becomes permeable to much larger cations such as N-methyl-D-glucamine and the propidium analog YO-PRO-1. This effect is enhanced in P2X2 receptors carrying point mutations in the second transmembrane segment. Progressive dilation of the ion-conducting pathway during prolonged activation reveals a mechanism by which ionotropic receptors may alter neuronal function.

Neurturin, a relative of glial-cell-line-derived neurotrophic factor.

The normal development of the vertebrate nervous system entails the death of 30-70% of the neurons originally generated in most neuronal populations. This naturally occurring cell death is regulated by specific neurotrophic factors that promote neuronal survival and which are produced in limiting quantities by target cells, glial cells and neurons. These factors are also of potential utility as therapeutic agents for neurodegenerative diseases. Here we describe the purification and cloning of a new neurotrophic factor, identified on the basis of its ability to support the survival of sympathetic neurons in culture. This factor, neurturin, is structurally related to glial-cell-line-derived neurotrophic factor (GDNF). These factors can each activate the MAP kinase signalling pathway in cultured sympathetic neurons and support the survival of sympathetic neurons, as well as of sensory neurons of the nodose and dorsal root ganglia. Thus, neurturin and GDNF together now define a new family of neurotrophic factors.

A quantitative investigation of the effects of neonatal capsaicin treatment on vagal afferent neurons in the rat.

The sensory cells of the nodose and jugular ganglia of the rat have been quantitatively evaluated in longitudinal paraffin sections. The right vagal ganglia contain significantly more neurons than the left, particularly neurons with somata having sectioned areas 200-400 microm2 and longest diameters 15-25 microm. Such neurons appear to be homogenously distributed because sections of the right vagal ganglia did not show specific areas of neuronal density compared with those of the left. Neonatal capsaicin treatment reduced the number of neurons in both the left and right ganglia to about 30% of controls. Capsaicin destroyed neurons with sectioned areas of 100-600 microm2 and longest diameters of 15-35 microm, but had no statistically significant effects on larger neurons.