Membrane potential and resistance measurement in acinar cells from salivary glands in vitro: effect of acetylcholine

Watching Living Cells in Action in the Exocrine Pancreas: The Palade Prize Lecture

George Palade's pioneering electron microscopical studies of the pancreatic acinar cell revealed the intracellular secretory pathway from the rough endoplasmic reticulum at the base of the cell to the zymogen granules in the apical region. Palade also described for the first time the final stage of exocytotic enzyme secretion into the acinar lumen. The contemporary studies of the mechanism by which secretion is acutely controlled, and how the pancreas is destroyed in the disease acute pancreatitis, rely on monitoring molecular events in the various identified pancreatic cell types in the living pancreas. These studies have been carried out with the help of high-resolution fluorescence recordings, often in conjunction with patch clamp current measurements. In such studies we have gained much detailed information about the regulatory events in the exocrine pancreas in health as well as disease, and new therapeutic opportunities have been revealed.

Membrane potential modulation of ionomycin-stimulated Ca(2+) entry via Ca (2+)/H (+) exchange and SOC in rat submandibular acinar cells

Ionomycin (IM) at 5 microM mediates the Ca(2+)/H(+) exchange, while IM at 1 microM activates the store-operated Ca(2+) entry channels (SOCs). In this study, the effects of depolarization on both pathways were examined in rat submandibular acinar cells by increasing extracellular K(+) concentration ([K(+)](o)). IM (5 microM, the Ca(2+)/H(+) exchange) increased the intracellular Ca(2+) concentration ([Ca(2+)](i)) to an extremely high value at 151 mM [K(+)](o). However, with increasing [K(+)](o), the rates of Ca(2+) entry decreased in a linear relationship. The reversal potential (E (rev)) for the Ca(2+)/H(+) exchange was +93 mV, suggesting that IM (5 microM) exchanges 1 Ca(2+) for 1 H(+). Thus, depolarization decreases the Ca(2+) influx via the Ca(2+)/H(+) exchange because of its electrogenicity (1 Ca(2+) for 1 H(+)). On the other hand, IM (1 microM, the SOCs) abolished an increase in [Ca(2+)](i) at 151 mM [K(+)](o). With increasing [K(+)](o), the rate of Ca(2+) entry immediately decreased linearly. The E (rev) for the SOC was +3.7 mV, suggesting that the SOCs are nonselective cation channels and less selective for Ca(2+) over Na(+) (P (Ca)/P (Na) = 8.2). Moreover, an increase in extracellular Ca(2+) concentration (20 mM) enhanced the Ca(2+) entry via the SOCs at 151 mM [K(+)](o), suggesting depolarization does not inhibit the SOCs and decreases the driving force for the Ca(2+) entry. This suggests that membrane potential changes induced by a secretory stimulation finely regulate the [Ca(2+)](i) via the SOCs in rat submandibular acinar cells. In conclusion, IM increases [Ca(2+)](i) via two pathways depending on its concentration, the exchange of 1 Ca(2+) for 1 H(+) at 5 muM and the SOCs at 1 microM.

Ca2+ signalling and Ca2+-activated ion channels in exocrine acinar cells

The development of the calcium signalling field, from its early beginnings some 40 years ago to the present, is described. Calcium signalling in exocrine gland acinar cells and the effects of neurotransmitter- or hormone-elicited rises in the cytosolic calcium ion concentration on ion channel gating are reviewed. The highly polarized arrangement of the organelle systems in living acinar cells is described as well as its importance for the physiologically relevant local and polarized calcium signalling events.

A novel chloride conductance activated by extracellular ATP in mouse parotid acinar cells

Salivary gland fluid secretion is driven by transepithelial Cl- movement involving an apical Cl- channel whose molecular identity remains unknown. Extracellular ATP (ATP(o)) has been shown to activate a Cl- conductance (I(ATPCl)) in secretory epithelia; to gain further insight into I(ATPCl) in mouse parotid acinar cells, we investigated the effects of ATP(o) using the whole-cell patch-clamp technique. ATP(o) and 2'- and 3'-O-(4-benzoylbenzoyl)adenosine 5'-triphosphate triethylammonium salt (Bz-ATP) produced concentration-dependent, time-independent Cl- currents with an EC50 of 160 and 15 microM, respectively. I(ATPCl) displayed a selectivity sequence of SCN- > I- = NO3- > Cl- > glutamate, similar to the Cl- channels activated by Ca2+, cAMP and cell swelling in acinar cells. In contrast, I(ATPCl) was insensitive to pharmacological agents that are known to inhibit these latter Cl- channels, was independent of Ca2+ and was not regulated by cell volume. Moreover, the I(ATPCl) magnitude from wild-type animals was comparable to that from mice with null mutations in the Cftr, Clcn3 and Clcn2 Cl- channel genes. Taken together, our results demonstrate that I(ATPCl) is distinct from the channels described previously in acinar cells. The activation of I(ATPCl) by Bz-ATP suggests that P2 nucleotide receptors are involved. However, inhibition of G-protein activation with GDP-beta-S failed to block I(ATPCl), and Cibacron Blue 3GA and 4,4'-diisothyocyanostilbene-2,2'-disulphonic disodium salt selectively inhibited the Na+ currents (presumably through P2X receptors) without altering I(ATPCl), suggesting that neither P2Y nor P2X receptors are likely to be involved in I(ATPCl) activation. We conclude that I(ATPCl) is not associated with Cl- channels previously characterized in mouse parotid acinar cells, nor is it dependent on P2 nucleotide receptor stimulation. I(ATPCl) expressed in acinar cells reflects the activation of a novel ATP-gated Cl- channel that may play an important physiological role in salivary gland fluid secretion.

Loss of hyperpolarization-activated Cl(-) current in salivary acinar cells from Clcn2 knockout mice

ClC-2 is localized to the apical membranes of secretory epithelia where it has been hypothesized to play a role in fluid secretion. Although ClC-2 is clearly the inwardly rectifying anion channel in several tissues, the molecular identity of the hyperpolarization-activated Cl(-) current in other organs, including the salivary gland, is currently unknown. To determine the nature of the hyperpolarization-activated Cl(-) current and to examine the role of ClC-2 in salivary gland function, a mouse line containing a targeted disruption of the Clcn2 gene was generated. The resulting homozygous Clcn2(-/-) mice lacked detectable hyperpolarization-activated chloride currents in parotid acinar cells and, as described previously, displayed postnatal degeneration of the retina and testis. The magnitude and biophysical characteristics of the volume- and calcium-activated chloride currents in these cells were unaffected by the absence of ClC-2. Although ClC-2 appears to contribute to fluid secretion in some cell types, both the initial and sustained salivary flow rates were normal in Clcn2(-/-) mice following in vivo stimulation with pilocarpine, a cholinergic agonist. In addition, the electrolytes and protein contents of the mature secretions were normal. Because ClC-2 has been postulated to contribute to cell volume control, we also examined regulatory volume decrease following cell swelling. However, parotid acinar cells from Clcn2(-/-) mice recovered volume with similar efficiency to wild-type littermates. These data demonstrate that ClC-2 is the hyperpolarization-activated Cl(-) channel in salivary acinar cells but is not essential for maximum chloride flux during stimulated secretion of saliva or acinar cell volume regulation.

