The effect of glucagon on the liver cell membrane potential

Hepatocyte membrane potential regulates serum insulin and insulin sensitivity by altering hepatic GABA release

Hepatic lipid accumulation in obesity correlates with the severity of hyperinsulinemia and systemic insulin resistance. Obesity-induced hepatocellular lipid accumulation results in hepatocyte depolarization. We have established that hepatocyte depolarization depresses hepatic afferent vagal nerve firing, increases GABA release from liver slices, and causes hyperinsulinemia. Preventing hepatic GABA release or eliminating the ability of the liver to communicate to the hepatic vagal nerve ameliorates the hyperinsulinemia and insulin resistance associated with diet-induced obesity. In people with obesity, hepatic expression of GABA transporters is associated with glucose infusion and disposal rates during a hyperinsulinemic euglycemic clamp. Single-nucleotide polymorphisms in hepatic GABA re-uptake transporters are associated with an increased incidence of type 2 diabetes mellitus. Herein, we identify GABA as a neuro-hepatokine that is dysregulated in obesity and whose release can be manipulated to mute or exacerbate the glucoregulatory dysfunction common to obesity.

Two-probe microfluorometry estimation of transmembrane potential (ΔΨ(p)) slight changes in individual hepatocytes under short-term hormone action

Early events in individual hepatocytes of rat activated by adrenaline (10(-6)M) and phenylephrine (10(-5)M) have been investigated by quantitative image microfluorometry and microspectrofluorometry. Cationic DiOC2 and anionic SqSC4 probes have been used for image analysis and transmembrane potential (ΔΨ p) estimation in real-time studies. Fluorescence spectra resulting from the accumulation of dyes in single cells were recorded. Based on the mean fluorescence intensity, the magnitude of ΔΨ p was calculated by Nernst equation adapted for lipophilic cationic probes. DiOC2 has revealed that both hormones induce biphasic hyperpolarization of hepatocytes membrane with α-agonist phenylephrine causing ΔΨ p changes at higher amplitude. The first increase of ΔΨ p within 2 and 5 min (ΔΔΨ p = -8.6 ± 4.2 mV) apparently related to Na(+)/K(+)-ATPase activation by the Ca(2+)-mobilizing hormone. The second peak of hyperpolarization (ΔΔΨ p = -13.2 ± 3.2 mV) between 25 and 30 min, after a transient decrease of ΔΨ p (ΔΔΨ p = 10.9 ± 4.3 mV) over 15 min experiment, probably is mediated by phenylephrine stimulating action on K(+)-channels. K(+) channel blocker (Ba(2+) or 4-aminopyridine) as well as elevating of extracellular K(+) prevented the hyperpolarization. Modulation of PLD-dependent signal transduction pathway by 0.4% butanol had a weak influence on the first increase of ΔΨ p but it abolished the second phase of hyperpolarization. That points to PLD involvement in the ΔΨ p fluctuations mediated by K(+)-channels in response to phenylephrine. Based on SqSC4, fluorescent parameters estimation of relative changes of ΔΨ p revealed similar character of time dependence with two phases of hyperpolarization. Synchronic fluctuation of ΔΨ p determined by oppositely charged probes demonstrate that the quantitative microfluorometry allows to evaluate slight ΔΨ p changes separately from ΔΨ m in non-excitable individual cells at the short-term hormone action.

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.

Pancreatic signals controlling food intake; insulin, glucagon and amylin

The control of food intake and body weight by the brain relies upon the detection and integration of signals reflecting energy stores and fluxes, and their interaction with many different inputs related to food palatability and gastrointestinal handling as well as social, emotional, circadian, habitual and other situational factors. This review focuses upon the role of hormones secreted by the endocrine pancreas: hormones, which individually and collectively influence food intake, with an emphasis upon insulin, glucagon and amylin. Insulin and amylin are co-secreted by B-cells and provide a signal that reflects both circulating energy in the form of glucose and stored energy in the form of visceral adipose tissue. Insulin acts directly at the liver to suppress the synthesis and secretion of glucose, and some plasma insulin is transported into the brain and especially the mediobasal hypothalamus where it elicits a net catabolic response, particularly reduced food intake and loss of body weight. Amylin reduces meal size by stimulating neurons in the hindbrain, and there is evidence that amylin additionally functions as an adiposity signal controlling body weight as well as meal size. Glucagon is secreted from A-cells and increases glucose secretion from the liver. Glucagon acts in the liver to reduce meal size, the signal being relayed to the brain via the vagus nerves. To summarize, hormones of the endocrine pancreas are collectively at the crossroads of many aspects of energy homeostasis. Glucagon and amylin act in the short term to reduce meal size, and insulin sensitizes the brain to short-term meal-generated satiety signals; and insulin and perhaps amylin as well act over longer intervals to modulate the amount of fat maintained and defended by the brain. Hormones of the endocrine pancreas interact with receptors at many points along the gut-brain axis, from the liver to the sensory vagus nerve to the hindbrain to the hypothalamus; and their signals are conveyed both neurally and humorally. Finally, their actions include gastrointestinal and metabolic as well as behavioural effects.

