Circadian integration of sleep-wake and feeding requires NPY receptor-expressing neurons in the mediobasal hypothalamus.

Sleep and feeding rhythms are highly coordinated across the circadian cycle, but the brain sites responsible for this coordination are unknown. We examined the role of neuropeptide Y (NPY) receptor-expressing neurons in the mediobasal hypothalamus (MBH) in this process by injecting the targeted toxin, NPY-saporin (NPY-SAP), into the arcuate nucleus (Arc). NPY-SAP-lesioned rats were initially hyperphagic, became obese, exhibited sustained disruption of circadian feeding patterns, and had abnormal circadian distribution of sleep-wake patterns. Total amounts of rapid eye movement sleep (REMS) and non-REMS (NREMS) were not altered by NPY-SAP lesions, but a peak amount of REMS was permanently displaced to the dark period, and circadian variation in NREMS was eliminated. The phase reversal of REMS to the dark period by the lesion suggests that REMS timing is independently linked to the function of MBH NPY receptor-expressing neurons and is not dependent on NREMS pattern, which was altered but not phase reversed by the lesion. Sleep-wake patterns were altered in controls by restricting feeding to the light period, but were not altered in NPY-SAP rats by restricting feeding to either the light or dark period, indicating that disturbed sleep-wake patterns in lesioned rats were not secondary to changes in food intake. Sleep abnormalities persisted even after hyperphagia abated during the static phase of the lesion. Results suggest that the MBH is required for the essential task of integrating sleep-wake and feeding rhythms, a function that allows animals to accommodate changeable patterns of food availability. NPY receptor-expressing neurons are key components of this integrative function.

Leptin analog antagonizes leptin effects on food intake and body weight but mimics leptin-induced vagal afferent activation.

A recombinantly produced murine leptin analog (MLA) antagonizes leptin-induced signaling in cell lines that express the long form of the leptin receptor. However, the effects of MLA on the activity of leptin-sensitive neurons and on central neural controls of food intake have not been reported. Here we report effects of MLA on food intake and body weight in adult rats and on the activity of cultured rat vagal afferent neurons. Daily intracerebroventricular coinjection of MLA with exogenous leptin significantly attenuated leptin-induced reduction of 48-h food intake and body weight. Coinjection of MLA with leptin also reduced leptin-induced phosphorylation of signal transducer and activator of transcription 3 (STAT3) in the hypothalamus. In addition, chronic intracerebroventricular MLA infusion over 14 d via osmotic minipumps significantly increased daily food intake, rate of body weight gain, fat-pad mass, and circulating plasma leptin concentrations. Surprisingly, however, MLA did not antagonize leptin-evoked increases in cytosolic calcium concentrations in vagal afferent neurons in primary culture. Rather, MLA itself produced acute activation selectively in leptin-responsive vagal afferent neurons. These data suggest that MLA is an antagonist for the central effects of leptin on food intake and body weight but an agonist at sites where leptin induces acute neuronal activation. This mixed antagonist/agonist action suggests either 1) that the coupling of a single leptin receptor (ObRb) to acute activation of neurons occurs by a signaling mechanism different from those that mediate centrally evoked reductions in food intake and body weight or 2) that acute neuronal activation and centrally induced reductions of food intake and body weight are mediated by different leptin receptor subtypes.

AT4 receptor activation increases intracellular calcium influx and induces a non-N-methyl-D-aspartate dependent form of long-term potentiation.

