Effects of acetylcholine and transport inhibitors on K content in dispersed submandibular salivary cells of newborn and adult rats

Ion transport in an immortalized rat submandibular cell line SMG-C6

The immortalized rat submandibular epithelial cell line, SMG-C6, cultured on porous tissue culture supports, forms polarized, tight-junction epithelia facilitating bioelectric characterization in Ussing chambers. The SMG-C6 epithelia generated transepithelial resistances of 956+/-84Omega.cm2 and potential differences (PD) of -16.9 +/- 1.5mV (apical surface negative) with a basal short-circuit current (Isc) of 23.9 +/- 1.7 microA/cm2 (n = 69). P2 nucleotide receptor agonists, ATP or UTP, applied apically or basolaterally induced a transient increase in Isc, followed by a sustained decreased below baseline value. The peak DeltaIsc increase was partly sensitive to Cl- and K+ channel inhibitors, DPC, glibenclamide, and tetraethylammonium (TEA) and was completely abolished following Ca2+ chelation with BAPTA or bilateral substitution of gluconate for Cl-. The major component of basal Isc was sensitive to apical Na+ replacement or amiloride (half-maximal inhibitory concentration 392 nM). Following pretreatment with amiloride, ATP induced a significantly greater Isc; however, the poststimulatory decline was abolished, suggesting an ATP-induced inhibition of amiloride-sensitive Na+ transport. Consistent with the ion transport properties found in Ussing chambers, SMG-C6 cells express the rat epithelial Na+ channel alpha-subunit (alpha-rENaC). Thus, cultured SMG-C6 cells produce tight polarized epithelia on permeable support with stimulated Cl- secretory conductance and an inward Isc accounted for by amiloride-sensitive Na+ absorption.

Effects of forksolin, dibutyryl cAMP and H89 on Ca2+ mobilization in submandibular salivary cells of newborn rats

The effects of substances which affect cAMP or the cAMP-dependent protein kinase (PKA) on the inositol 1,4,5-trisphosphate (IP3) and Ca2+ responses to acetylcholine or thapsigargin were investigated in submandibular gland cells of newborn rats. Exposure to forskolin, dibutyryl cAMP or the PKA inhibitor H89 did not affect the formation of IP3 or the release of Ca2+ from intracellular stores elicited by acetylcholine. However, the thapsigargin-induced Ca2+ release was reduced by dibutyryl cAMP and enhanced by H89 in immature cells. Ca2+ influx activated by acetylcholine and thapsigargin was additive in immature cells but not in mature cells, suggesting the presence of a separate Ca2+ entry pathway in immature cells. Moreover, the acetylcholine-stimulated Ca2+ influx was significantly potentiated by forskolin and dibutyrylcAMP, but not by H89 in immature cells. In contrast, the thapsigargin-activated Ca2+ influx was dramatically enhanced by H89, but not by forskolin and dibutyrylcAMP in these cells. This modulation of Ca2+ mobilization by the test substances is different from that observed in mature submandibular cells in which forskolin, dibutyrylcAMP and H89 affected both IP3 formation and Ca2+ release in response to acetylcholine. Therefore, these results suggest differences in the interaction between the cAMP-PKA and the phosphoinositide-Ca2+ signalling pathways of mature and immature salivary cells. The modulation of Ca2+ influx by the cAMP-PKA pathway in immature cells is likely to play a part in the maturation of salivary cells.