Leukotriene and purinergic receptors are involved in the hyperpolarizing effect of glucagon in liver cells

The pancreatic hormone glucagon hyperpolarizes the liver cell membrane. In the present study, we investigated the cellular signalling pathway of glucagon-induced hyperpolarization of liver cells by using the conventional microelectrode method. The membrane potential was recorded in superficial liver cells of superfused mouse liver slices. In the presence of the K+ channel blockers tetraethylammonium (TEA, 1 mmol/l) and Ba2+ (BaCl2, 5 mmol/l) and the blocker of the Na+/K+ ATPase, ouabain (1 mmol/l), no glucagon-induced hyperpolarization was observed confirming previous findings. The hyperpolarizing effect of glucagon was abolished by the leukotriene B4 receptor antagonist CP 195543 (0.1 mmol/l) and the purinergic receptor antagonist PPADS (5 micromol/l). ATPgammaS (10 micromol/l), a non-hydrolyzable ATP analogue, induced a hyperpolarization of the liver cell membrane similar to glucagon. U 73122 (1 micromol/l), a blocker of phospholipase C, prevented both the glucagon- and ATPgammaS-induced hyperpolarization. These findings suggest that glucagon affects the hepatic membrane potential partly by inducing the formation and release of leukotrienes and release of ATP acting on purinergic receptors of the liver cell membrane.

Ionic and pharmacologic characteristics of epithelial cells in a semi-intact preparation of the rat ventral prostate gland

BACKGROUND

The essential ionic and pharmacologic characteristics of epithelial cells within the ducts of the prostate gland are not well known.

METHODS

Experiments were carried out on segments of ventral prostate glands from adult male rats. By using sharp microelectrodes, intracellular epithelial cell and transepithelial (lumen) potentials were recorded in response to ionic substitution and application of ion channel blockers, hormones, and other pharmacologic agents related to prostatic function.

RESULTS

Membrane permeabilities to K(+), Na(+), and Cl(-) were found to account for approximately 43% of the resting membrane potential, whereas some 39% was likely to be metabolic in origin. The membrane potential also responded to adrenaline, acetylcholine, insulin, prolactin, testosterone, nerve growth factor, and nitric oxide. The lumen potential was found to be particularly sensitive to citrate, prolactin, and testosterone.

CONCLUSION

It was concluded that the basal membrane potential of prostatic epithelial cells is associated with a relatively high Na(+):K(+) permeability ratio and metabolic dependence. The hormonal and pharmacologic sensitivity observed is consistent with the functional characteristics of the prostate gland.

The contribution of afferent signals from the liver to metabolic regulation during exercise

The crucial role of the liver as the only organ to produce glucose used by skeletal muscle during exercise is well known. Since hepatic glucose production is central to blood glucose homeostasis during exercise, it has been postulated that the liver may inform the central nervous system and other organs of its diminishing capacity to produce glucose from glycogen, before blood glucose falls. The sensory role of the liver during exercise would be similar to its role in the control of food intake. As a consequence, the experimental approaches used to test the hypothesis that afferent signals from the liver contribute to metabolic regulation during exercise are inspired by those used to test the same hypothesis in the regulation of food intake. In the present review, two questions are addressed. The existing evidence for the liver's sensory influence on metabolic adjustments to exercise is first reviewed; the nature of the initiating stimuli for the afferent contribution of the liver to physical exercise is discussed thereafter. The hypothetical construct upon which rests the contribution of the liver's afferent signals to metabolic regulation during exercise is that a decrease in liver glycogen or a related metabolic intermediate is sensed by the liver, and the signal is transduced to the central nervous system, most likely through the afferent activity of the hepatic vagus nerve, where it contributes to the orchestration of the metabolic and hormonal responses to exercise. Support in favour of this construct comes mainly from the demonstration that sectioning of the hepatic vagus nerve attenuates the normal hormonal response to exercise. It seems that the liver-glucagon axis is particularly responsive to this reflex activation. In other respects, the hepatic mechanism responsible for linking the metabolic activity in the liver to an afferent signal capable of regulating the metabolic response to exercise remains speculative. Substrates or derivatives of substrate oxidation, energy-related compounds (ATP and Pi), or changes in cell volume may all be related to changes in transmembrane potential in the liver cell, which according to the "potentiostatic" theory would determine the afferent vagal activity.

