Information processing in brainstem bitter taste-relaying neurons defined by genetic tracing.

Bitter reception is mediated by taste receptor cells that coexpress multiple T2Rs, a family of G-protein-coupled receptors. However, it remains elusive how bitter taste information is translated in the brain into appropriate behavioral responses. Here we used a combination of genetic tracing and electrophysiological and immunohistochemical analyses in mice to functionally characterize the neurons in the solitary tract nuclei of the medulla, which receive input from mT2R5-expressing cells. The neurons defined by a transneuronal tracer originating from mT2R5-expressing cells receive glutamatergic synaptic input via the AMPA receptor. The satiety peptide cholecystokinin increases glutamatergic transmission, suggesting an interaction between information processing of taste and the homeostatic control of feeding. Nevertheless, the tracer-labeled neuron types are heterogeneous, and can be classified into catecholamine and pro-opiomelanocortin neurons. Our data reveal that the architectural solution in the first-order central relay that processes information from mT2R5-expressing cells uses unique ensembles of neurons with different neurotransmitters.

Irsogladine maleate counters the interleukin-1 beta-induced suppression in gap-junctional intercellular communication but does not affect the interleukin-1 beta-induced zonula occludens protein-1 levels in human gingival epithelial cells.

BACKGROUND AND OBJECTIVE: Irsogladine maleate counters gap junctional intercellular communication reduction induced by interleukin-8 or Actinobacillus actinomycetemcomitans in cultured human gingival epithelial cells. Interleukin-1 beta is involved in periodontal disease. Little is known, however, about the effect of interleukin-1 beta on intercellular junctional complexes in human gingival epithelial cells. Furthermore, irsogladine maleate may affect the actions of interleukin-1 beta. In this study, we examined how interleukin-1 beta affected gap junctional intercellular communication, connexin 43 and zonula occludens protein-1, and how irsogladine maleate modulated the interleukin-1 beta-induced changes in the intercellular junctional complexes in human gingival epithelial cells. MATERIAL AND METHODS: Human gingival epithelial cells were exposed to interleukin-1 beta, with or without irsogladine maleate. Connexin 43 and zonula occludens protein-1 were examined at mRNA and protein levels by real-time polymerase chain reaction and western blotting, respectively. Gap junctional intercellular communication was determined using the dye transfer method. The expression of zonula occludens protein-1 was also confirmed by immunofluorescence. RESULTS: Interleukin-1 beta decreased connexin 43 mRNA levels, but increased zonula occludens protein-1 mRNA levels. Irsogladine maleate countered the interleukin-1 beta-induced reduction in gap junctional intercellular communication and connexin 43 levels. However, irsogladine maleate did not influence the increased zonula occludens protein-1 levels. CONCLUSION: The effect of interleukin-1 beta on gap junctional intercellular communication and tight junctions of human gingival epithelial cells is different. The recovery of gap junctional intercellular communication by irsogladine maleate in the gingival epithelium may be a normal process in gingival epithelial homeostasis.

Role of mastication and swallowing in the control of autonomic nervous activity for heart rate in different postures.

Mastication and swallowing increase the heart rate, and posture change and respiration also modulate the heart rate. To clarify the role of mastication and swallowing in the modulation of the autonomic nervous activity, we investigated how they interact with modulation of the heart rate by changing body positions and respiration in young healthy subjects. R-R intervals of electrocardiogram at rest were significantly changed with different body positions, compared with supine and standing. A net shortening by mastication of a chewing gum base was similar in various postures. Respiration induced a periodic change in the R-R intervals, depending on the body postures, but mastication did not markedly change them in each posture. Dry swallowing at rest and spontaneous swallowing during the mastication in the sitting position induced a similar transient shortening and suppressed the respiration-induced changes after the swallowing. The net transient shortening by dry swallowing at rest was similar in the different postures. These results suggest that signals from mastication and swallowing are summated with those from body positions and respiration for shortening the R-R intervals and that signals from swallowing suppress the respiration-induced periodic changes.

Evaluation of mastication-induced change in sympatho-vagal balance through spectral analysis of heart rate variability.