The angiotensin 4 receptor (AT4) subtype is heavily distributed in the dentate gyrus and CA1-CA3 subfields of the hippocampus. Neuronal pathways connecting these subfields are believed to be activated during learning and memory processing. ur laboratory previously demonstrated that application of the AT4 agonist, Norleucine1-angiotensin IV, enhanced baseline synaptic transmission and long-term potentiation, whereas perfusion with the AT4 antagonist, Norleucine1-Leu3-psi(CH2-NH2)3-4-angiotensin IV disrupted long-term potentiation stabilization in area CA1. The objective of the present study was to identify the mechanism(s) responsible for Norleucine1-angiotensin IV-induced increase in hippocampal long-term potentiation. Hippocampal slices perfused with Norleucine1-angiotensin IV for 20 min revealed a notable increase in baseline responses in a non-reversible manner and were blocked by the alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate receptor antagonist, 6-cyano-7-nitroquinoxaline-2,3-dione disodium salt. Infusions of Norleucine1-angiotensin IV prior to, but not after theta burst stimulation, significantly enhanced long-term potentiation compared with control slices. Further, N-methyl-D-aspartate receptor-independent long-term potentiation could be induced by tetanization during the perfusion of Norleucine1-angiotensin IV in the presence of the N-methyl-D-aspartate antagonist, D,L-2-amino-5-phosphonovaleric acid. Blockade of select voltage dependent calcium channels significantly reduced Norleucine1-angiotensin IV-induced increase in baseline responses and subsequent long-term potentiation suggesting that AT4 receptor activation increases intracellular calcium levels via altering voltage dependent calcium channels and triggers an N-methyl-D-aspartate-independent form of long-term potentiation. In support of this notion the application of Nle1-angiotensin IV to cultured rat hippocampal neurons resulted in increased intracellular calcium derived exclusively from extracellular sources. Consistent with these observations Nle1-angiotensin IV was capable of augmenting the uptake of 45Ca2+ into rat hippocampal slices. Taken together, these data indicate that increased calcium influx through postsynaptic calcium channels contribute to Norleucine1-angiotensin IV-induced enhancement of long-term potentiation.

Reevaluation of the electrophysiological actions of thyrotropin-releasing hormone in a rat pituitary cell line (GH3).

The electrophysiological actions of TRH were examined in the clonal pituitary cell line GH3 with the use of the perforated patch variation of the standard whole cell patch-clamp technique. The action of TRH on spontaneously spiking cells was to cause a brief hyperpolarization (first phase action), followed by a period during which action potential behavior was significantly modified (second phase action). The modifications during second phase action included a reduction in the slope of the up-stroke, a reduced peak potential, an increase in duration, and a depolarizing shift of the after-hyperpolarization. The modification of voltage- and calcium-dependent conductances that underlie these changes were investigated in voltage clamp experiments. During first phase action TRH was found to increase calcium-dependent potassium current. During second phase action TRH was found to significantly reduce the L-type calcium current (35%), with no alteration in the T-type calcium current. The second phase action of TRH on calcium-dependent potassium conductance was complex. First, a decrease was observed. This was followed by an increase that did not become fully manifest until after TRH was washed from the cell. TRH caused no change in voltage-dependent potassium current. These results indicate that the second phase action of TRH on action potential behavior in GH3 cells is mediated by a reduction in L-type calcium current and alterations in the behavior of calcium-dependent potassium currents, but not through changes in voltage-dependent potassium currents.

Cooperative activation of cultured vagal afferent neurons by leptin and cholecystokinin.

To test the hypothesis that leptin can directly activate vagal afferent neurons, we used fluorescence imaging to detect acute changes in cytosolic calcium after leptin application to primary cultures of vagal afferent neurons dissociated from adult rat nodose ganglia. We found that approximately 40% of vagal afferent neurons exposed to leptin (40 ng/ml) responded with rapid and reversible increases in cytosolic calcium. These responses were dependent upon extracellular calcium. As previously reported, about 35% of vagal afferents increase cytosolic calcium in response to the gut-peptide cholecystokinin (CCK). A majority (74%) of neurons that responded to CCK also exhibited increases in cytosolic calcium in response to leptin. In addition, synergistic increases in cytosolic calcium were observed when leptin and CCK were applied in combination. These results demonstrate that leptin acts directly on vagal afferent neurons to trigger acute influxes of extracellular calcium. Our results also suggest cooperation between leptin and CCK in the activation of some vagal afferent neurons. Acute activation of vagal afferents by leptin alone and in combination with CCK may contribute to modulation of visceral reflexes and control of food intake.

Treatment of rats with the TRH analog MK-771. Down-regulation of TRH receptors and behavioral tolerance.