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.

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.

Study of nonspecific cation channel coupled to P2z purinergic receptors using an acid load technique

The intracellular pH (pHi) of rat submandibular cells was measured by 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein (BCECF). The cells recovered from ammonium (30 mM) prepulse to their resting pHi within 10 min. Ethylisopropylamiloride (EIPA), an inhibitor of the Na+/H+ exchanger, slows the rate of pHi recovery. ATP (1 mM), in the presence of EIPA, increases the rate of recovery 3.7-fold in the absence or presence of ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid. The recovery was blocked by the addition of 5 mM Mg2+ or 10 microM Coomassie blue. The response was elicited by 2'- and 3'-O-(4-benzoylbenzoyl)-adenosine 5'-triphosphate but not by ADP, UTP, adenyl (beta-gamma-methylene)-diphosphonate, 2-methylthioadenosine 5'-triphosphate, or muscarinic or beta-adrenergic agonists. The purinergic response was also observed when the cells were acidified by sodium propionate and could not be mimicked by the depolarization of the plasma membrane. Aluminum fluoride did not reproduce the response to ATP, suggesting that the observed response does not involve a high-molecular-weight GTP-binding protein. It is concluded that the activation of P2z receptors, probably by the opening of nonspecific cation channels, increases the permeability to protons in rat submandibular glands.

Three distinct chloride channels control anion movements in rat parotid acinar cells

1. We used the whole-cell configuration of the patch clamp technique to examine the different macroscopic Cl- currents present in single rat parotid acinar cells. 2. Cell swelling produced by negative osmotic pressure (hypotonic bath solutions) induced a large outwardly rectifying Cl- current with little or no time and voltage dependence. In contrast, an increase in intracellular [Ca2+] induced by ionomycin activated Cl- currents with very different properties. Ca(2+)-activated Cl- currents showed outward rectification, relatively slow activation kinetics and marked voltage dependence. These results are consistent with the existence of two different outwardly rectifying Cl- channels in rat parotid cells. 3. In conditions designed to eliminate the activation of these two Cl- currents, a third type of current was observed. This third current was activated in a time-dependent manner by hyperpolarized potentials and was about equally permeant to Cl-, I- and Br-. 4. The properties of the hyperpolarization-activated current were similar to those of the cloned ClC-2 channel. Polymerase chain reaction-based methods and ribonuclease protection analyses indicated the presence in parotid gland of mRNA homologous to ClC-2. 5. Individual parotid acinar cells expressed all three types of Cl- channels. Each type of channel may contribute to Cl- efflux in distinct stages of the secretion process depending on the intracellular [Ca2+], cell volume and membrane potential.

Responses of salivary acinar cells to intracellular alkalinization

Responses of rat submandibular acini to intracellular alkalinization were investigated. Intracellular alkalinization was induced by addition of NH4Cl or methyl amines, or by prepulse with Na butyrate. Only partial recovery occurred following Na butyrate prepulse or methylated amine addition, but full recovery was observed following addition of NH4Cl. The latter recovery was DIDS and dimethylamiloride-insensitive but was inhibited by bumetanide or high [K+] and stimulated in Na(+)-free buffer and by ouabain. Acetylcholine stimulated recovery from NH4Cl- or Na butyrate pre-pulse-induced alkalinization and reduced the extent of alkalinization induced by methylated amines. Acetylcholine-stimulated recovery from NH4Cl-induced alkalinization was mimicked by substance P or ionomycin and was partially Ca(2+)-dependent. This stimulated recovery was bumetanide-insensitive but was partially sensitive to charybdotoxin. Taken together, these data indicate that in unstimulated cells, recovery from alkalinization induced by NH4Cl occurs by bumetanide-sensitive transport of the NH4+ ion, that DIDS-inhibitable anion transport contributes little to this recovery, and that acetylcholine and other Ca(2+)-elevating agents accelerate recovery from NH4Cl-induced alkaline challenge by a mechanism insensitive to bumetanide, DIDS, ouabain, and dimethylamiloride but sensitive to extracellular Ca2+ and to charybdotoxin. Partial recovery from alkaline challenge can also occur in the absence of NH4+ ions, and acetylcholine also stimulates this mode of recovery. Together, these data suggest that these cells have little intrinsic ability to recover from intracellular alkalinization and that the NH4+ ion may be a surrogate for K+ in at least two ion transport pathways.

Acetylcholine- and caffeine-evoked repetitive transient Ca(2+)-activated K+ and C1- currents in mouse submandibular cells

1. Resting and acetylcholine-induced membrane currents were measured in single mouse submandibular acinar cells using the patch-clamp whole-cell current recording technique. 2. Micromolar ACh activated a large, sustained outward, Ca(2+)-dependent K+ current and a single transient inward Ca(2+)-dependent C1-current. 3. Nanomolar ACh induced a series of transients in both the K+ and C1- currents; C1- current activation was now observed throughout the period of agonist application. We consider this repetitive transient current activation better able to support sustained fluid and electrolyte secretion than the response elicited by a high dose of agonist. 4. Repetitive K+ and C1- current transients were also induced by 1 mM-caffeine, consistent with caffeine-induced Ca2+ release from the Ca(2+)-sensitive Ca2+ stores which are thought to comprise part of the pathway for activation of secretion. 5. The ACh-induced current transients were inhibited by 10 mM-caffeine, 100 microM-IBMX and 10 microM membrane-permeable cyclic AMP. Therefore, it seems likely that caffeine is able to inhibit agonist-induced calcium mobilization via a cyclic AMP-dependent pathway.