Depolarization of the liver cell membrane by metformin

Metformin (1,1-dimethylbiguanide; MET) is used in the treatment of type 2 diabetes mellitus. MET's antihyperglycemic action depends at least in part on its inhibitory effect on hepatic gluconeogenesis. As to gluconeogenesis from amino acids (e.g. L-alanine), this is associated with an inhibition of L-alanine uptake into hepatocytes. Since this uptake is mediated by an electrogenic transport mechanism, the aim of the present study was to investigate whether MET has an influence on the liver cell membrane potential which might explain its inhibitory effect on L-alanine uptake. The experiments were performed in vivo in anesthetized rats and in vitro using superfused mouse liver slices with the conventional microelectrode technique. In vivo, MET (160 mg/kg intraperitoneally (i.p.)) significantly depolarized (dV) the liver cell membrane by 6 mV. MET (1 mmol/l) also depolarized the liver cell membrane in vitro (e.g. 15 min after start of superfusion: dV=8 mV). MET's effect was at least partly reversible. Glucagon (10(-7) mol/l), which hyperpolarized the liver cell membrane, abolished MET's effect. Further, the MET-induced depolarization was completely absent during superfusion with low Cl(-) ([Cl(-)]=27 mmol/l) medium, and significantly attenuated by the Cl(-) channel blocker NPPB (25 micromol/l). While MET's effect was only somewhat attenuated by blockade of the Na(+)/K(+)/2Cl(-) cotransporter or by superfusion with (HCO(-)(3)-free) HEPES buffer, the carboanhydrase blocker acetazolamide (1 mmol/l) or blockade of the HCO(-)(3)/Cl(-) exchanger by DIDS (100 micromol/l), which, however, also blocks Cl(-) channels, abolished its effect. The depolarization of the liver cell membrane by MET was unaffected by a blockade of K(+) channels with Ba(2+), a blockade of the Na(+)/K(+) pump or superfusion with low Na(+) medium ([Na(+)]=26 mmol/l). According to these results, the MET-induced depolarization of the liver cell membrane could be due to an activation of the Cl(-)/HCO(-)(3) exchanger and thus depend on intracellular HCO(-)(3) formation. This activation could then lead to a disturbance of the equilibrium between intra- and extracellular Cl(-) and therefore to an enhanced Cl(-) efflux via Cl(-) channels. It is plausible that the depolarizing effect induced by MET is associated with its inhibitory effect on gluconeogenesis by inhibiting uptake of L-alanine and other amino acids into hepatocytes.

Electrophysiological recordings from the rat prostate gland in vitro: identified single-cell and transepithelial (lumen) potentials

OBJECTIVE

To develop a preparation for the in vitro maintenance of the rat prostate gland and thus allow intracellular and transepithelial voltage measurements.

MATERIALS AND METHODS

Ventral prostate glands from male rats were dissected free of connective tissue, separated into smaller lobes and maintained in vitro at 30 degrees C. Voltages were recorded with sharp micropipettes in identified cellular and luminal compartments, differentiated by several electrophysiological and histological parameters, including intracellular staining.

RESULTS

Intracellular epithelial membrane potentials (median -40 mV) and transepithelial or luminal potentials (mean -4.2 mV) were recorded successfully. Luminal epithelial cells were dye-coupled. Prostate tissue could be maintained in vitro with no apparent electrophysiological or structural deterioration for up to approximately 7 h.

CONCLUSION

Rat prostate tissue can be successfully maintained in vitro and electrophysiological recordings made from identified cellular compartments.

Effect of hepatic portal injection of ouabain on the hepato-sympathoadrenal reflex

The purpose of the present investigation was to evaluate the effects of an intraportal injection of ouabain (2 mg/kg), an inhibitor of the sodium-potassium pump, on plasma catecholamine response in unrestrained normally fed rats with and without an intact hepatic vagus nerve. Three groups of rats were submitted to two injection conditions each. Hepatic vagotomized (HV) rats were randomly injected with ouabain or saline (0.9%) in the portal vein. Sham-operated rats were either injected with ouabain or saline in the portal or jugular vein. Ouabain or saline were injected at 0 min and again at 20 min. Plasma catecholamines were measured before the first injection and 15 min after each injection. Blood glucose concentrations were significantly (p < 0.01) increased by the ouabain injection as compared with basal values and saline-injected groups. The hyperglycemic effect of ouabain was not affected by the hepatic vagotomy or the site of infusion. The injection of ouabain, either into the portal or the jugular vein and either after HV or the sham operation, resulted in a significant (p < 0.01) increase in epinephrine levels as compared with saline-infused rats. Plasma norepinephrine levels were significantly (p < 0.05) increased after the second intraportal injection of ouabain in both HV and sham-operated groups. However, the injection of ouabain into the jugular vein did not change the plasma norepinephrine levels. The latter observation indicates a specific action of ouabain in the liver on the sympathetic activity.

Role of the liver in the metabolic control of eating: what we know--and what we do not know

Profound metal-related changes in the supply of metabolites to t he liver and in the hepatic metabolism occur, and there is ample evidence that neural signals from hepatic metabolic sensors can affect eating. Hepatic afferent nerves presumably represent glucosensors which contribute to the control of eating by monitoring their own glucose utilization. Yet, the nature of the putative sensors that respond to the oxidation of other metabolites than glucose had not been identified. ATP and sodium pump activity may link hepatic oxidative metabolism and membrane potential, because hepatic phosphate-trapping by 2,5-anhydro-mannitol, and inhibition of sodium pump activity by ouabain is associated with a stimulation of eating. Hepatocyte membrane potential is also subject to changes in transmembranal potassium flow through volumetrically controlled membranal potassium channels. Yet it is unknown if and how hepatocytes are linked to afferent nerves. It is also unclear how the effects of glucagon and insulin fit into the hepatic metabolic control of eating. Glucagon appears to induce satiety through its actions in the liver, but the involved mechanism is still unclear. Recent studies suggest that insulin, which has mainly been explored as a centrally acting long-term satiety signal, has an immediate effect on meal size, but is presently unknown whether an hepatic action of insulin is involved.

