Inhibition by thiocyanate of muscarinic-induced cytosolic acidification and Ca2+ entry in rat sublingual acini

Calcium-activated chloride channels

Calcium-activated chloride channels (CaCCs) play important roles in cellular physiology, including epithelial secretion of electrolytes and water, sensory transduction, regulation of neuronal and cardiac excitability, and regulation of vascular tone. This review discusses the physiological roles of these channels, their mechanisms of regulation and activation, and the mechanisms of anion selectivity and conduction. Despite the fact that CaCCs are so broadly expressed in cells and play such important functions, understanding these channels has been limited by the absence of specific blockers and the fact that the molecular identities of CaCCs remains in question. Recent status of the pharmacology and molecular identification of CaCCs is evaluated.

Chloride channels and salivary gland function

Fluid and electrolyte transport is driven by transepithelial Cl- movement. The opening of Cl- channels in the apical membrane of salivary gland acinar cells initiates the fluid secretion process, whereas the activation of Cl- channels in both the apical and the basolateral membranes of ductal cells is thought to be necessary for NaCl re-absorption. Saliva formation can be evoked by sympathetic and parasympathetic stimulation. The composition and flow rate vary greatly, depending on the type of stimulation. As many as five classes of Cl- channels with distinct gating mechanisms have been identified in salivary cells. One of these Cl- channels is activated by intracellular Ca2+, while another is gated by cAMP. An increase in the intracellular free Ca2+ concentration is the dominant mechanism triggering fluid secretion from acinar cells, while cAMP may be required for efficient NaCl re-absorption in many ductal cells. In addition to cAMP- and Ca(2+)-gated Cl- channels, agonist-induced changes in membrane potential and cell volume activate different Cl- channels that likely play a role in modulating fluid and electrolyte movement. In this review, the properties of the different types of Cl- currents expressed in salivary gland cells are described, and functions are proposed based on the unique properties of these channels.

Muscarinic receptor-induced acidification in sublingual mucous acinar cells: loss of pH recovery in Na+-H+ exchanger-1 deficient mice

1. Intracellular pH (pHi) plays an important role in regulating fluid and electrolyte secretion by salivary gland acinar cells. The pH-sensitive, fluorescent dye 2', 7'-bis(carboxyethyl)-5(6)-carboxylfluorescein (BCECF) was used to characterize the mechanisms involved in regulating pHi during muscarinic stimulation in mouse sublingual mucous acinar cells. 2. In the presence of HCO3-, muscarinic stimulation caused a rapid decrease in pHi (0.24 +/- 0.02 pH units) followed by a slow recovery rate (0.042 +/- 0.002 pH units min-1) to the initial resting pHi in sublingual acinar cells. The muscarinic receptor-induced acidification in parotid acinar cells was of a similar magnitude (0. 25 +/- 0.02 pH units), but in contrast, the recovery rate was approximately 4-fold faster (0.181 +/- 0.005 pH units min-1). 3. The agonist-induced intracellular acidification was inhibited by the anion channel blocker niflumate, and was prevented in the absence of HCO3- by treatment with the carbonic anhydrase inhibitor methazolamide. These results indicate that the muscarinic-induced acidification is due to HCO3- loss, probably mediated by an anion conductive pathway. 4. The Na+-H+ exchange inhibitor 5-(N-ethyl-N-isopropyl)amiloride (EIPA) amplified the magnitude of the agonist-induced acidification and completely blocked the Na+-dependent pHi recovery. 5. To examine the molecular nature of the Na+-H+ exchange mechanism in sublingual acinar cells, pH regulation was investigated in mice lacking Na+-H+ exchanger isoforms 1 and 2 (NHE1 and NHE2, respectively). The magnitude and the rate of pHi recovery in response to an acid load in acinar cells isolated from mice lacking NHE2 were comparable to that observed in cells from wild-type animals. In contrast, targeted disruption of the Nhe1 gene completely abolished pHi recovery from an acid load. These results demonstrate that NHE1 is critical for regulating pHi during a muscarinic agonist-stimulated acid challenge and probably plays an important role in regulating fluid secretion in the sublingual exocrine gland. 6. In NHE1-deficient mice, sublingual acinar cells failed to recover from an acid load in the presence of bicarbonate. These results confirm that the major regulatory mechanism involved in pHi recovery from an acid load is not Na+-HCO3- cotransport, but amiloride-sensitive Na+-H+ exchange via isoform 1.