The regulation of receptors for thyrotropin-releasing hormone (TRH) in the central nervous system (CNS) was studied by administering the TRH analog, MK-771 to rats by three different schedules and then measuring changes in the binding of [3H](3MeHis2) TRH and behavioral responses to a challenge with MK-771. The behavioral responses monitored were wet-dog shakes, large motor movements, small motor movements and forepaw tremor. Temperature changes were also monitored. The first schedule consisted of intracerebroventricular (i.c.v.) administration of MK-771 for seven days (5 micrograms/microliter per hr) via a mini-osmotic pump. At the end of the treatment, rats showed no shaking or large motor movements typically induced by TRH, in response to a 5 mg/kg (i.p.) challenge of MK-771. Receptors were found to be 50% of control levels in the three areas of brain examined. The second schedule consisted of the administration of MK-771 (5 micrograms/2 microliters, i.c.v., once a day and 2 mg/kg, i.p., once a day). It was found that the number of receptors decreased on about the same time course as development of tolerance to wet-dog shakes and large motor movements. The third schedule consisted of the administration of MK-771 (5 micrograms/2 microliters, i.c.v.) once every 2 hr to a total of four doses. These animals eventually developed tolerance to the wet-dog shakes produced by the subsequent challenge with MK-771 and also showed a 50% decrease in receptor binding after the fourth exposure.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of calcium on membrane potential behavior in a rat pituitary cell line (GH3).

The effects of intracellular calcium buffering and increasing bath Ca2+ on spontaneous membrane depolarizations expressed by the clonal rat pituitary cell line GH3 were examined by use of the whole-cell patch-clamp technique. Increasing intracellular calcium buffering capacity caused the duration of spontaneous depolarizations to increase without altering other parameters of membrane potential activity. Increasing bath Ca2+ caused a decrease in duration. These results suggest that the duration of spontaneous membrane depolarization in GH3 cells is regulated by the accumulation of free intracellular Ca2+. The behavior of spontaneous depolarizations measured with the perforated-patch variation of whole-cell patch-clamp techniques closely resembled that obtained in standard whole-cell patch-clamp measurements with an intracellular calcium buffer of 200 microM EGTA with free Ca2+ adjusted to 100 nM.

Intracellular free calcium in response to oxytocin in pig endometrial cells.

Intracellular free calcium concentration ([Ca2+]i) in response to oxytocin (OT) was studied in stromal, glandular epithelial and luminal epithelial cells obtained from the endometrium of gilts 16 days post-estrus. The amplitude of increased [Ca2+]i in response to 100 nM OT was greatest in stromal cells, intermediate in glandular epithelial cells and not evident in luminal epithelial cells. During continuous OT administration, stromal cells responded initially with a synchronous spike of [Ca2+]i that did not require extracellular Ca2+ and then displayed spontaneous asynchronous [Ca2+]i spikes that required extracellular Ca2+. Each cell possessed its own characteristic response. Increasing concentrations of OT induced an increasing percentage of stromal cells responding, with some cells having nearly equal [Ca2+]i responses at all concentrations and others having graded [Ca2+]i responses as the concentration of OT increased. These results are consistent with the proposed mechanism of OT action in pig endometrium involving activation of phosphoinositide-Ca2+ signaling pathway.

Localization of thyrotropin-releasing hormone (TRH) receptors in the septal nucleus of the rat brain.

[3H](3MeHis2)TRH binding was examined in the septal nucleus of rats given brain lesions which destroyed specific neuronal elements within the septum. Kainic acid injected directly into the septum caused a 35% decrease in receptor binding. All other lesions did not significantly alter receptor binding. These data suggest that the septal TRH receptors are located on kainic acid-sensitive cell bodies.

Effect of septohippocampal lesions on thyrotropin-releasing hormone antagonism of pentobarbital narcosis.