Stimulus-secretion coupling: cytoplasmic calcium signals and the control of ion channels in exocrine acinar cells

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Evidence for apical chloride channels in rabbit mandibular salivary glands. A chloride-selective microelectrode study

Double-barrelled, chloride-selective microelectrodes were used to study mandibular gland acinar cells at rest and during cholinergic stimulation. At rest, intracellular chloride activity was five times the expected equilibrium activity. During sustained stimulation with acetylcholine, chloride activity fell to three times the expected equilibrium activity. Thus, the gradient for chloride exit was reduced in the stimulated cell. These results lead to the conclusion that stimulation increases the permeability of the acinar cell to chloride. Experiments in which extracellular chloride was removed provided evidence that the permeability increase was due to opening of chloride channels located principally in the apical membrane of the acinar cell.

The control of ion channels and pumps in exocrine acinar cells

The historical development of ideas concerning mechanisms of exocrine fluid secretion will be traced from the original finding of stimulant-evoked K+ release in 1956 to current models involving Ca2+-activated K+ and Cl- channels.

Potassium uptake in the mouse submandibular gland is dependent on chloride and sodium and abolished by piretanide

Nervous or hormonal stimulation of salivary secretion in vivo is associated with a pronounced efflux of K+ from the secretory, acinar cells into the blood. This K+ efflux is followed in the post-stimulus period by a reuptake of K+ into the glandular tissue. In the present study we monitor the changes in [K+] of physiological solutions perfusing a flow chamber containing isolated segments of mouse submandibular glands. Nervous stimulation or the application of exogenous acetylcholine (ACh, 10(-5) M) to the isolated glandular tissue results in characteristic changes in the [K+] of the superfusate, indicating net K+ release followed by K+ reuptake. The post-stimulus reuptake of K+ is shown to be susceptible to blockade by either ouabain (10(-3) M) or piretanide (10(-4) M). The reuptake was markedly attenuated if Cl- in the superfusate was replaced by either NO3- or SO4(2-). The K+ uptake was, however, unaffected when Br- replaced Cl- in the superfusate. Similar effects were observed in the unstimulated glandular tissues. The introduction of Cl-(-)free media containing either NO3- or SO4(2-) resulted in a loss of K+ from the tissue which was followed, upon reintroduction of Cl-, by a pronounced uptake of K+. When Br- was substituted for Cl- there was very little change in [K+] upon removal or reintroduction of Cl-. The uptake of K+ induced by reintroduction of Cl- after a period of NO3- or SO4(2-) superfusion was blocked by both ouabain and piretanide. This uptake of K+ was also dependent on the presence of extracellular Na+. Both Cl- and Na+ had to be present in the superfusing medium for K+ uptake to be fully manifest. These findings indicate that the K+ uptake observed in both the resting and stimulated submandibular gland cannot be explained as solely due to the activity of the Na+-K+-adenosine triphosphatase (Na+-K+-ATPase). The demonstrated anionic selectivity, dependence on extracellular Na+ and susceptibility to blockade by the diuretic piretanide would strongly suggest that a coupled Na+-K+-Cl- co-transport system operates in submandibular glands as it does in other transporting epithelia to achieve K+ uptake.

A patch-clamp study of potassium currents in resting and acetylcholine-stimulated mouse submandibular acinar cells

Salivary acini were enzymatically isolated from submandibular glands of adult male mice. The patch-clamp technique was employed to investigate the conductive properties and activities of a large-conductance K+ channel in both cell-attached and in excised patches of basolateral acinar cell membranes. In excised, inside out, patches with identical high-K+ solutions (145 mM-KCl) on either side of the membrane the current-voltage (I-V) plot was linear. The mean single-channel conductance was 245 +/- 4.8 ps with a single-channel permeability of 4.6 X 10(-13) cm3 s-1. At Ca2+ concentrations of 10(-9)-10(-8) M bathing the intracellular membrane face the channel was exquisitely sensitive to changes in transmembrane potential, i.e. voltage sensitive. At 10(-7) M-Ca the channel was almost always open and displayed little sensitivity to voltage. Single-channel currents were recorded in cell-attached patches. When the recording pipettes contained the high-K+ solution the I-V plots were linear and the mean single-channel conductance and permeability almost identical to that in the excised patches. The mean spontaneous resting potential of the acinar cells bathed in physiological saline (140 mM-NaCl, 4.5 mM-KCl) was -43 +/- 1.8 mV. The voltage sensitivity of the in situ K+ channel was very similar to that recorded in excised patches at 10(-9)-10(-8) M-Ca. In experiments designed to reproduce the physiological ionic gradients across the patch membrane pipettes were filled with the high-Na+ solution. The I-V plot was not linear but showed pronounced rectification at negative membrane potentials. The channel is K+ selective and the extrapolated reversal potential was close to -90 mV. The single-channel conductance at the spontaneous resting membrane potential was about 35 pS. The single-channel permeability was however only slightly reduced at 4.29 X 10(-13) cm3 s-1. It was demonstrated that current flow through the open K+ channel could be accurately modelled using constant field electrodiffusion theory. Continuous in situ recordings before and after application of the agonist acetylcholine to the solution bathing the acini revealed that acetylcholine stimulation is associated with a marked increase in the frequency and duration of K+ currents in the patch membrane. The increased current activity in the patch membrane during acetylcholine application must be mediated via an intracellular second messenger and was very similar to that observed in the excised patches on increasing ionized Ca2+ concentrations from 10(-8) to 10(-7) M.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of acetylcholine and short-chain fatty acids on acinar cells of the exocrine pancreas in sheep

In order to investigate the actions of acetylcholine and short-chain fatty acids on acinar cells of the exocrine pancreas of sheep, measurements of amylase release and 45Ca efflux from superfused segments, as well as changes in membrane potential, input resistance and equilibrium potential in the acinar cells, were carried out in vitro. The application of acetylcholine or short-chain fatty acids caused a dose-dependent increase in amylase release from the superfused tissue segments. The amylase release evoked by 10(-3) M-short-chain fatty acids containing 2-8 carbon atoms increased with increasing carbon number, up to 5 (i.e. it was maximum with iso-valerate, which has 5 carbon atoms). The amylase release stimulated by acetylcholine (5.5 X 10(-6) M) or caprylate (10(-3) was accompanied by an increase in 45Ca efflux, and was significantly reduced by the removal of extracellular Ca2+. The stimulating effect of caprylate (10(-3) M) on amylase secretion was also observed in superfused segments of the guinea-pig, but not in those of the mouse, rabbit or hamster. The resting membrane potential and input resistance of acinar cells of sheep pancreas were -31.1 +/- 1.6 mV and 2.7 +/- 0.7 M omega (means +/- S.E. of means), respectively. The application of acetylcholine or short-chain fatty acids always depolarized the cell membrane and reduced the input resistance. The effect of short-chain fatty acids was observed in the presence of atropine (1.4 X 10(-6) M). The equilibrium potentials for acetylcholine and butyrate were -15.0 +/- 0.8 and -16.0 +/- 1.1 mV, respectively. It is concluded that the cellular secretory process evoked by acetylcholine is qualitatively similar to that of short-chain fatty acids, and that Ca2+ ions might be an important mediator for these secretagogues in the acinar cells of the pancreas of sheep.