Mastication modulates the autonomic nervous activity of the digestive glands and the heart. The autonomic nervous balance is evaluated with spectral analysis of heart rate variability. In the present study, we investigated the effects of mastication of chewing gum base on heart rate variability to clarify the role of mastication in the sympatho-vagal balance for the regulation of the heart rate. Mastication of a chewing gum base stimulated the salivary secretion and shortened the R-R intervals in the electrocardiogram of healthy young subjects without swallowing of saliva at a fixed rate of respiration. Based on the analysis of heart rate variability, mastication increased the low-frequency band spectral power (LF), and decreased the high-frequency band spectral power (HF). The LF/HF was markedly increased by the mastication. Mastication enhances the sympathetic nervous activity and/or suppresses the parasympathetic nervous activity for the heart. Feeding behaviour with mastication might play a role in the modulation of the autonomic nervous activity.

Forskolin-induced clearance of the fluorescent dye sulforhodamine from rat parotid intralobular duct lumen: visualization of the secretory function under a confocal laser scanning microscope.

Cyclic AMP evokes fluid secretion with bicarbonate in exocrine ducts. Clearance of fluorescent dyes from rat parotid intralobular ducts by forskolin was visualized as a fluorescence change in the duct luminal space by optical sectioning under a confocal laser scanning microscope to clarify the secretory function in the ducts. When the isolated rat parotid intralobular duct segments were superfused with membrane-impermeable fluorescent dyes during the experimental period, fluorescent dyes were passively moved into the duct space. Forskolin and isobutylmethylxanthine decreased the fluorescence of anionic dye, sulforhodamine B, and neutral dye, dextran tetramethyl-rhodamine, in the duct space, suggesting that the forskolin-induced clearance of fluorescent dyes might be the result of fluid secretion in the ducts. Methazolamide inhibited a forskolin-induced sustained decrease in duct fluorescence and intracellular acidification. Low concentrations of external Cl?, DIDS, bumetanide and amiloride did not markedly inhibit a forskolin-induced decrease in duct fluorescence. These findings suggest that a major portion of the steady decrease in duct fluorescence by forskolin was related to intracellular HCO3? production, not the uptake mechanism of external Cl?. Glibenclamide, NPPB, DPC and DMA inhibited the forskolin-induced decrease. Forskolin evokes the clearance of fluorescent dyes from duct space possibly due to fluid secretion in rat parotid ducts, associated with secretion through CFTR and DPC-sensitive anion channels of carbonic anhydrase-dependent bicarbonate linked with the Na+/H+ exchange mechanism.

Gramicidin-perforated patch analysis on HCO3- secretion through a forskolin-activated anion channel in rat parotid intralobular duct cells.

Forskolin-induced anion currents and depolarization were investigated to clarify the mechanism of HCO3- secretion in the intralobular duct cells of rat parotid glands. Anion currents of the cells were measured at the equilibrium potential of K+, using a gramicidin-perforated patch technique that negligibly affects intracellular anion concentration. The forskolin-induced anion current was sustained and significantly (54%) suppressed by glibenclamide (200 microM), a blocker of the cystic fibrosis transmembrane conductance regulator (CFTR) Cl- channel. The anion current was markedly suppressed by addition of 1 mM methazolamide, a carbonic anhydrase inhibitor, and removal of external HCO3-. Forskolin depolarized the cells in the current-clamp mode. Addition of methazolamide and removal of external HCO3- significantly decreased the depolarizing level. These results suggest that activation of anion channels (mainly the CFTR Cl- channel located in luminal membranes) and production of cytosolic HCO3- induce the inward anion current and resulting depolarization. Inhibition of the Na(+)-K(+)-2Cl- cotransporter and the Cl(-)-HCO3- exchanger had no significant effect on the current or depolarization, indicating that the uptake of Cl- via the Na(+)-K(+)-2Cl- cotransporter or the Cl(-)-HCO3- exchanger is not involved in the responses. Taken together, we conclude that forskolin activates the outward movement (probably secretion) of HCO3- produced intracellularly, but not of Cl- due to lack of active Cl- transport in parotid duct cells, and that the gramicidin-perforated patch method is very useful to analyze anion transport.

External Cl(-)-dependent formation of watery vacuoles by long-term hypotonic shock in 3T3-L1 cells.