Thyrotropin-releasing hormone (TRH) has been shown to antagonize pentobarbital narcosis in a variety of mammalian phylogeny, and many lines of evidence indicate that TRH action in the septum to modulate the septohippocampal system may be the neuroanatomical substrate mediating this effect. To further examine this hypothesis, the analeptic response following injection of TRH into the lateral ventricles or ventromedial septum was measured after lesions of the septum, fimbria or hippocampus. Lesions were induced using either radiofrequency current, aspiration or microinjection of kainic acid. Bilateral electrolytic lesions of the fimbria were found to block the antagonism of pentobarbital narcosis by intraseptal injection of 500 ng TRH, indicating that intraseptal TRH is acting via the septohippocampal system. In contrast, complete aspiration of the dorsal hippocampi did not attenuate intracerebroventricular (i.c.v.) administration of TRH. However, large electrolytic septal lesions effectively blocked i.c.v. TRH. These findings indicate first that i.c.v. TRH can cause arousal from pentobarbital narcosis via interaction with alternative neuroanatomical substrates from the septohippocampal system, and secondly, that these alternative substrates have axons which either synapse in or pass through the septum. The fact that injection of kainic acid into the ventromedial septum did not antagonize i.c.v. TRH supports the likelihood that the effectiveness of electrolytic septal lesions results from disruption of fibers in passage and not destruction of neuron perikarya in the septum.

Effect of ethanol on calcium regulation in rat fetal hypothalamic cells in culture.

The effects of acute exposure to ethanol on calcium regulation in primary cultures of rat fetal hypothalamic cells was studied with the use of the calcium indicator fura-2 and digital imaging techniques. We found that ethanol caused cytoplasmic calcium to increase in a dose-dependent and reversible manner, and these increases could be observed at pharmacologically relevant doses (34 mM). At 170 mM ethanol 65% of 1059 cells examined responded to ethanol with an increase in cytoplasmic calcium. Removing bath calcium eliminated the ethanol-induced calcium response in most cells (76% of 427 cells). In most cells exposure to thapsigargin (20 nM) had no significant effect on the ethanol-induced calcium increase (87% of 67 cells examined). The ethanol-induced calcium increase was reduced by 79+/-5% (n=110 cells) by the P/Q-type calcium channel blocker omega-agatoxin-TK (20 nM), by 51+/-10% (n=115 cells) by the N-type calcium channel blocker omega-conotoxin-GVIA (100 nM), and by 26+/-3% (n=90 cells) by the T-type calcium channel blocker flunarizine (1 microM). The L-type calcium channel blocker nifedipine (1 microM) had complex actions, sometimes inhibiting and sometimes increasing the calcium response. These results demonstrate that ethanol can directly modulate cytoplasmic calcium levels in hypothalamic cells mostly by a pathway that involves extracellular calcium and voltage-dependent calcium channels, and that this response may participate in the biological effects of acute ethanol exposure.

Effect of neurotensin, substance P and TRH on the regulation of dopamine receptors in rat brain.

Rats were exposed for one week to either neurotensin (4 micrograms/h), substance P (3.3 micrograms/h), thyrotropin-releasing hormone (5 micrograms/h), or saline administered intracerebroventricularly via mini osmotic-pumps and either haloperidol (2.5 mg/kg i.p., 2 X daily) or vehicle control. The peptide treatments by themselves did not alter [3H]spiroperidol binding in either the nucleus accumbens or the striatum. Neurotensin, however, augmented the increase in [3H]spiroperidol binding caused by the haloperidol treatment in both the nucleus accumbens and striatum.

Characterization and distribution of 3H-(3MeHis2)thyrotropin releasing hormone receptors in rat brain.

The characteristics and distribution of putative thyrotropin releasing hormone (TRH) receptors were studied in rat central nervous system using the TRH analogue 3H-(3MeHis2)TRH as a radiolabeled ligand. The analogue had a dissociation constant of 2.3 +/- 0.2 nM and a receptor density of 34 +/- 2 fm/mg protein in whole brain, homogenates. An association rate constant ot 1.6 x 10(-3) min-1nM-1 and a biphasic dissociation with rate constants of 2.6 x 10(-3) min-1 and 1.3 x 10(-4) min-1 were observed. The brain was dissected into ten regions, and detectable levels of binding were found in all regions. The highest levels were found in amygdala/piriform cortex area and the septal region, and the lowest levels were found in the cerebellar and cerebral cortex. Competition curves showed the methylated analogue to have approximately 7-fold higher affinity for the receptor than TRH. The higher affinity, along with lower nonspecific binding, accounts for the much improved sensitivity of the binding assay of the methylated analogue (70-80% specific binding) as compared to 3H-TRH (15-20% specific binding) and enables one to work with much lower tissue amounts. Use of the tritiated analogue will greatly aid in further studies of TRH receptors.