Effect of extracellular K+ on saliva secretion by isolated, perfused rat submandibular glands

Changes in perfusate K+ concentration altered the secretory response of the glands to 10(-6) M acetylcholine. Lack of extracellular K+ caused a transient fluid secretory response lasting less than 10 min, and a 91 per cent reduction in the overall volume of saliva secreted in 60 min; it inhibited the response to acetylcholine even when the perfusate was changed to K+-containing solutions after 30 min. Absence of K+ in the perfusate resulted in increased Na+ and decreased K+ and Cl- concentrations in saliva. An increase in the perfusate K+ concentration to 50 mM/l caused a reduced but more sustained secretory response, although the volume of saliva secreted in 60 min was still reduced by 76 per cent compared to that obtained when the perfusate contained 4.6 m-equiv./l K+. Acetylcholine release induced by the high K seemed mostly responsible as the response was inhibited by atropine. However, in the presence of excess of exogenous acetylcholine, perfusion with high K+ medium resulted in reduced Na+ and elevated K+ and Cl- concentrations in saliva. It seems that a physiological (4-5 m-equiv./l) extracellular K+ concentration is required for acinar fluid secretion and for transductal electrolyte transport in the rat glands; lack of external K+ hyperpolarizes salivary cells and, although allowing an initial increase in Na+ conductance capable of causing secretion, prevents the further influx of this ion required to sustain saliva secretion. It also inhibits K+ secretion and Na+ re-absorption in salivary ducts, probably by inhibiting the Na+, K+ pump in duct cells; high external K+ depolarizes acinar cells and may reduce Na+ conductance.(ABSTRACT TRUNCATED AT 250 WORDS)

Electric current flow in a two-cell preparation from Chironomus salivary glands

Conventional micro-electrode techniques were used to study the passive electrical properties of salivary glands from Chironomus nuditarsis insect larvae of the fourth instar stage. Linear cable analysis performed on intact glands revealed the following constants: axial intracellular resistance, Ri = 2730 omega cm; membrane resistance per unit apparent cylindrical area, Rm = 1350 omega cm2; membrane capacitance per unit apparent cylindrical area, Cm = 17.6 microF cm-2. The multicellular glands were reduced to intact two-cell preparations by destroying neighbouring cells mechanically. Each cell of a coupled cell pair was impaled with two micro-electrodes, one to pass rectangular current pulses and the other to monitor the resulting voltage deflexions. Internal consistency tests revealed that the experimental data under steady-state conditions may be described accurately by an equivalent circuit consisting of a delta configuration of three resistive elements: the resistances of the non-junctional membrane of cell 1 and cell 2 (r1 and r2), and the resistance of the gap junctional membrane connecting the two cells (rg). The current-voltage relation of the non-junctional membrane was found ohmic over a membrane potential ranging from -40 mV to + 10 mV. The mean value of Rm was 2020 omega cm2. The resistance function of the gap junctional membrane was also ohmic. There was no dependence of gap junctional resistance on voltage or direction of current flow, at least over the relatively narrow range of potentials tested (approximately +/- 10 mV). Individual values of rg varied from 20 to 3800 k omega, with an over-all mean of 1100 k omega. The lower values are thought to represent the physiological state of cellular coupling, whereas the higher ones may reflect partial uncoupling caused by local damage. The proposed cell pair is a suitable preparation for studying problems related to intercellular coupling.

Substance P is a functional neurotransmitter in the rat parotid gland

The technique of electrical field stimulation was employed to stimulate the intrinsic nerves of isolated rat parotid gland fragments. Responses to field stimulation were recorded as changes in enzyme secretion (amylase release), radiolabelled ion fluxes (86Rb efflux) and electrophysiological effects (changes in acinar cell membrane potential and input resistance). All effects of field stimulation were abolished by the neurotoxin, tetrodotoxin (TTX). Selective use of pharmacological antagonists revealed that both the sympathetic and parasympathetic nerves to this tissue were being excited by field stimulation. Importantly a significant component of the response to field stimulation persisted in the presence of combined autonomic receptor blockade by atropine, phentolamine and propranolol, i.e. due to release of a non-cholinergic, non-adrenergic neurotransmitter. The non-cholinergic, non-adrenergic neurotransmitter evoked amylase release, 86Rb efflux and electrophysiological effects seen as changes in acinar cell membrane potential and conductance, i.e. stimulus-permeability coupled. Two biologically active peptides, substance P (SP) and vasoactive intestinal polypeptide (VIP) were shown to evoke amylase release in the presence of combined autonomic blockade. VIP however did not evoke any increase in 86Rb efflux, i.e. not stimulus-permeability coupled. All the effects of the non-cholinergic, non-adrenergic transmitter were mimicked by substance P which evokes 86Rb efflux and electrophysiological effects in addition to amylase release. The non-cholinergic, non-adrenergic field stimulus effects on amylase release and 86Rb efflux were abolished or markedly attenuated in tissues which had been desensitized by prior exposure to exogenous substance P. In the presence of VIP, however, the non-cholinergic, non-adrenergic effects persisted and were apparently potentiated. Acute application of the neurotoxin capsaicin first stimulated a transient release of amylase and subsequently abolished the non-cholinergic, non-adrenergic field stimulus-evoked enzyme release. The putative substance P antagonist, D-Pro2, D-Trp7,9 substance P, reversibly blocked the response to both non-cholinergic, non-adrenergic nerve stimulation and exogenous substance P. It was demonstrated however that prolonged exposure to this antagonist is associated with non-reversible and, importantly, non-specific neurotoxic effects. It is concluded that substance P or a closely related peptide is a functional neurotransmitter in the rat parotid gland.