Osmotic shock transiently induces a volume change in the cells, followed by a restoration of the cell volume due to intracellular water regulation. Effect of long-term osmotic shock on the water regulation is not completely understood. Vacuole formation by long-term osmotic shock was investigated to clarify the water exclusion mechanism from cytoplasm into intracellular vacuoles in 3T3-L1 cells. Incubation of cells in hypotonic solution reversibly induced the vacuole formation. Staining of vacuoles with fluorescent dyes revealed that vacuoles were derived from endoplasmic reticulum and Golgi apparatus but not lysosomes. Membrane-impermeable fluorescent dyes were taken up into some vacuoles from cytoplasm and extracellular solution, suggesting that some vacuoles exhibit the dynamic changes for the connection of plasma membrane, and that transporter for membrane-impermeable dyes might be active in some vacuole membranes. External Cl(-), but not Na(+), was required for vacuole formation. DPC suppressed the vacuole formation and increased cell height, and further incubation with DPC increased the number of dead cells. Bumetanide, dimethylamiloride, and HgCl(2) did not suppress the hypotonic stress-induced formation of water vacuoles. These findings suggest that 3T3-L1 cells regulate the intracellular water content through the DPC-sensitive external Cl(-)-dependent vacuole formation during long-term osmotic stress.

Visualization of the secretory process involved in Ca2+-activated fluid secretion from rat submandibular glands using the fluorescent dye, calcein.

The central feature of fluid and electrolyte secretion by salivary acinar cells is transepithelial Cl- movement as a driving force for the secretion. However, little is known about the membrane localization and regulation by agonists of various anion channels. To characterize the anion transport and fluid secretion, we visualized the secretory process induced by the cholinergic agonist, carbachol (CCh), using the anionic fluorescent dye, calcein, under a confocal laser scanning microscope. The fluorescence of calcein loaded into the isolated acini was spread diffusely throughout the cytoplasm and was less intense in the secretory vesicles which occupied the apical pole. Cytoplasmic calcein was released into intercellular canaliculi just after the addition of CCh, depending upon a rise in [Ca2+]i by Ca2+ release from intracellular stores. Thereafter, the formation of watery vacuoles connected with intercellular canaliculi was visualized in the calcein-loaded acini, depending upon external Ca2+. Both the calcein release and vacuole formation were inhibited by suppressing the Ca(2+)-activated K+ efflux. The calcein release was also affected by the external anion substitution, suggesting that calcein is released through an anion channel. In the isolated, perfused glands, CCh-induced fluid secretion was sustained in two phases, whereas the loaded calcein was initially and transiently released into the saliva. By revealing the [Ca2+]i dependence and sensitivities to channel blockers, our results suggest that the initial phase of CCh-induced fluid secretion was evoked in association with the release of the organic anion, calcein, and the late phase of fluid secretion, during which calcein is less permeable, was associated with the formation of watery vacuoles. Thus, the anion channels possessing the distinct property of anion permeation may be activated in the initial phase and late phase. These results indicate that the anionic fluorescent dye, calcein, is useful for visualizing the process of Ca(2+)-dependent fluid secretion, and for clarifying the relation between fluid secretion and anion transport.

cAMP-Dependent potentiation of the Ca(2+)-activated release of the anionic fluorescent dye, calcein, from rat parotid acinar cells.

A recent study indicates that elevation of [Ca(2+)](i) enhances the release of calcein, an anionic fluorescent dye, from isolated exocrine acinar cells, so cytoplasmic calcein is useful for monitoring the secretion of organic anions. In this study, we investigated the effect of cAMP on the calcein release evoked by elevation of [Ca(2+)](i). Isoproterenol, forskolin and dibutyryl cyclic AMP (dbcAMP) did not induce the release of calcein from isolated parotid acinar cells, but they potentiated the carbachol-induced release of calcein. Although cytoplasmic calcein is released through an increase in [Ca(2+)](i), isoproterenol potentiated the carbachol-induced release of calcein without affecting the increase in [Ca(2+)](i) evoked by a high concentration of carbachol (10(-6) M). Charybdotoxin, a K(+) channel blocker, inhibited both the carbachol-induced release and the potentiation by isoproterenol. However, the calcein permeation pathways mediating the carbachol-induced release and the isoproterenol-potentiated release exhibited distinct sensitivities to anion channel blockers. Our results indicate that the calcein release induced by carbachol is potentiated through an increase in intracellular levels of cAMP. Although both the Ca(2+)-activated release and the cAMP-potentiated release may be coupled to Ca(2+)-activated K(+) efflux, increases in both [Ca(2+)](i) and [cAMP](i) may activate the calcein conduction pathway which is not activated by an increase in [Ca(2+)](i) alone.

Modulation of carbachol-induced Cl(-) currents and fluid secretion by isoproterenol in rat submandibular acinar cells.