Pancreatic glucagon signals postprandial satiety

The hypothesis that prandial increases in circulating pancreatic glucagon initiates an important peripheral satiety signal is reviewed. Glucagon administration at the beginning of meals reduces the size of test meals in animals and humans and reduces the size of spontaneous meals in rats. Exogenous glucagon may also interact synergistically with cholecystokinin to inhibit feeding. These appear to be satiety effects because they are behaviorally specific in rats and subjectively specific in humans. Glucagon's pharmacological satiety effect is complemented by compelling evidence for a necessary contribution of endogenous glucagon to the control of meal size: administration of glucagon antibodies increases both test and spontaneous meal size in rats. Under many, but not all, conditions exogenous glucagon's satiety effect appears to originate in the liver and to be relayed to the brain via hepatic vagal afferents. Analysis of the central processing of this signal, however, has barely begun. How glucagon changes are transduced into neural afferent signals also remains an open question. The only hypothesis that has been extensively tested is that stimulation of hepatic glucose production initiates the satiety signal, but this is neither convincingly supported nor clearly rejected by currently available data. It is also not yet clear whether glucagon contributes to some forms of obesity or has potential use as a therapeutic tool in the control of eating disorders. Of the several proposed controls of hunger and satiety, glucagon appears to be one of the most likely to be physiologically relevant. This encourages further analysis of its behavioral characteristics, its neural mechanisms, and its clinical potential.

[Regulation of food intake]

Regulation of food intake is commonly treated as a negative feedback-loop. Hunger and/or appetite lead man and animals to ingest food. The subsequent meal-contingent activation of pre- and postabsorptive mechanisms then leads to satiety. The activation of oral and gastrointestinal chemo- and mechanoreceptors is important on the preabsorptive site. The gastrointestinal hormone cholecystokinin may also have a physiological satiety effect. Preabsorptive satiety mechanisms are influenced by the rate of gastrointestinal transit. The pancreatic hormone glucagon, which is released during meal taking, and various metabolites contribute to the postabsorptive regulation of food intake through activation of hepatic chemoreceptors, which are connected to the brain via predominantly vagal afferents. In addition, glucoreceptors in the brain, in particular in the nucleus of the solitary tract, contribute to food intake regulation by monitoring blood glucose concentration or, more specifically, glucose utilization. The nucleus of the solitary tract, which relays vagal afferents from gut and liver and also gustatory afferents, projects to the hypothalamus and to other forebrain structures. In this neural network the informations from the periphery are integrated by various neurotransmitters and neuropeptides, but the exact role of the substances involved is not fully understood yet. Body weight and, hence, body fat presumably affects feeding through modulation of a postabsorptive mechanism.

A whole-cell and single-channel study of the voltage-dependent outward potassium current in avian hepatocytes

Voltage-dependent membrane currents were studied in dissociated hepatocytes from chick, using the patch-clamp technique. All cells had voltage-dependent outward K+ currents; in 10% of the cells, a fast, transient, tetrodotoxin-sensitive Na+ current was identified. None of the cells had voltage-dependent inward Ca2+ currents. The K+ current activated at a membrane potential of about -10 mV, had a sigmoidal time course, and did not inactivate in 500 ms. The maximum outward conductance was 6.6 +/- 2.4 nS in 18 cells. The reversal potential, estimated from tail current measurements, shifted by 50 mV per 10-fold increase in the external K+ concentration. The current traces were fitted by n2 kinetics with voltage-dependent time constants. Omitting Ca2+ from the external bath or buffering the internal Ca2+ with EGTA did not alter the outward current, which shows that Ca2+-activated K+ currents were not present. 1-5 mM 4-aminopyridine, 0.5-2 mM BaCl2, and 0.1-1 mM CdCl2 reversibly inhibited the current. The block caused by Ba was voltage dependent. Single-channel currents were recorded in cell-attached and outside-out patches. The mean unitary conductance was 7 pS, and the channels displayed bursting kinetics. Thus, avian hepatocytes have a single type of K+ channel belonging to the delayed rectifier class of K+ channels.

Sodium-dependent taurocholate uptake by isolated rat hepatocytes occurs through an electrogenic mechanism

The uptake mechanism for the bile salt, taurocholate, by the liver cell is coupled to sodium but the stoichiometry is controversial. A one-to-one coupling ratio would result in electroneutral transport, whereas cotransport of more than one sodium ion with each taurocholate molecule cause an electrogenic response. To better define the uptake of this bile salt, we measured the effect of taurocholate on the membrane potential and resistance of isolated rat hepatocytes using conventional microelectrode electrophysiology. The addition of 20 microM taurocholate caused transient but significant depolarization accompanied by a significant decrease in membrane resistance. The electrical effect induced by taurocholate mimicked that induced by L-alanine (10 mM), the uptake of which is known to occur through an electrogenic, sodium-coupled mechanism. The sodium dependence of taurocholate-induced depolarization was further confirmed by: (1) replacing Na+ with choline +, and (2) preincubating cells with ouabain (2 mM) or with the Na+-ionophore, gramicidin (25 micrograms/ml); both suppressed the electrogenic response. Further, cholic acid, which inhibits sodium-coupled taurocholate uptake in hepatocytes, inhibited taurocholate evoked depolarization. These results support the hypothesis that sodium-coupled taurocholate uptake by isolated hepatocytes occurs through an electrogenic process which transports more than one Na+ with each taurocholate molecule.