Developmental aspects of fluid and electrolyte secretion in salivary glands

The salivary glands of rodents undergo considerable cytodifferentiation after birth and are useful models for the study of functional development, including the mechanisms of fluid and electrolyte secretion. In the rat submandibular gland, secretion of salivary fluid cannot be elicited until approximately 2 weeks of age. The currently accepted model of salivary fluid secretion indicates that this process depends on the activation, on stimulation of cholinergic receptors, of several ion transport systems, resulting in a net transport of osmotically active ions (primarily Cl- and Na+) across the acinar epithelium. This creates the necessary osmotic gradient for the transacinar movement of water. The process is associated with a signal transduction pathway involving the formation of phosphoinositide products (primarily inositol triphosphate or IP3) and the mobilization of Ca2+. The latter regulates monovalent ion conductances (K+, Cl-), which are critical for the secretory process. Immature submandibular glands and cells of early postnatal rats have a lower density of cholinergic receptors and release less K+ and Cl- than mature cells and gradually develop other ion transport systems (such as a Na, K, 2Cl cotransport system) involved in the secretory process. Surprisingly, they form more IP3 and show a larger increase in cytosolic Ca2+ when stimulated with maximal or supramaximal concentrations of agonist. Therefore, they show some interesting dissociations in the signal transduction mechanism that suggest differences in the coupling between receptors and membrane phosphoinositides, between IP3 and IP3-dependent Ca2+ stores, and between the Ca2+ signal and the monovalent ion transport systems which are critical for secretion.

Intracellular [Ca2+] and K+ and Cl- efflux responses in submandibular cells of neonatal and adult rats

The effects of graded doses (5 x 10(-8) to 10(-5)) acetylcholine on intracellular Ca2+ and on 86Rb and 36Cl efflux were compared in submandibular cell clusters of 1 and 7 day-old and adult rats. Initial Ca2+ peaks were similar at agonists concentrations lower than 10(-7) M but the release of Rb+ and Cl- were smaller in cells of young animals. At higher agonist concentrations, Ca2+ peaks were higher in immature cells; however, initial Cl- (but not Rb+) efflux was similar to that of mature cells. Plateau Ca2+ levels were independent of age and agonist concentrations but the content of Cl- and Rb+ varied greatly and differences between age groups were less evident. These data confirm a dissociation between intracellular Ca2+ levels and Ca(2+)-mediated ion transport in immature salivary cells.

Intracellular pH changes induced by exposure to weak acids and bases in submandibular cells of early postnatal rats

The intracellular pH of submandibular cells of adult, 1-day-old and 1-week-old rats was measured with the pH sensitive fluorimetric indicator SNARF-1, following shifts induced by exposure to a weak acid (sodium butyrate) or a weak base (NH4Cl). The effects of several ion transport inhibitors and agonists on both the pH change and the rate of recovery were examined. The results indicate that, in most respects, the processes involved in pH regulation were similar in the neonatal and mature cells. However, cholinergic and peptidergic stimulation accelerated recovery from sodium butyrate-induced acidification more, and from NH4Cl-induced alkalinization less, in cell preparations from 1-day-old animals.

The effect of NH4Cl on Rb+ fluxes in resting and stimulated rat submandibular acinar cells

Dispersed salivary acini isolated from the rat submandibular gland were incubated in a HEPES-buffered Krebs-Ringer solution or in the same buffer containing 20 mM NH4Cl and the accumulation and efflux of K+ were measured with the radiotracer 86Rb+, in the presence and absence of acetylcholine and of transport inhibitors. Exposure to NH4Cl caused a significant (greater than 50%) reduction in tracer accumulation. This effect was blocked by 0.1 mM bumetanide, but not by 1 mM ouabain. The effect of NH4Cl was, on the other hand, nearly additive with that of 1 microM acetylcholine. In cells preincubated with tracer, acute addition of NH4Cl caused a significant net efflux of isotope, so that the tracer content fell to 45% of the control value within 10 min. Bumetanide added to preloaded cells in the same fashion had no effect on tracer content and did not modify the efflux of 86Rb+ induced by 1 microM acetylcholine. However, this inhibitor essentially abolished the NH4Cl-induced tracer efflux. Exposure to NH4Cl during tracer loading did not appear to affect subsequent agonist-stimulated tracer efflux. These results suggest that: (1) the inhibition of K+ entry by NH4Cl is due to an effective competition by the NH4+ ion with Rb+ (and K+) for uptake via a bumetanide-sensitive Na+/K+/2Cl- contransporter.(ABSTRACT TRUNCATED AT 250 WORDS)