Activation of potassium transport induced by secretagogues in superfused submaxillary gland segments of rat and mouse

In order to investigate the actions of acetylcholine (ACh), catecholamines and substance P on K transport in the submaxillary gland, measurements of net K flux to and from the gland tissue using flame photometry, Na efflux from the tissue using radioactive 22Na, and membrane potential and input resistance using micro-electrodes were carried out on isolated superfused segments of rat and mouse submaxillary glands. ACh (5.5 X 10(-8) to 5.5 X 10(-4) M), phenylephrine (5 X 10(-7) to 5 X 10(-4) M) or substance P (10(-9) to 10(-5) M) stimulation for 5 min induced a transient K release followed by a small K uptake after the cessation of stimulation. The K release was markedly enhanced by the simultaneous addition of ouabain (10(-3) M). On the other hand, isoprenaline (2.5 X 10(-9) to 2.5 X 10(-5) M) induced a transient K uptake without any preceding K release. The K uptake was completely blocked by the addition of ouabain. Noradrenaline induced only K uptake at a low concentration (3 X 10(-7) M), but induced transient K release followed by marked K uptake at higher concentrations (3 X 10(-6) to 3 X 10(-4) M). The K release induced by noradrenaline was suppressed by the addition of phentolamine (10(-5) M), while the K uptake was suppressed by propranolol (5 X 10(-6) M). The K release induced by ACh, phenylephrine, noradrenaline or substance P was severely reduced by Ca omission from the superfusing solution and restored by the re-admission of Ca. The isoprenaline- or noradrenaline-induced K uptake was, however, little affected by Ca omission. Application of isoprenaline (2.5 X 10(-6) M) induced an increase in 22 Na efflux. The increase in 22Na efflux was completely abolished in the presence of ouabain. Local application to the tissue bath of isoprenaline (4.7 X 10(-13) to 4.7 X 10(-12) mole) or noradrenaline (5.7 X 10(-12) to 5.7 X 10(-11) mole) in the presence of phentolamine (10(-5) M) induced membrane hyperpolarization without any appreciable change in input resistance. The hyperpolarization was abolished in the presence of ouabain (10(-3) M) or propranolol (5 X 10(-6) M) or in a K-free or low Na solution. Higher doses of both agonists, however, induced depolarization or biphasic responses (initial depolarization followed by hyperpolarization). The depolarizations were accompanied by a moderate reduction in input resistance. It is concluded that in the rat and mouse submaxillary gland acinar cells cholinergic, alpha-adrenergic or substance P stimulation causes K release (and perhaps Na uptake) resulting in activation of the Na-K pump, while beta-adrenergic receptor stimulation might directly activate the Na-K pump resulting in K uptake, or might cause Na uptake resulting in activation of the Na-K pump.

Voltage and Ca2+-activated K+ channel in baso-lateral acinar cell membranes of mammalian salivary glands

Nervous or hormonal stimulation of many exocrine glands evokes release of cellular K+ (ref. 1), as originally demonstrated in mammalian salivary glands2,3, and is associated with a marked increase in membrane conductance1,4,5. We now demonstrate directly, by using the patch-clamp technique6, the existence of a K+ channel with a large conductance localized in the baso-lateral plasma membranes of mouse and rat salivary gland acinar cells. The K+ channel has a conductance of approximately 250 pS in the presence of high K+ solutions on both sides of the membrane. Although mammalian exocrine glands are believed not to possess voltage-activated channels1,7, the probability of opening the salivary gland K+ channel was increased by membrane depolarization. The frequency of channel opening, particularly at higher membrane potentials, was increased markedly by elevating the internal ionized Ca2+ concentration, as previously shown for high-conductance K+ channels from cells of neural origin8-10. The Ca2+ and voltage-activated K+ channel explains the marked cellular K+ release that is characteristically observed when salivary glands are stimulated to secrete.

Substance P: indirect and direct effects on parotid acinar cell membrane potential

Direct effects of exogenously applied substance P on salivary acinar cells have been previously reported. This electro-physiological study confirms these direct effects in rat but not mouse parotid gland. We demonstrate that in the absence of autonomic blockade the peptide evokes marked responses which are blocked by atropine (10(-6) M). These effects cannot be attributed to direct activation of acinar cells and are presumably due to release of acetylcholine from parasympathetic nerve endings. We consider that substance P, in addition to direct effects, could act to modulate neuronal activity in salivary glands; a role already assigned to the peptide in the central nervous system.

Electrophysiology of mouse parotid acini: effects of electrical field stimulation and ionophoresis of neurotransmitters

1. Intracellular micro-electrode recordings of membrane potential and input resistance were made from surface acini of mouse parotid glands placed in a Perspex tissue bath through which oxygenated physiological saline solutions were circulated. The acinar cells were stimulated by microionophoresis of both acetylcholine (ACh) and adrenaline (Ad) from extracellular micropipettes, and by electrical field stimulation via a pair of platinum electrodes. 2. The acinar cells had a mean resting membrane potential of -64.9 mV +/- 0.6 S.E. The input resistance of the unstimulated cell was 4.63 M omega +/- 0.19 S.E. In a number of cells spontaneous miniature depolarizations were observed, associated with synchronous reductions in input resistance. 3. The responses to ionophoresis of both ACh and Ad and the response to supra-maximal field stimulation were identical. Stimulation always evoked a marked decrease in input resistance associated with an initial potential change, generally followed by a delayed hyperpolarization during which the input resistance returned to normal. 4. Field-stimulation responses could be evoked to single shock (1-2 msec) and to low frequency (1-4 Hz) stimulation. The latency for this response was 245 msec +/- 12 S.E. 5. The field-stimulation response was shown to be susceptible to blockade of nerve conduction in sodium-free or tetrodotoxin- (TTX-) containing media; and to blockade of neurotransmitter release in calcium-free media. 6. The field-stimulation and ACh responses were recorded at different levels of membrane potential within the same cells by applying either hyperpolarizing or depolarizing direct current through the recording electrode. The membrane potential at which the initial potential change undergoes reversal, i.e. changes from a depolarization to a hyperpolarization, is known as the equilibrium or reversal potential, EFS and EACh respectively. The field-stimulation (FS) and ACh responses underwent simultaneous reversal at about -60 mV, i.e. EFS = EACh. Equilibrium potentials were also determined indirectly by analysis of the responses evoked by each stimulus in the manner described by Trautwein & Dudel (1958). Using this technique the equilibrium potentials of the responses to all three stimuli, field stimulation, ACh and Ad, were again about -60mV, i.e. EFS = EACh = EAd. 7. Both the field-stimulation and ACh responses were abolished by atrophine (10(-6) M) while the response to Ad persisted. Atropine also abolished all spontaneous activity. The alpha-adrenergic blocker phentolamine (10(-5) M) abolished the response to Ad but left the field-stimulation response unaffected. 8. Electrical field stimulation of isolated segments of salivary gland evoked release of endogenous neurotransmitter as a consequence of neural excitation. The technique of field stimulation thus makes it possible to investigate the functional innervation of a gland using the in vitro preparation. In the mouse parotid gland the field stimulus response was mediated by ACh released from parasympathetic nerve endings.