Evidence for a role of the sodium pump of hepatocytes in the control of food intake

To test the hypothesis that the sodium pump of hepatocytes is involved in the control of food intake, we investigated the effect of ouabain, an inhibitor of the sodium pump, on feeding in intact and hepatic vagotomized rats. Ouabain (2 mg/kg b.wt.), injected intraperitoneally during the bright phase of the lighting cycle, stimulated feeding in intact and sham-vagotomized rats, but not in hepatic vagotomized rats. Atropinization did not block ouabain's hyperphagic effect. Ouabain did not affect portal blood glucose level. Rats started to eat sooner than normal when ouabain was injected, while their meal size and duration was unchanged. The results are consistent with a role of the sodium pump of hepatocytes in the control of food intake.

Short-term stimulation of Na+-dependent amino acid transport by dibutyryl cyclic AMP in hepatocytes. Characteristics and partial mechanism

The short-term protein-synthesis-independent stimulation of alanine transport in hepatocytes was further investigated. Cyclic AMP increased the Vmax. of alanine transport. Amino acid transport via systems A, ASC and N was stimulated. A good correlation was found between the initial rate of transport and the cell membrane potential as calculated from the distribution of Cl-. Cyclic AMP increased the rate of alanine transport, stimulated Na+/K+ ATPase (Na+/K+-transporting ATPase) activity and caused membrane hyperpolarization. The time courses and cyclic AMP dose-dependencies of all three effects were similar. Ouabain abolished the effect of cyclic AMP on Cl- distribution and on transport of alanine. The effect of cyclic AMP on alanine transport and Cl- distribution was mimicked by the antibiotic nigericin; the effect of nigericin was also abolished by ouabain. It is concluded that the effect of cyclic AMP on transport is mediated via membrane hyperpolarization. It is suggested that the primary action of cyclic AMP is to increase the activity of an electroneutral Na+/K+-exchange system in the liver cell plasma membrane, thus hyperpolarizing the membrane by stimulating the electrogenic Na+/K+ ATPase.

Isolated rat hepatocyte couplets: a primary secretory unit for electrophysiologic studies of bile secretory function

Hepatocyte couplets were isolated by collagenase perfusion from rat liver. Between adjacent cells, the bile canaliculus forms a closed space into which secretion occurs. As in intact liver, Mg2+-ATPase is localized at the canalicular lumen, the organic anion fluorescein is excreted, and secretion is modified by osmotic gradients. By passing a microelectrode through one cell into the canalicular vacuole, a transepithelial potential profile was obtained. In 27 cell couplets the steady-state intracellular (-26.3 +/- 5.3 mV) and intracanalicular (-5.9 +/- 3.3 mV) potentials were recorded at 37 degrees C with reference to the external medium. Input resistances were determined within the cell (86 +/- 23 M omega) and in the bile canalicular lumen (32 +/- 17 M omega) by passing current pulses through the microelectrode. These data define electrical driving forces for ion transport across the sinusoidal, canalicular, and paracellular barriers and indicate ion permeation across a leaky paracellular junctional pathway. These findings indicate that the isolated hepatocyte couplet is an effective model for electrophysiologic studies of bile secretory function.

Electrophysiological study of single Leydig cells freshly isolated from rat testis. I. Technical approach and recordings of the membrane potential in standard solution

Single Leydig cells were isolated from rat testis by a collagenase digestion procedure and purified through a 21,000 g self generated densities gradient of 35% Percoll. A method including collagen and fibronectin was proposed to attach freshly prepared Leydig cells to the bottom of plastic Petri dishes. Four hours after the isolation of the cells, it was simultaneously possible to determine their membrane potential by a standard electrophysiological technique using intracellular microelectrodes and to judge cellular integrity by direct microscopic observations. In standard Earle's solution, changes of membrane potentials appeared to be biphasic. On 198 impaled cells, 18 +/- 1 S after the impalement was effective, the membrane potential reached a most negative value (MP1) (-37.6 +/- 0.7 mV), followed by a gradual depolarization to a steady state (MP2) (-25.1 +/- 0.6 mV) which remained constant for a few minutes. In standard Earle's solution, the membrane resistance was low or decreasing towards the most negative potential, then it increased towards the steady potential. At this state, the average value of the cell input resistance was 65.9 +/- 6.0 M omega (n = 16). No action potential was observed either in standard Earle's solution or under a depolarizing current state. It was concluded that the electrophysiological characteristics of the Leydig cell are similar to those of fibroblasts and macrophages, three types of cells with the same mesenchymal origin, present in the interstitial tissue of the rat testis. But the resting potential of the Leydig cell is higher and this secreting cell does not elicit hyperpolarizing oscillations at the steady state, under mechanical or electrical stimuli.