Na+ influx mechanisms in submandibular salivary cells of newborn rats

Uptake of this isotopic tracer was essentially the same as in cells derived from salivary glands of adult animals, both in the absence and in the presence of 1 microM acetylcholine, 10 microM monensin or 10 microM A23187. Tracer accumulation in resting cells was inhibited in the immature cells by 1 mM amiloride but the inhibition was significantly smaller than in fully mature cells (16 and 33%, respectively). Bumetanide inhibited tracer uptake by 28% in mature cells not exposed to agonist, but had essentially no effect in those of newborn rats. The tracer content of adult cells exposed to acetylcholine in Ca(2+)-free incubation solutions was significantly reduced when compared to that of cells exposed to agonist in solutions containing 1.0 mM CaCl2. A similar but significantly smaller reduction in tracer content was observed in cells of newborn animals incubated in the Ca(2+)-free medium. The inhibition of 22Na uptake observed in the presence of amiloride was the same in both types of cells in the presence or absence of external Ca2+. The findings suggest that Na entry into immature salivary cells of newborn rats is quantitatively similar to that in mature cells, but that the contribution of the loop diuretic-sensitive co-transporter and of the amiloride-sensitive Na/H exchange to Na+ entry is less in the immature cells. Na entry in the immature cells is likely to occur, therefore, primarily by other mechanisms such as Ca(2+)-regulated channels.

The influence of vasoactive intestinal peptide receptors in dispersed acini from rat submandibular gland on cyclic AMP production and mucin release

Vasoactive intestinal peptide has been identified as an important regulator of submandibular salivary gland function, consistent with its localization with acetylcholine in parasympathetic neurones innervating this gland. Enzymatically dispersed acini from rat submandibular gland are a useful system in which to study gland regulation at the cellular level. Here, three aspects of vasoactive intestinal peptide interactions with acini were examined: inhibition of binding of [125I]-vasoactive intestinal peptide, stimulation of cyclic AMP production and enhancement of mucin release. Vasoactive intestinal peptide and peptide histidineisoleucineamide inhibited [125I]-vasoactive intestinal peptide binding to intact acini, with IC50 values of 16 +/- 3 and 46 +/- 17 nM, respectively. This rank order of potency agrees with that observed previously in assays using rat submandibular gland membranes and is similar to values obtained in assays measuring increases in cyclic AMP production in which the ED50 values for vasoactive intestinal peptide and peptide histidineisoleucineamide were 3.1 +/- 1.8 and 29 +/- 13 nM, respectively. Although vasoactive intestinal peptide stimulation of cyclic AMP production was only about 10% of that seen in response to isoproterenol, the levels of mucin release induced by the two agents were more similar. The ED50 for vasoactive intestinal peptide-stimulated mucin release was 0.12 +/- 0.05 nM, thus suggesting an activation anomaly in the vasoactive intestinal peptide receptor-coupled signal transduction pathway at a point between cyclic AMP production and mucin release.

Amiloride inhibits 22Na uptake and [3H]QNB binding in rat submandibular cells

Dispersed acini isolated by collagenase digestion of the rat submandibular gland were used to compare the effects of amiloride and furosemide on the uptake of the isotopic tracer 22Na and on the binding of [3H]quinuclidinyl benzylate ([3H]QNB). In mM concentrations, both inhibitors reduced 22Na uptake in resting cells 34 and 25-29%, respectively. Acetylcholine (1 microM) enhanced uptake 23% and this effect was reduced 45% by amiloride and 26% by furosemide. Amiloride inhibited the binding of [3H]QNB to crude membranes prepared from fresh submandibular glands in a dose-dependent fashion (IC50 = 8 x 10(-6) M). Furosemide (3 x 10(-8) to 10(-3) M) did not inhibit radioligand binding. Na influx into resting salivary acini thus appears to occur by both amiloride-sensitive and furosemide-sensitive transport systems. The similar inhibition by furosemide of unstimulated and stimulated uptake of 22Na suggests that acetylcholine does not significantly activate the cotransport system within the time frame (i.e., 2 min) of the experiments. Acetylcholine appears to activate an amiloride-sensitive Na/H antiport, but amiloride blocks cholinergic receptors and may thus affect Na transport by receptor blockade. Other actions of amiloride, such as its ability to penetrate into cells and to act as a weak base which alters intracellular pH, may also contribute to the inhibition of Na entry into salivary cells.