The effects of muscarinic and beta-adrenergic agonists on Cl(-) currents in acinar cells were investigated to clarify their role in the regulation of fluid secretion in rat perfused submandibular glands. Additions of isoproterenol (IPR) at 10(-8) to 10(-6) M and 8-(4-chlorophenylthio)-cyclic AMP (CPT-cAMP) at 10(-3) M to the perfusate suppressed carbachol (CCh; 10(-6) M)-induced fluid secretion. IPR and CPT-cAMP also diminished CCh-induced oscillatory Cl(-) current and increased CCh-stimulated non-oscillatory Cl(-) current. Propranolol blocked the effect of IPR on fluid secretion. IPR did not modulate the CCh-induced increase in intracellular concentration of calcium ions and intracellular pH in isolated cells. Propranolol blocked IPR-induced changes in Cl(- )currents, while propranolol itself increased CCh-induced K(+) current and reduced CCh-induced oscillatory Cl(-) current. Increasing external osmolarity with 50 mM sucrose abolished IPR-enhanced non-oscillatory Cl(-) current. Neither CCh-induced oscillatory Cl(-) current nor IPR-induced suppression of the oscillatory Cl(-) current was influenced by the hypertonicity. Perfusion of the gland with the hypertonic solution did not affect the IPR-induced suppression of fluid secretion. These results suggest that IPR induces the suppression of CCh-induced oscillatory Cl(-) current and potentiation of the non-oscillatory Cl(-) current via an increase in cyclic AMP level, and that suppression of the oscillatory Cl(-) current by IPR may contribute to the inhibition of fluid secretion from submandibular glands.

Effects of cytochalasin D on taste pores of rat fungiform papillae.

Effects of cytochalasin D on actin filaments in cells encircling taste pores were examined to clarify the functional role of actin filaments in the maintenance of taste pores in rat fungiform papillae, using a confocal laser microscope and a scanning electron microscope. Fluorescence in the taste pore cells was detected as a ring shape produced by actin staining with rhodamine-phalloidin. Treatment of fungiform papillae with cytochalasin D diminished the positive reactions in the taste pore cells and increased the inner diameter of the ring reactions. However, deformation of the taste pores in fungiform papillae was not detected under a scanning electron microscope after treatment with cytochalasin D. These findings suggest that the organization of actin filaments encircling the taste pores contributes to regulation of the taste pore's size in rat fungiform papillae.

Potentiation by isoproterenol on carbachol-induced K+ and Cl- currents and fluid secretion in rat parotid.

Isoproterenol (IPR) and 8-(4-chlorophenylthio)-cyclic AMP (cpt-cAMP) enhanced carbachol (CCh)-induced fluid secretion from rat parotid glands, but had no effect by themselves. The enhancement by IPR was blocked by propranolol. In dispersed parotid acinar cells, IPR and cpt-cAMP potentiated CCh-induced K+ and Cl- currents (IK and ICl). IPR at the concentration of 0.1 microM significantly potentiated the CCh-induced increase in intracellular Ca2+ concentration ([Ca2+]i), but 1 mm cpt-cAMP did not. The incidence of the potentiation by IPR in CCh-induced Mn2+ entry was 31% and that by cpt-cAMP was 21%. The potentiation by IPR in the ionic currents and the [Ca2+]i was suppressed by propranolol. These results suggest that the CCh-induced fluid secretion from rat parotid glands is enhanced by IPR through the potentiation of IK and ICl mainly by the increased cyclic AMP level and partially by the potentiated Ca2+ influx and [Ca2+]i increase, and that IPR is more effective than cpt-cAMP in the enhancement of the CCh-induced [Ca2+]i increase.

The ACh-induced whole-cell currents in sheep parotid secretory cells. Do BK channels really carry the ACh-evoked whole-cell K+ current?