ACh-evoked complex membrane potential changes in mouse submaxillary gland acini. A study employing channel blockers and atropine

The responses in membrane potential and resistance of acinar cells to iontophoretically applied acetylcholine (ACh) were investigated using intracellular micro-electrode recording in superfused segments of mouse submaxillary gland. For measurements of membrane resistance and acetylcholine equilibrium potential (EACh), two micro-electrodes were inserted into neighbouring communicating cells. Current could be injected through one of the electrodes. The pattern of membrane potential change induced by ACh depended on the resting potential. Simple hyperpolarizations were induced at low resting potentials, while biphasic potential changes (depolarization followed by hyperpolarization) or simple depolarizations were observed at relatively high resting potentials. A similar dependence of the ACh induced potential change on the resting potential was obtained in experiments in which the resting membrane potential was set at different levels by injecting direct current and stimulating the same cell with equal doses of ACh. The ACh equilibrium potential ranged widely between -45 and -75 mV. Under special conditions the conversion in response to ACh from a hyperpolarization to depolarization could be obtained without change in resting potential. Small doses of ACh evoked simple depolarization, while medium doses induced biphasic responses and large doses of ACh caused hyperpolarization. The effect of a low concentration of atropine on the response was an initial block of hyperpolarization followed by a secondary block of depolarization. Intracellular injection of TEA ions converted the ACh induced potential response from hyperpolarization to depolarization. Both the depolarizing and hyperpolarizing ACh responses were accompanied by a marked reduction in membrane resistance. The depolarization was abolished by a severe reduction in external Na concentration, while the hyperpolarization was sensitive to alternations in external K concentration. These results indicate that some of the complex responses in submaxillary gland acinar cells to ACh may be explained by the interaction between two different kinds of potential change (Na dependent depolarization and K dependent hyperpolarization).

Rheogenic sodium transport in a tight epithelium, the amphibian skin

1. Intracellular potentials from frog and toad skins were measured to identify rheogenic components of active Na transport across the basolateral membrane. Transcellular current flow and associated R . I-drops were blocked with amiloride or Na-free mucosal solution. 2. The potential difference across the basolateral membrane was found to be hyperpolarized by 18 . 5 +/- 1 . 6 mV above the steady-state value immediately after blockage of apical membrane Na conductance. The hyperpolarization disappeared within 15--25 min. 3. The final steady-state value of 93 . 1 +/- 2 . 5 mV was slightly less than reasonable estimates of the K equilibrium potential. 4. The hyperpolarization could not be observed 3--5 min after addition of ouabain (10(-4) M). 5. Both the magnitude and duration of the hyperpolarization correlate directly with the amount of Na accumulated in the intracellular space. 6. A fraction of the intracellular potential was missing when Na transport was re-established after long term blockage of apical membrane Na entry. It reappeared within 10--20 min. 7. It is suggested that the hyperpolarization is due to rheogenic Na transport across the basolateral membranes. This transport mechanism may contribute some 30--50% of the electrical gradient for passive Na entry across the mucosal membrane. 8. A coupling ratio between pumped fluxes of Na and K of about 2:1 is calculated from the data.

Effect of neural stimulation on acinar cell membrane potentials in isolated pancreas and salivary gland segments

The effect of cholinergic neural excitation by field stimulation on the acinar cell membrane potential was investigated in superfused segments of mouse pancreas and salivary glands (sublingual, submaxillary, and parotid glands). Responses of acinar cells in both exocrine pancreas and salivary glands to the neural excitation obtained by field stimulation were similar to responses previously described in each gland to the externally applied acetylcholine. In the pancreatic acinar cell, electrical field simulation induced depolarization with a latency of 0.3 to 1.2 sec. This depolarization was accompanied by a marked decrease in membrane resistance. The equilibrium potential of the depolarization induced by stimulation was between - 10 and - 20 mV. In the sublingual gland, field stimulation induced depolarization of the acinar cell with a latency of 0.2 to 0.3 sec. The stimulus induced depolarization was block by the addition of atropine. In the submaxillary and parotid glands, field stimulation induced depolarization in some acinar cell and hyperpolarization in other cells. The results support evidence previously presented by Petersen and his colleagues that acetylcholine acts to increase Na+ and K+ or Na+, K+, and Cl- permeabilities in the pancreatic acinar cell and to increase K+ and Na+ permeabilities in the salivary gland [11,24].

Calcium and receptor regulation of radiosodium uptake by dispersed rat parotid acinar cells

1. Dispersed rat parotid acinar cells were used to study the effects of secretagogues on 22Na uptake. 2. Carbachol stimulated 22Na uptake, and caused a net gain in total Na and a loss in total K. These effects were accentuated in the presence of 10(-3) M-ouabain. 3. Substance P, epinephrine and phenylephrine also stimulated 22Na uptake while isoproterenol and angiotensin II did not. 4. The 22Na uptake due to carbachol was inhibited by atropine, procaine or CoCl2; the response to Substance P was inhibited by CoCl2 only. 5. Extracellular Ca was required for stimulation of 22Na uptake by carbachol. Strontium but not Ba could substitute for Ca in supporting 22Na uptake. 6. Uptake of 22Na was stimulated by the divalent cationophore, A-23187, and Ca was required for this effect. 7. It is concluded that activation of Ca influx by muscarinic, alpha-adrenergic or peptide agonists triggers, among other effects, an increased membrane permeability to Na.

Physiological and morphological evidence for coupling in mouse salivary gland acinar cells

Three experimental techniques were employed to examine coupling between acinar cells of the mouse salivary gland. Passage of DC current pulses via intracellular microelectrodes between neighboring cells showed that small ions could be directly passed from one cell to another. Intracellular iontophoresis of the dye Lucifer Yellow CH into a single cell indicated that small molecules could spread by means of intercellular cytoplasmic bridges througout an acinus and, occasionally, into cells of adjacent acini. Freeze-fracture replicas of acinar cell membranes indicated the presence of gap junctions which were correlated with both electrical and dye coupling experiments. Suggestions are made for the function of direct intercellular exchange in salivary secretory cells. The role of electrical coupling in coordination of the activity of different secretory cell types is discussed as one possible function.

Does acetylcholine change the electrical resistance of the basal membrane of secretory cells in eccrine sweat glands?