Capsaicin-sensitive vagal afferent neurons contribute to the detection of pathogenic bacterial colonization in the gut.

Vagal activation can reduce inflammation and disease activity in various animal models of intestinal inflammation via the cholinergic anti-inflammatory pathway. In the current model of this pathway, activation of descending vagal efferents is dependent on a signal initiated by stimulation of vagal afferents. However, little is known about how vagal afferents are activated, especially in the context of subclinical or clinical pathogenic bacterial infection. To address this question, we first determined if selective lesions of capsaicin-sensitive vagal afferents altered c-Fos expression in the nucleus of the solitary tract (nTS) after mice were inoculated with either Campylobacter jejuni or Salmonella typhimurium. Our results demonstrate that the activation of nTS neurons by intraluminal pathogenic bacteria is dependent on intact, capsaicin sensitive vagal afferents. We next determined if inflammatory mediators could cause the observed increase in c-Fos expression in the nTS by a direct action on vagal afferents. This was tested by the use of single-cell calcium measurements in cultured vagal afferent neurons. We found that tumor necrosis factor alpha (TNFα) and lipopolysaccharide (LPS) directly activate cultured vagal afferent neurons and that almost all TNFα and LPS responsive neurons were sensitive to capsaicin. We conclude that activation of the afferent arm of the parasympathetic neuroimmune reflex by pathogenic bacteria in the gut is dependent on capsaicin sensitive vagal afferent neurons and that the release of inflammatory mediators into intestinal tissue can be directly sensed by these neurons.

Leptin and CCK selectively activate vagal afferent neurons innervating the stomach and duodenum.

The hormone leptin and the gut peptide CCK synergistically interact to enhance the process of satiation. Although this interaction may occur at several levels of the neuroaxis, our previous results indicate that leptin can specifically enhance the satiation effect of CCK by acting on subdiaphragmatic vagal afferent neurons. Because of this localized action, we hypothesized that a high proportion of vagal afferent neurons innervating the stomach or duodenum would be responsive to leptin and/or CCK. To test this hypothesis, we measured changes in cytosolic calcium levels induced by leptin and CCK in cultured nodose ganglion neurons labeled with a retrograde neuronal tracer injected into either the stomach or the duodenum. In the neurons labeled from the stomach, CCK activated 74% (39 of 53) compared with only 35% (34 of 97) of nonlabeled cells. Of the CCK-responsive neurons 60% (18 of 30) were capsaicin-sensitive. Leptin activated 42% (22 of 53) of the stomach innervating neurons compared with 26% of nonlabeled neurons. All of the leptin-sensitive neurons labeled from the stomach also responded to CCK. In the neurons labeled from the duodenum, CCK activated 71% (20 of 28). Of these CCK-responsive neurons 80% (12 of 15) were capsaicin sensitive. Leptin activated 46% (13 of 28) of these duodenal innervating neurons, of which 89% (8 of 9) were capsaicin-sensitive. Among neurons labeled from the duodenum 43% (12 of 28) were responsive to both leptin and CCK, compared with only 15% (15 of 97) of unlabeled neurons. Our results support the hypothesis that vagal afferent sensitivity to CCK and leptin is concentrated in neurons that innervate the stomach and duodenum. These specific visceral afferent populations are likely to comprise a substrate through which acute leptin/CCK interactions enhance satiation.

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.

Leptin-induced satiation mediated by abdominal vagal afferents.