As in other salivary glands, the secretory cells of the sheep parotid have a resting K+ conductance that is dominated by BK channels, which are activated by acetylcholine (ACh) and are blocked by tetraethylammonium (TEA). Nevertheless, perfusion studies indicate that TEA does not inhibit ACh-evoked fluid secretion or K+ efflux from intact sheep parotid glands. In the present study, we have used whole-cell patch clamp techniques to show that ACh activates K+ and Cl- conductances in sheep parotid secretory cells by increasing intracellular free Ca2+, and we have compared the blocker sensitivity of the ACh-evoked whole-cell K+ current to the previously reported blocker sensitivity of the BK channels seen in these cells. The ACh-induced whole-cell K+ current was not blocked by TEA (10 mmol/l) or verapamil (100 mumol/l), both of which block the resting K+ conductance and inhibit BK channels in these cells. Quinine (1 mmol/l) and quinidine (1 mmol/l), although only weak blockers of the resting K+ conductance, inhibited the ACh-evoked current at 0 mV (K+ current), by 68% and 78%, respectively. 4-Aminopyridine (10 mmol/l) partially inhibited the ACh-induced K+ current and caused it to fluctuate. It also caused the resting membrane currents to fluctuate, possibly by altering cytosolic free Ca2+. Ba2+ (100 mumol/l), a blocker of the inwardly rectifying K+ conductance in sheep parotid cells, had no effect on the ACh-induced K+ current. We conclude that the ACh-induced K+ conductance in sheep parotid cells is pharmacologically distinct from both the outwardly rectifying (BK) K+ conductance and the inwardly rectifying K+ conductance seen in unstimulated cells. Given that in vitro perfusion and K+ efflux studies on other salivary glands in which BK channels dominate the resting conductance (e.g., the rat mandibular, rat parotid and mouse mandibular glands) have revealed an insensitivity to TEA, suggesting that BK channels do not carry the ACh-evoked K+ current, we propose that BK channels do not contribute substantially to the K+ current evoked by ACh in the secretory cells of most salivary glands.

Different localizations of 21 and 27 kDa gap-junction proteins in rat salivary glands.

Antibodies against 21 and 27 kDa gap-junction proteins from rat liver were used to examine the identification and localization of gap-junction proteins in rat salivary glands. Acinar cells of the submandibular glands and parotid glands stained well for the 27 kDa gap junction protein and less intensely for the 21 kDa protein. Acinar cells of the sublingual glands were stained heavily for the 27 kDa gap junction protein and stained well for 21 kDa gap junction protein. No 27 kDa protein was observed in the ducts of the salivary glands. The 21 kDa gap-junction protein was distributed in some of the intercalated ducts in the parotid and submandibular glands. Immunoblotting of an extract of parotid glands with antibodies against 21 and 27 kDa gap-junction proteins revealed the presence of 21 and 27 kDa proteins in the parotid glands. It is concluded that the 27 kDa gap-junction protein is distributed as a major component of the gap junctions in the acinar cells of all the salivary glands; the 21 kDa protein is localized as a minor component in the acinar cells and some portions of the intercalated ducts in the salivary glands. It is possible that these gap-junction proteins might contribute to the regulation of function of the salivary glands.

Developmental regulation and maintenance of inwardly and outwardly rectifying K+ currents in sheep parotid cells.

Sheep parotid secretory cells contain an inwardly rectifying K+ conductance not seen in nonruminants. The channels underlying this conductance are highly active in unstimulated cells and, in consequence, have been implicated in spontaneous secretion (secretion in the absence of neural and hormonal stimulation), an unusual phenomenon seen conspicuously in ruminant parotid glands. Since spontaneous secretion by the sheep parotid first appears after weaning, at the same time that the parasympathetic secretomotor innervation becomes functional, and since parasympathetic denervation of the adult parotid causes spontaneous secretion to abate over a period of weeks, it might be expected that the activity of the inwardly rectifying K+ conductance would be similarly related to parasympathetic innervation if it plays an important role in spontaneous secretion. To test this hypothesis, we used whole cell patch-clamp techniques to study the inwardly rectifying K+ conductance in secretory cells from the parotid glands of unweaned lambs and normal adult sheep studied 6 wk after unilateral parotid parasympathectomy. The secretory cells from unweaned lambs showed almost no inwardly rectifying current, and the cells from parasympathectomized glands in adults showed a reduced current compared with the contralateral control glands. Our results thus provide evidence that the inwardly rectifying current is somehow enabled by the development of a functional parasympathetic innervation.

Close relationship between modulation of serum-induced stimulation of DNA synthesis and changes in gap-junctional intercellular communication in quiescent 3T3-L1 cells caused by cyclic AMP and the tumor-promoting phorbol ester TPA.