The present experiment was intended to study whether or not acetylcholine decreases the electrical resistance of the basal membrane of secretory cells in stimulating eccrine secretion of fluid and electrolytes. An isolated segment of the secretory coil of the monkey palm eccrine sweat gland was dissected out in vitro and immobilized in the tip of a constriction pipette. Using a bridge-balanced single glass microelectrode, input impedance of the secretory cell was compared before and after local superfusion of acetylcholine in each cell. The mean input impedance was 27 Momega, which did not significantly change after application of acetylcholine. Between 15 and 30 sec after cessation of acetylcholine superfusion, input impedance increased by 42% and then returned to normal within 60 sec. The current-induced voltage deflection due to intraluminally injected current pulse was measured across both the basal membrane (deltaVb) and the epithelial wall (deltaVt) as qualitative measures of the respective membrane resistances. Both deltaVb and deltaVt increased by about 10%, but their ratio remained unchanged after stimulation with acetylcholine. A Ca++ ionophore, A23187, which is as potent a stimulant of eccrine sweat secretion as acetylcholine in vitro, also failed to change the above two parameters. It was concluded that the decrease in the electrical resistance of the basal membrane of the secretory cells could not be detected in the sweat gland after stimulation with acetylcholine or A23187. The possibility was discussed that the action of acetylcholine at the basal membrane is one of enhancing the activity of the nonconductive pathway rather than the conductive pathway in this exocrine gland.

Parotid acinar cells: ionic dependence of acetylcholine-evoked membrane potential changes

Segments of mouse parotid were placed in a superfusion chamber. Surface acini were impaled by one or two micro-electrodes for measurement of membrane potential and resistance. The acinus under investigation was stimulated by micro-iontophoretic application of acetylcholine (ACh) or adrenaline. Neighbouring acinar cells were electrically coupled. Electrical coupling between acinar cells only occurred within restricted domains probably corresponding to an acinus or a group of acini. Passing direct current through one intracellular electrode, the resting potential of an acinus could be set at desired levels and the dependency of the ACh-evoked potential change on the resting potential investigated. The ACh null potential (initial effect) was about--60 mV. A delayed hyperpolarizing effect of ACh could not be reversed. The initial ACh-evoked potential change was sensitive to alterations in extracellular Na, K and Cl concentration. The delayed ACh-evoked hyperpolarization was blocked by ouabain, exposure to Na-free or K-free solutions. It is concluded that ACh increases mainly K and Na membrane conductance causing K efflux and Na influx with a subsequent Na activation of an electrogenic Na pump.

Membrane potential and resistance changes induced in salivary gland acinar cells by microiontophoretic application of acetylcholine and adrenergic agonists

The effects of microiontophoretic applications of catecholamines and acetylcholine on parotid acinar cell membrane potential and resistance were investigated using intracellular microelectrode recording in superfused segments of mouse parotid or rat submandibular glands. Short pulses of acetylcholine and alpha-adrenergic agonists had similar effects, consisting of a marked decrease in membrane resistance accompanied by an initial depolization or hyperpolarization depending on the level of the resting membrane potential. This initial response was followed by a slow hyperpolarization occurring at a time when the resistance was increasing towards the prestimulation level. The equilibrium potential for the initial potential change caused by excitation of the cholinergic receptors was investigated directly by setting the membrane potential at different levels by injecting direct current and stimulating the same cell repeatedly with equal doses of acetylcholine. The equilibrium potential was found to be about -55 mV. The delayed hyperpolarization could not be reversed by passing hyperpolarizing current, but actually increased in size with higher membrane potentials. The minimum latency of the effect of acetylcholine or alpha-adrenergic agonists was 200-500 msec. Excitation of beta-adrenoceptors caused, after a long latency of several seconds, a small depolarization. Epinephrine induced a combined alpha- and beta-adrenergic response, with the alpha-component predominating. Blocking the alpha-adrenoceptors with phentolamine revealed the beta-adrenergic depolarization, while blocking the beta-adrenoceptors with propranolol caused the components of the alpha-adrenergic response to become more pronounced. All three receptors (alpha- and beta-adrenoceptors and cholinergic receptors) were present in individual acini.

Membrane potential, resistance, and intercellular communication in the lacrimal gland: effects of acetylcholine and adrenaline

1. Intracellular micro-electrode recordings were made from surface acini of mouse exorbital lacrimal glands placed in a Perspex bath through which oxygenated physiological saline solutions were circulated. Two micro-electrodes were inserted into neighbouring communicating cells. Through one of the electrodes, current pulses could be injected. The cells impaled were stimulated by iontophoresis of acetylcholine (ACh), adrenaline or isoprenaline from an extracellular micropipette. 2. During exposure to standard Krebs solution the resting membrane potential was -42.5 mV +/- 1.2 and the resting input resistance 3.3 Momega +/- 0.3. When the tips of the two intracellular micro-electrodes were more than 100 micrometer apart no electrical coupling between two impaled cells could be detected. At intertip distances below about 80 micrometer coupling was frequently observed. In all such cases the coupling ratio was 1. The resting current-voltage relation was almost linear within the membrane potential range of -30 to -80 mV. 3. During exposure to standard Krebs solution the resting membrane potential was -42.5 mV +/- 1.2 and the resting input resistance 3.3 Momega +/- 0.3. When the tips of the two intracellular micro-electrodes were more than 100 micrometer apart no electrical coupling between two impaled cells could be detected. At intertip distances below about 80 micrometer coupling was frequently observed. In all such cases the coupling ratio was 1. The resting current-voltage relation was almost linear within the membrane potential range of -30 to -80mV. 3. During exposure to standard Krebs solution short iontophoretic pulses of ACh or adrenaline caused fully reversible hyperpolarizations accompanied by marked reduction of surface cell membrane resistance and membrane time constant. The effects of ACh were blocked by atropine (1.4 x 10(-6)M). Iontophoresis of isoprenaline never had any detectable effect on membrane potential or resistance. 4. Applying de- or hyperpolarizing direct currents through one of the two intracellular micro-electrodes the effect of ACh or adrenaline could be observed at different lvels of resting potential. Depolarizing the acinar cell membrane resulted in an enhanced stimulant-evoked hyperpolarization whereas hyperpolarizing the acinar cell membrane resulted in a reduction, and at potentials more negative than -60 mV in a reversal of the stimulant-evoked potential change. The ACh equilibrium potential (EACh) under control conditions was -56.6 mV +/- 1.1 and EAdrenaline was -61.4 mV +/- 1.0. 5. Replacing the control superfusion solution by a Clfree sulphate solution resulted in an immediate shift of EACh towards more negative values. At steady state in the Cl-free solution the resting input resistance was 6.8 Momega +/- 1.3 EACh was -95.9 mV +/- 3.4. 6. Reducing [K]o from the usual 4.7 to 1.0 mM resulted in an immediate marked increase in the amplitude of ACh-evoked hyperpolarization whereas increasing [K]o to 10 mM almost abolished the ACh-evoked potential, but not resistance change. 7...