Effects of SCN substitution for Cl- on tension, [Ca2+]i, and ionic currents in vascular smooth muscle

Substitution of thiocyanate ions (SCN-) for chloride ions (Cl-) in the extracellular medium of aortic rings and strips causes a biphasic contractile response; initial relaxation followed by sustained contraction. Alterations in these responses are sex-specific, and may elucidate fundamental differences in vascular function between males and females. In order to investigate the role of changes in intracellular Ca2+ ([Ca2+]i) in these changes in tension, we investigated effects of SCN- on [Ca2+]i and ionic currents in vascular smooth muscle cells (VSMC). Extracellular substitution of SCN- for Cl- caused a biphasic change in [Ca2+]i. Initially, [Ca2+]i decreased, reaching a minimum within 1-2 min, subsequently returned to original levels within 4-5 min, and then increased to a higher plateau over the next 10 minutes. This pattern of change in [Ca2+]i is identical to the pattern of tension changes in aortic rings, but it occurs somewhat faster. Partial substitution of SCN- for Cl- elicited increased, but no preceding decrease in [Ca2+]i. In the absence of external Ca2+, anion substitution elicited the decrease in [Ca2+]i but not the subsequent increase. Verapamil (1 microM) blocked the increased [Ca2+]i phase but not the decreased [Ca2+]i phase; whereas, R+ verapamil (up to 5 microM for 20 min), an inactive enantiomer, caused no change. Ionic current measurements obtained using whole cell patch and current clamp techniques revealed two responses to anion substitution: (a) a rapid, transient outward shift in holding current, and (b) a sustained increase in peak current and a hyperpolarizing shift in voltage sensitivity of Ca2+ channels. The calcium channel blocker PN200-110 blocked SCN(-)-enhanced current but had no effect on the changes in holding current. S- verapamil, but not R+ verapamil, reduced SCN(-)-enhanced current. In current clamp mode, SCN- caused an initial hyperpolarization followed by a slow depolarization punctuated by spikes. Thus, SCN- causes changes in vascular smooth muscle [Ca2+]i that could underlie both phases of its effects on tension in isolated aortas and may be explained by the following model: an initial outward shift in current causes hyperpolarization with a consequent decrease in cell excitability, and the somewhat slower increase in Ca2+ channel excitability eventually leads to enhanced calcium influx and tension. These data shed light on possible mechanisms underlying gender-related differences in VSMC physiology.

Mediation of the depolarization-induced [Ca(2+)]i increase in rat sublingual acini by acetylcholine released from nerve terminals

In sublingual mucous acini, membrane depolarization induces a threefold transient increase in cytosolic free Ca(2+) concentration [(Ca(2+))i]. The underlying mechanism was examined by using the Ca(2+) sensitive fluorescent indicator fura-2. Membrane depolarization with high K+ induced a transient [Ca(2+)]i increase in acini, but not in single acinar cells. Atropine, pirenzepine and 4-diphenylacetoxy-N-methylpiperidine methiodide prevented the[Ca(2)+]i increase, suggesting the involvement of muscarinic receptor activation. Inhibition of the inositol trisphosphate (IP3)-sensitive Ca(2+) release pathway with S-(diethylamino)-octyl-3,4,5-trimethoxybenzoate prevented the depolarization-induced increase in [Ca(2+)]i. Blockade of nicotinic receptors and L-, N-, and P-type voltage-dependent Ca(2+) channels (hexamethonium, nifedipine, diltiazem, (omega-conotoxin GVIA and omega-agatoxin IVA) did not inhibit the increase in [Ca(2+)]i. However, Cd(2)+ (0.2 mM) blocked >85 percent of the [Ca2+]i increase. The depolarization-induced [Ca(2+)]i increase was also extracellular Ca(2+)-dependent. These results suggest that the membrane depolarization-induced Ca(2+) increase in sublingual acini is mediated by activating Cd(2+)-sensitive, voltage-dependent Ca(2+) channels in nerve terminals associated with the dispersed acini and stimulating release of acetylcholine, which then triggers the [Ca(2+)]i increase in acinar cells.