Involvement of gap-junctional intercellular communication in the stimulation of growth was investigated in quiescent 3T3-L1 cells. When the cells in monolayer were growth-arrested by culture in a low concentration of calf serum, addition of dibutyryl cyclic AMP enhanced dye-coupling and suppressed the enhancement of DNA synthesis, induced by calf serum, in quiescent cells. 12-O-Tetradecanoylphorbol-13-acetate (TPA) suppressed dye-coupling in quiescent cells and enhanced DNA synthesis in both quiescent and serum-treated cells. When about 5000 cells were cultured in contact to form a colony, growth arrest of the cells was observed in the central region of such colonies rather than in the peripheral region, but addition of calf serum induced DNA synthesis in the cells in both the peripheral and central regions of the colonies. Addition of TPA enhanced serum-induced DNA synthesis in the cells in the central region of colonies rather than in the peripheral region. These results suggest that the ability of quiescent cells to escape from growth arrest is inversely correlated to the extent of gap-junctional intercellular communication.

Herbimycin A suppresses the reduction of gap-junctional intercellular communication induced by tumor-promoting phorbol ester in 3T3-L1 cells.

We have examined the suppressive effect of herbimycin A on the reduction of gap-junctional intercellular communication that is induced by a tumor-promoting phorbol ester in 3T3-L1 cells. Most cells in growth arrest participated in dye-coupling, as evaluated by the transfer between cells of a fluorescent dye (Lucifer Yellow CH). Treatment of cells with 0.25 microgram/ml herbimycin A slightly enhanced the dye-coupling. This enhancement required treatment for periods as long as 24 h. Addition of 100 ng/ml 12-O-tetradecanoylphorbol-13-acetate (TPA) caused a rapid reduction of dye-coupling. However, addition of TPA did not suppress dye-coupling in cells pretreated for more than 24 h with herbimycin A. Pretreatment of cells for less than 6 h with herbimycin A did not suppress the TPA-induced reduction of dye-coupling. These results suggest that herbimycin A suppresses the reduction of gap-junctional intercellular communication that is induced by TPA through enhancement of the ability of the cells to participate in gap-junctional intercellular communication.

Characterization of glutamate receptors induced in Xenopus oocytes after injection of rat brain mRNA.

Xenopus oocytes in which poly(A)+ mRNA isolated from rat brains were previously injected, exhibited at least 3 categories of current responses to excitatory amino acids. They were oscillatory responses to glutamate (Glu) or quisqualate (QA), smooth large responses to kainate (KA), and smooth small responses to Glu and QA. Oscillatory responses were mediated by a metabotropic type of Glu receptor which is coupled to a G-protein but not directly to an ionic channel. Amplitudes of smooth Glu responses and smooth QA responses were similar in size, and were not additive to each other, suggesting a common receptor mediating both responses. L-Glutamylglycine inhibited KA responses in a competitive manner without affecting smooth Glu/QA responses, indicating that KA and smooth Glu/QA responses were mediated by separate receptors. From these results, it was concluded that the injection of rat brain mRNA induced at least 3 different glutamatergic receptors: receptors mediating (a) KA responses and (b) smooth Glu/QA responses, and (c) the metabotropic Glu receptor. The former two may most likely correspond to Glu receptor subtypes preferring KA and QA, respectively, as seen in the brain.

Roles of protein kinases in neurotransmitter responses in Xenopus oocytes injected with rat brain mRNA.

Microinjection of rat brain mRNA in Xenopus oocytes induced acetylcholine, neurotensin, serotonin, and glutamate receptors in the cells. These receptors stimulate an intracellular reaction pathway, including G-protein activation, inositol trisphosphate (IP3) formation, and Ca2+-dependent Cl- channels. In the present study, we examined the roles of several protein kinases in these responses by means of inhibitors and activators of these kinases. Isoquinolinesulfonamides, inhibitors of protein kinases, caused no current responses and affected no receptor-mediated responses when injected into the oocytes at low doses (30-50 pmol), which inhibit cyclic nucleotide-dependent kinases or kinase C specifically, but abolished the receptor-mediated responses at a higher dose (300 pmol), which inhibit most protein kinases nonspecifically. Calmodulin inhibitors blocked the receptor-mediated responses strongly. Activation of cyclic nucleotide-dependent kinases or kinase C by injection of cAMP (or cGMP) or perfusion with phorbol esters caused no direct current responses but suppressed receptor-mediated responses. Current responses triggered by IP3 injection were not suppressed by these treatments. These results suggest that cAMP- (or cGMP-)dependent kinases or kinase C may not be involved in the pathway directly but may modulate it by inhibiting the initial part of the pathway (receptors, G-proteins, and/or phospholipase C), and they suggest that calmodulin may most likely be involved in the activation of Ca2+-dependent Cl- channels.