Electrical coupling and dye transfer between acinar cells in rat salivary glands

1. Adjacent acinar cells in isolated rat parotid and submaxillary glands were found to be electrically coupled in greater than 90% of the pairs tested. 2. Cells injected with fluorescein or procion yellow showed transfer of the dyes to their coupled neighbours. While not all coupled cells exchanged dye, exchange occurred only between coupled cells. 3. In experiments using three micro-electrodes, coupled acinar cells from parotid gland were found to have a mean coupling coefficient of 0.69 +/- 0.04. This value is higher than those reported for most other vertebrate epithelial systems. 4. Membrane damage sufficient to reduce the occurrence of coupling between cells by 97% lowered the transmembrane potential by only 13%. This would indicate that in this system membrane potential may not be the most sensitive indicator of cell damage. 5. The significance of the presence of electrical coupling and cell-to-cell transfer of small tracer molecules is discussed in relation to salivary gland structure and possible functional consequences.

Salivary gland K+ transport: in vivo studies with K+-specific microelectrodes

Stimulation-induced transport of K+ in the submandibular salivary gland of cats and dogs anesthetized with pentobarbital was studied with an extracellular K+-specific microelectrode. Electrical stimulation of the para-sympathetic chorda-lingual nerve caused a rapid transient increase in extracellular K+ concentration from 2.2 to 18.7 meq/liter in the cat and from 2.3 to 15.2 meq/liter in the dog. Eventually the K+ concentration fell below the prestimulatory level, indicating uptake of K+ by the gland cells. In case of prolonged stimulation (2-10 min), the uptake began during stimulation. However, a further reduction in extracellular K+ concentration occurred upon cessation of stimulation, a result that demonstrated that the cells did not fully recover their K+ ,content during stimulation. The latency of the release of K+, defined as the time from the beginning of stimulation to the point at which, the K+-specific microelectrode signal had increased by 2 mV, was 0.6 s in the cat and 0.8 s in the dog. Because these are overestimates of the "true" latencies, we conclude that the K+ release begins simultaneously with the hyperpolarization of the acinar cell membrane.

Membrane potential of mitochondrial measured with microelectrodes

The membrane potentials of giant mitochondria from cuprizone-fed mice were found to be independent of metabolic state. Experiments are described in which the presence of the microelectrodes in the inner mitochondrial space, and the metabolic viability of the impaled mitochonidra, are validated.

Increase in membrane conductance by adrenaline in parotid acinar cells

It is shown that excitation of the alpha- or beta-adrenoceptors in mouse parotid acinar cells causes a marked reduction of surface cell membrane resistance. The alpha-adrenoceptor induced membrane effect is an increase in K conductance. The beta-adrenoceptor induced membrane effect does not seem to be mediated by cyclic AMP.

Pancreatic acinar cells: effect of acetylcholine, pancreozymin, gastrin and secretin on membrane potential and resistance in vivo and in vitro

1. Intracellular recordings of membrane potential and input resistance have been made in vivo and in vitro from the exocrine acinar cells of rat pancreas using indwelling glass micro-electrodes. 2. The resting cell membrane potential and input resistance in the in vivo experiments were not markedly different from the values obtained in the in vitro experiments. The effect of both acetylcholine (ACh) and pancreozymin (CCK-Pz) on the pancreas in vivo as well as in vitro was to reduce both the acinar cell membrane potential and the input resistance narkedly. The amplitude of the evoked depolarization and the change in input resistance evoked by supramaximal stimuli were of the same magnitude in both types of preparations. 3. Gastrin had an effect on the acinar cell potential and resistance which was indistinguishable from that of CCK-Pz or ACh. The effect of gastrin or CCK-Pz was, in contrast to that of ACh, not influenced by the presence of atropine. The reversal potential for the gastrin evoked potential change was about -20 mV. 4. Secretin in doses producing maximal volume secretion in vivo had no effect on acinar cell membrane potential and input resistance. 5. Dibutyryl cyclic AMP (5mM) and cyclic GMP (1mM) had no effect on cell membrane potential or resistance. 6. It is concluded that the in vitro superfused pancreas segment preparation is a useful model system in electrophysiological studies since it functions essentially as the in vivo preparation. In contrast to both gastrin and CCK-Pz, secretin has no effect on the bioelectrical properties of the acinar cells, indicating that there are no physiologically important secretin receptors in rat acinar cells.

Membrane potential and input resistance in acinar cells from cat and rabbit submaxillary glands in vivo: effects of autonomic nerve stimulation

1. Membrane potential and input resistance measurements were made from acinar cells of cat and rabbit submaxillary glands in vivo, using intracellular glass micro-electrodes.2. The mean resting cell membrane potential was higher than previously reported, but ranged widely from -15 to -80 mV.3. Single shock electrical stimulation of the parasympathetic nerve fibres evoked characteristic potential changes. In some cases monophasic hyperpolarizations, in others biphasic responses (depolarization - hyperpolarization) were observed.4. The latency of the hyperpolarizing response was considerably longer (300-550 msec) than the latency of the biphasic response (about 150 msec).5. Hyperpolarizing and biphasic responses could be observed in the same cell at different levels of membrane potential. The initial depolarization of the biphasic response was dependent on the magnitude of the resting potential in such a manner that it was very small or absent at the lowest potentials and increased gradually with increasing level of the resting potential.6. Single-shock stimulation of the sympathetic nerve fibres to the gland did not evoke any response. In the cat, repetitive stimulation evoked hyperpolarizing or biphasic responses similar to those seen after repetitive stimulation of the parasympathetic nerve fibres. In the rabbit small hyperpolarizations were seen in a few cells only; mostly there was no response. Repetitive stimulation of the parasympathetic nerve fibres to the rabbit submaxillary gland evoked complex potential changes mostly of the depolarization-hyperpolarization type.7. Both single shock and repetitive stimulation of the parasympathetic nerve fibres evoked marked reductions in cell input resistance. In the hyperpolarizing cell type the conductance change sometimes preceded the potential change whereas they always occurred simultaneously in the biphasic cell type.8. It is concluded that both the hyperpolarizing and the biphasic secretory potentials are derived from the same type of acinar cells. The neurotransmitter released by the parasympathetic nerve endings (ACh) acts on the acinar cell membrane by increasing the ion permeability.