Leptin is a hormone secreted into the systemic blood primarily by white adipose tissue. However, leptin also is synthesized and stored by cells in the gastric mucosa. Because gastric mucosal leptin is secreted in response to ingestion of a meal, we hypothesized that it might contribute to satiation (meal termination) by acting on gastrointestinal vagal afferent neurons. To test whether leptin is capable of acutely reducing short-term food intake, we measured consumption of a liquid meal (15% sucrose) following low-dose leptin administration via the celiac artery, which perfuses the upper gastrointestinal tract. Leptin (1, 3, 10 mug) was infused via a chronically implanted, nonocclusive celiac arterial catheter or via a jugular vein catheter with its tip in the right cardiac atrium. Fifteen percent sucrose intake was then measured for 30 min. We found that leptin dose dependently inhibited sucrose intake when infused through the celiac catheter but not when infused into the general circulation via a jugular catheter. Plasma leptin concentrations in the general circulation following celiac arterial or jugular leptin infusions were not significantly different. Celiac arterial leptin infusion did not reduce meal size in vagotomized or capsaicin-treated rats. Finally, we also found that reduction of meal size by celiac leptin infusion was markedly enhanced when coinfused with cholecystokinin, a gastrointestinal satiety peptide whose action depends on vagal afferent neurons. Our results support the hypothesis that leptin contributes to satiation by a mechanism dependent on gastrointestinal vagal afferent innervation of the upper gastrointestinal tract.

Evidence for a delayed rectifier-like potassium current in the clonal rat pituitary cell line GH3.

Whole cell patch-clamp techniques were used to investigate voltage-dependent potassium currents in the clonal rat pituitary cell line GH3. Inactivation of the voltage-dependent potassium current was best fit by two time constants (50-80 ms and 2-3 s) plus a sustained value. These components of inactivation could be separated based on their voltage-dependent properties and pharmacological sensitivity to 10 mM tetraethylammonium (TEA) and 5 mM 4-aminopyridine (4-AP). The fast component begins to activate around -50 mV, is half-maximally activated at -19 mV, is 50% inactivated at -55 mV, and is sensitive to 4-AP but insensitive to TEA. The slow component begins to activate at around -10 mV, is half-maximally activated at +4 mV, is 50% inactivated at -23 mV, and is sensitive to both TEA and 4-AP. The sustained component is apparent by 0 mV but has not yet reached half-maximal activation at +57 mV. It is somewhat sensitive to TEA but relatively resistant to 4-AP. In the presence of TEA it was found that the fast-inactivating component actually inactivated in a biphasic manner with time constants of approximately 50 and 500 ms. From the properties of these components it is concluded that at least three distinct voltage-dependent potassium channel types exist in GH3 cells as follows: an A-like current (fast-inactivating component), a delayed rectifier-like current (slow-inactivating component), and the voltage-dependent properties of calcium-dependent potassium channels (the sustained component).

A background sodium conductance is necessary for spontaneous depolarizations in rat pituitary cell line GH3.

The role of Na+ in the expression of membrane potential activity in the clonal rat pituitary cell line GH3 was investigated using the perforated patch variation of patch-clamp electrophysiological techniques. It was found that replacing bath Na+ with choline, tris(hydroxymethyl)aminomethane (Tris), or N-methyl-D-glucamine (NMG) caused the cells to hyperpolarize 20-30 mV. Tetrodotoxin had no effect. The effects of the Na+ substitutes could not be explained by effects on potassium or calcium currents. Although all three Na+ substitutes suppressed voltage-dependent calcium current by 10-20%, block of voltage-dependent calcium current by nifedipine or Co2+ did not result in hyperpolarization of the cells. There was no effect of the Na+ substitutes on voltage-dependent potassium currents. In contrast, all three Na+ substitutes influenced calcium-activated potassium currents [IK(Ca)], but only at depolarized potentials. Choline consistently suppressed IK(Ca), whereas Tris and NMG either had no effect or slightly increased IK(Ca). These effects on IK(Ca) also cannot explain the hyperpolarization induced by removing bath Na+. Choline always hyperpolarized cells yet suppressed IK(Ca). Furthermore, removing bath Na+ caused an increase in cell input resistance, an observation consistent with the loss of a membrane conductance as the basis of the hyperpolarization. Direct measurement of background currents revealed a 12-pA inward current at -84 mV that was lost upon removing bath Na+. These results suggest that this background sodium conductance provides the depolarizing drive for GH3 cells to reach the threshold for firing calcium-dependent action potentials.