Electrophysiological studies on the cultured cells obtained from transplantable pancreatic carcinoma in Syrian golden hamsters

A pancreatic ductal carcinoma was established as a transplantable tumor line in an inbred strain of Syrian golden hamsters. Intracellular recordings of membrane potentials and input resistance were made from cultured cells obtained from the transplanted tumors using indwelling glass microelectrode. The mean value of the resting membrane potential was -46.5 +/- 1.8 mV (S.E.) (n = 13), while the mean resting input resistance was 21.2 +/- 4.3 M omega (S.E.) (N = 13). Dibutyryl cyclic AMP (2 X 10(-3)M) caused a marked hyperpolarization of about 30 mV accompanied by a reduction of input resistance. The transplantable tumor and its cultured cell line developed in this study have demonstrated their effectiveness as a reliable experimental model for use in pancreatic cancer research.

Glucagon stimulation of hepatic Na+, K+-ATPase

In the perfused rat liver administration of glucagon was shown to result in a transiently increased uptake of K+, indicating the possible involvement of the Na+, K+-ATPase. Direct measurement of the activity of Na+, K+-ATPase revealed a two-fold stimulation of the enzyme by glucagon. The effect of glucagon on the activity of the enzyme was immediate. Simultaneously with the increase in the activity of the Na+, K+-ATPase, the activity of Mg2+-ATPase decreased. In order to evaluate whether the activation of the Na+, K+-ATPase by glucagon is related to the metabolic effects of the hormone, experimental conditions known to interfere with the activity of the enzyme were employed and glucagon stimulation of Ca2+-efflux, mitochondrial metabolism and gluconeogenesis were measured. K+-free perfusate, high K+ perfusate or ouabain interfered to varying degrees with the glucagon stimulation of these responses. The combination of K+-free perfusate and ouabain almost completely abolished the glucagon stimulation of all three parameters. These results demonstrate the glucagon stimulation of Na+, K+-ATPase and raise the possibility that the activation of the enzyme by glucagon might be a necessary link for the manifestation of its metabolic effects.

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

The effect of microionophoretic application of isoprenaline on membrane potential and resistance of mouse parotid acinar cells was investigated. For measurements of membrane resistance and the isoprenaline equilibrium potential (Eiso), two microelectrodes were inserted into neighbouring communicating cells. Passing direct current through one of these electrodes, the resting potential could be set at desired levels and Eiso was determined by plotting the relation between the size of the isoprenaline-evoked potential change and the resting potential. Simple depolarizations were found at relatively high resting potentials, while biphasic potential changes in response to isoprenaline (hyperpolarization followed by depolarization) were observed at low resting potentials. Both depolarizing and hyperpolarizing responses to isoprenaline were accompanied by a reduction of membrane resistance. The isoprenaline equilibrium potential in the initial phase of the response was about -53 mV, but had a value of about -24mV in the delayed phase. The initial isoprenaline-evoked potential change was sensitive to alterations in extracellular Na, K and Cl concentrations. The delayed depolarizing response to isoprenaline was markedly reduced by replacing extracellular Na by Tris or extracellular Cl by SO4. These results indicate that isoprenaline opens up conductance pathways permeable to Na and K.

Isoprenaline- and noradrenaline-induced hyperpolarization of guinea-pig liver cells

1 Effects of pretreatment with isoprenaline (Isop) or noradrenaline (NA) and various ionic environments on the NA-induced or Isop-induced hyperpolarization of guinea-pig liver cells were investigated by means of a microelectrode technique.2 NA (5.9 x 10(-6) M) decreased the membrane resistance, and hyperpolarized the membrane with or without generation of an initial transient small depolarization. The NA-induced initial depolarization was not dependent on the membrane potential and was increased by Isop (4.0 x 10(-6) M) or glucagon (10(-7) M).3 In Ca-free solution, the NA-induced hyperpolarization became transient and a continuous depolarization followed in the presence of NA. Repetitive application of NA resulted in a complete disappearance of the NA-induced hyperpolarization and was replaced by a slowly developing depolarization with or without generation of the initial transient depolarization. In excess [Ca](o), the NA or Isop-induced hyperpolarization was increased.4 Both Isop and glucagon hyperpolarized the membrane and decreased the membrane resistance, to various degrees. Repetitive application of Isop or glucagon resulted in the disappearance of both Isop and glucagon-induced hyperpolarizations. Pretreatment with NA not only resulted in a recovery of both Isop and glucagon-induced hyperpolarizations, but also extensively enhanced the hyperpolarization.5 After pretreatment with Isop, the NA-induced hyperpolarization was decreased in amplitude and duration and was followed by a slowly developing depolarization. After repetitive application of Isop, NA produced only depolarization of the membrane, and in these conditions, Isop, glucagon or ATP also depolarized the membrane. These depolarizations were reversed to hyperpolarizations by pretreatment with excess [Ca](o).6 After treatment with Na-deficient solution, NA depolarized the membrane and decreased the membrane resistance. Excess [Ca](o) restored the NA-induced membrane response from one of depolarization to one of hyperpolarization.7 In the presence of tetraethylammonium 10mM, the NA-induced hyperpolarization became transient or ceased and depolarization occurred with a reduction in the membrane resistance.8 It is postulated that both NA and Isop increase the free [Ca](i) by releasing bound Ca from storage sites and consequently an increase in K conductance follows. NA but not Isop promotes Ca-influx which replenishes the storage site. In Ca-depleted conditions, NA does not elevate the free [Ca](i) to a threshold concentration required for hyperpolarization, probably because NA induces a small release of Ca from storage sites.

Transmembrane potential and amino acid transport in rat hepatocytes in primary monolayer culture

Transmembrane potential (Em) and alpha-aminoisobutyric acid (AIB) transport were measured in primary monolayer cultures of rat hepatocytes obtained from unoperated control rats and from rats 12 hr following partial hepatectomy. Measurements were performed 20-24 hr after plating the cells. The capacity of both kinds of cells to concentrate AIB depended upon extracellular sodium: however, the steady-state accumulation in regenerating cells was twice that of control cells. Transmembrane potentials, recorded with glass microelectrodes, were -13 +/- 0.6 mV and -27 +/- 1.6 mV in control and regenerating cells, respectively. Ouabain (1 mM) depolarized regenerating cell to -18 +/- 1.0 mV, but it had no effect on control cells. The initial rates of 1 mM AIB transport into control and regenerating cells were 1.2 +/- 0.1 and 3.1 +/- 0.1 nanomoles/mg protein x 4 min, respectively. Ouabain (1 mM) reduced the initial rate of AIB transport into regenerating cells to 2.7 +/- 0.1 nanomoles/mg protein x 4 min, but it had no effect on AIB transport into control cells. Glucagon (10(-7) M) added to control cells 12 hr before measurements hyperpolarized Em to -31 +/- 1.3 mV and increased AIB transport rate to 3.1 nanomoles/mg protein x 4 min. The results suggest a relationship between increases in Em and increases in AIB transport in rat hepatocytes. An electrogenic Na-K pump may be involved in both of these events.

Hyperpolarization as a mediator of insulin action: increased muscle glucose uptake induced electrically

Insulin hyperpolarizes. This raises the questions: is hyperpolarization a means by which insulin exerts some of its other effects, and can electrically induced hyperpolarization mimic insulin action on membrane functions? A technique was devised to study the latter question. The technique permits electrical hyperpolarization of a segment of whole muscle. Rat caudofemoralis muscle was threaded into a triple sucrose-gap chamber. Continuous flow of sucrose displaced interstitial fluid of muscle segments in the gaps. In one electrolyte compartment between gaps was placed an anode and in the other a cathode. The muscle segment in the anodal compartment was hyperpolarized continuously for 30 min, probably by about 1.5 mV. Uptake of deoxyglucose was increased in the hyperpolarized muscle segment. This increase, by 39%, was highly significant. It was probably smaller than the twofold increase elicited by insulin (100 mU/ml), but not than the possible effect produced by 10 mU/ml. The effect of hyperpolarization was specific for the D-glucose transport system because uptake of L-glucose was not altered.

The effect of glucagon, dibutyrylic cyclic AMP and theophylline on bile production in the cat

The effect of glucagon, dibutyrylic cyclic AMP and theophylline on bile production and liver metabolism was studied in fasting, chloralose anesthetized cats. After 45 min infusion of glucagon (0.1 mug/kg/min) total bile flow started to increase and finally reached a level 32% above control bile flow. The rise in flow was accompanied by a parallel increase in the biliary clearance of erythritol and the rate of biliary excretion of inorganic ions, whereas the bile acid excretion remained constant. Glucagon therefore appears to stimulate selectively the bile acid-independent canalicular production of bile. In contrast to the delayed action on bile production, glucagon caused an immediate change in liver metabolism as judged from the elimination rate of ethanol and the rise in plasma glucose concentration. Dibutyrylic cyclic AMP or theorphylline also caused similar immediate changes in liver metabolism but neither substance influenced bile production or the biliary excretion of electrolytes or bile acids. It thus appears that glucagon choleresis in the cat is either independent of cAMP release or that an increase in intracellular cAMP is not in itself sufficient to influence bile secretion. The results also seem to exclude that an increase in insulin production induced by hyperglycemia, or hemodynamic changes in the liver, can explain glucagon choleresis.

The actions of natural secretin on the small intestinal vasculature of the anaesthetized cat

1 A plethysmographic preparation of cat jejunum was used to measure changes in tissue volume and capillary filtration coefficient (CFC), simultaneously with measurements of arterial and venous pressures, and total blood flow. 2 Secretin was infused and injected intravenously and also infused intra-arterially in relatively small doses. Probable resulting blood concentrations were compared with those determined under physiological conditions in other investigations. 3 By intravenous or intra-arterial infusion, secretin caused increases in CFC, indicating an increased functional exchange vessel area, and increases in jejunal volume, indicating increased vascular capacitance. The jejunal blood flow increased whilst the blood pressure remained essentially unchanged. 4 By intravenous injection, secretin caused rises in jejunal volume and reductions in calculated jejunal vascular resistance over the same dose range. Effects were statistically significant at 500 mu/kg and higher doses caused reductions in systemic arterial pressure. 5 The calculated peak blood concentrations of secretin resulting from the lower doses used in this investigation were of the same order of magnitude as those determined under physiological conditions in man. 6 It is possible that at physiological concentrations secretin causes an increased functional exchange vessel area in the small intestine, and may also increase the total blood flow through this tissue.

K+ transport in isolated rat liver cells stimulated by glucagon and insulin in vitro

Unidirectional K+ fluxes were measured in suspensions of isolated rat liver parenchymal cells incubated with 42K+ in vitro. By tracer exchange analysis fluxes in both directions were estimated to 8-9 10(-12) mol/cm2. Glucagon in concentrations above 2 x 10(-8) M increased both influx and efflux to 160% of control values. Insulin increased influx by 12-14%, whereas efflux was apparently unaffected. Using an extracellular marker 51Cr EDTA, intracellular level of some ions was estimated in isolated liver cells: K+ = 172 mmol/kg water, Na+ = 25 mmol/kg water, Cl = 53 mmol/kg water. Cellular water content: 60%. Incubation with insulin for 1 h increased the intracellular concentration of K+ 1.7 mmol/kg water. The results indicate that glucoagon increased primarily the K+-permeability of the cell membrane, while insulin stimulates active K+ transport into the cell.

The inhibition by glucagon of the vasoconstrictor actions of noradrenaline, angiotensin and vasopressin on the hepatic arterial vascular bed of the dog

1 The hepatic artery of the anaesthetized dog was cannulated and perfused from a femoral artery, the blood flow and perfusion pressure being monitored continuously. The sympathetic periarterial nerves were divided. 2 Dose-dependent increases in hepatic arterial vascular resistance (HAVR) resulted from intra-arterial injections of noradrenaline, angiotensin and vasopressin. 3 Single injections of glucagon (100 mug, i.a.) caused a transient significant fall in HAVR of 19.9 +/- 3.2%, and infusions of 25 mug/min of glucagon intra-arterially caused maintained reductions in HAVR of 16.9 +/- 4.2%. 4 After single injections of 100 mug glucagon intra-arterially the vasoconstrictor responses to noradrenaline, angiotensin, and vasopressin were reduced by about 85-95%. Recovery occurred in 8-10 minutes. 5 Intra-arterial infusions of glucagon, 2.5-50.0 mug/min, reduced the effects of test doses of noradrenaline, angiotensin and vasopressin throughout the period of the infusions. 6 Dose-response curves to the constrictor agents were constructed before, during and after intra-arterial infusions of 25 mug/min of glucagon. Glucagon caused a parallel shift of the curves for noradrenaline and angiotensin to the right, with no suppression of the maximum response. 7 Infusions of glucagon shifted the dose-response curve for vasopressin to the right, but, in contrast to noradrenaline and angiotensin, the shift was nonparallel and there was a suppression of the maximum response by about one-half. 8 A large dose of insulin, 10 iu, transiently reduced HAVR and caused a weak and very transient inhibition of the effect of test doses of noradrenaline. The characteristics of these effects were quite different from those of glucagon. 9 It is possible that the antagonism by glucagon of the vasoconstrictor responses of the hepatic arterial vasculature may be important in protecting this vascular bed from the effects of concomitantly released vasoconstrictor agents.

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.

Regulation of ion permeabilities of isolated rat liver cells by external calcium concentration and temperature

Regulation of ion transport through the plasma membrane was studied on single cell suspensions of hepatocytes, obtained after perfusion of rat liver with collagenase/hyaluronidase solution. Steady-state intracellular K and Na contents were shown to be markedly dependent on external Ca concentration and temperature, the sum of both ion concentrations remaining nearly constant. In contrast, steady-state intracellular chloride content was found to be independent of external Ca concentration, but dependent on temperature. Using the constant field relations, the passive permeabilities PK and PCl for potassium and chloride, respectively, were derived from the experimental data. At temperatures at and above 37 degrees C, with increasing external Ca concentration, PK, exhibits a sharp decrease at about 10(-4)M. In contrast, PCl at 37 degrees C was found to be independent of Ca concentration within experimental error. Earth alkali ions other than Ca, show marked but different effects on PK if compared at equal concentrations. Preincubation of the cells with cholesterol leads to a broadening of the dependence of PK on external Ca concentration. The above results, as well as those on the dependence of PK on external Ca concentration obtained by other authors, could be quantitatively described by a theoretical model of the plasma membrane proposed earlier. This model postulates regulatory binding sites, which cooperatively undergo a cation exchange of divalent cations by K+ ions from the external medium if the cation composition of the latter is altered.

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.