Ionic events induced by epidermal growth factor. Evidence that hyperpolarization and stimulated cation influx play a role in the stimulation of cell growth

Expression of different potassium channels in cells isolated from human myometrium and leiomyomas

OBJECTIVE

Electrophysiologic characteristics of human myometrial and leiomyomatous cells isolated in culture were investigated. Both types of cell were shown to be smooth muscle cells by immunofluorescence.

STUDY DESIGN

Voltage-activated potassium currents were recorded by whole-cell patch-clamp techniques and analyzed for differences in expression, voltage-dependence, kinetics, and inactivation.

RESULTS

Depolarizing-voltage steps from -90 mV to +30 mV elicited two types of noninactivating outward currents that differed in their kinetics in 83% (n = 36) of normal cells in culture for 3 to 5 days; 6% responded with fast (3.5 milliseconds) outward inactivating currents; 11% in culture for 1 day responded only with long-lasting inactivating currents (33.2 +/- 7.2 milliseconds). Cells isolated from leiomyomas responded preferentially (65%, n = 31) with fast (3.3 +/- 0.1 milliseconds) outward inactivating currents; 35% responded with noninactivating outward currents similar to those from normal cells.

CONCLUSION

Different potassium channel currents, noninactivating and inactivating, are predominantly expressed in cells isolated from human myometrium and leiomyomas, respectively.

Inositol trisphosphate and calcium signalling

Inositol trisphosphate is a second messenger that controls many cellular processes by generating internal calcium signals. It operates through receptors whose molecular and physiological properties closely resemble the calcium-mobilizing ryanodine receptors of muscle. This family of intracellular calcium channels displays the regenerative process of calcium-induced calcium release responsible for the complex spatiotemporal patterns of calcium waves and oscillations. Such a dynamic signalling pathway controls many cellular processes, including fertilization, cell growth, transformation, secretion, smooth muscle contraction, sensory perception and neuronal signalling.

Nonselective cation channels: physiological and pharmacological modulations of channel activity

Cation channels play a major role in fast and sustained cellular responses to hormones and neurotransmitters. They contribute to depolarization of the membrane and--in most cases--to an increase in the intracellular Ca2+ concentration. Nonselective cation channels presumably form a large family of diverse channels which are modulated by various extracellular and intracellular signals. Structure and regulation of ligand-operated and cyclic nucleotide-activated nonselective cation channels found in synapses and sensory receptor cells, respectively, are well documented; none of the structures of other cation channels are known. Except for ligand-operated and stretch-activated channels, G-proteins form the link between the involved receptors and signalling cascades stimulating nonselective cation channels. Observed in numerous cellular systems is hormonal activation of cation channels by hormones or neurotransmitters interacting with heptahelical receptors inducing a phosphoinositide breakdown (PI response); several pathways stimulated within the PI response may generate signals involved in cation channel activation. Pharmacological modifications of nonselective cation channels by inorganic and organic blockers are so far extremely limited; various blockers have been described but unfortunately lack high specificity for these channels.

Tyrosine kinase inhibitors block calcium channel currents in vascular smooth muscle cells

Selective inhibitors of tyrosine kinases, tyrphostin 23 and genistein, produced concentration-dependent inhibition of voltage-operated calcium channel currents in vascular smooth muscle cells isolated from rabbit ear artery. The potency of these two structurally dissimilar inhibitors was similar to that reported for their action as inhibitors of tyrosine kinases. Daidzein, an inactive analogue of genistein, had little inhibitory effect on calcium channel currents at concentrations below 300 microM consistent with an action of these agents at a tyrosine kinase. However, tyrphostin 1, a reportedly less active tyrphostin derivative, also inhibited calcium channel currents with a potency similar to tyrphostin 23. These findings suggest that voltage-operated calcium channels in vascular smooth muscle may be modulated by endogenous tyrosine kinase(s) which display different sensitivities to inhibitors compared with the epidermal growth factor (EGF) receptor. Alternatively the possibility of direct blocking actions of these inhibitors at voltage-operated calcium channels cannot be excluded.

Potassium and calcium currents activated by foetal calf serum in Balb-c 3T3 fibroblasts

In quiescent Balb-c mouse 3T3 fibroblasts, the application of whole or dialyzed 10% foetal calf serum elicits a biphasic electrical response, consisting of a transient outward current, flowing through Ca(2+)-activated K+ channels, followed by an inward one, lasting up to 15 min. On the basis of experiments with ion substitutions and blockers, the inward current can be attributed to the opening of cationic channels permeable to Na+ and Ca2+ ions. This current could mediate the calcium influx involved in the sustained elevation of [Ca2+]i that has been observed in many preparations in response to mitogen stimulation and that is involved in triggering cell proliferation.

Epidermal growth factor activates calcium channels by phospholipase A2/5-lipoxygenase-mediated leukotriene C4 production

Epidermal growth factor (EGF) induces a Ca2+ influx in many cell types, but the underlying mechanisms are so far unresolved. We report that: EGF-induced Ca2+ channel activity is eliminated by lipoxygenase inhibition and is mimicked by artificial induction of lipoxygenase activity; addition of leukotriene C4 can fully mimic EGF in its ability to activate Ca2+ channels; and EGF induces a rapid accumulation of intracellular leukotriene C4. In addition, we show that EGF-induced, Ca(2+)-dependent membrane hyperpolarization and junB proto-oncogene expression are dependent on lipoxygenase activity, whereas EGF-induced cytoplasmic alkalinization is not. We conclude that PLA2/5-lipoxygenase-mediated leukotriene C4 production constitutes a novel and specific signal transduction pathway in growth factor action.

Transforming growth factor alpha inhibits glycogen synthesis and counteracts the stimulation by insulin in hepatocytes

Rat transforming growth factor alpha (TGF alpha) inhibits glycogen synthesis in rat and guinea pig hepatocyte cultures and counteracts the stimulation of glycogen deposition and activation of glycogen synthase caused by insulin. The EC50 for inhibition of glycogen deposition was 0.2nM. The inhibition of glycogen synthesis was also observed in the absence of extracellular Ca2+ and was not blocked by indomethacin, suggesting that it is not mediated by production of prostaglandins. Since TGF alpha is produced by hepatocytes during liver regeneration and by macrophages during endotoxin stimulation, it may have an autocrine/paracrine effect on hepatic carbohydrate metabolism in these states, and may account for the low hepatic glycogen levels during liver regeneration and the impaired glucose tolerance associated with sepsis.

Two currents activated by epidermal growth factor in EGFR-T17 fibroblasts

Application of 10 nM Epidermal Growth Factor (EGF) to single EGFR-T17 fibroblasts induced a marked hyperpolarization that could last for tens of minutes; in many cases the first transient was followed by a series of oscillations of the membrane potential. The outward current responsible for the hyperpolarizing response could be recorded simultaneously to an increase in the intracellular calcium concentration, as measured with the fluorescent indicator fura-2. The conductance was nearly linear in the voltage range from -100 to +50 mV. While the EGF-induced current had many characteristics of a K+ current and was strongly reduced by 50 nM charybdotoxin (ChTx), its reversal potential was apparently more negative than the potassium equilibrium potential (VK). The application of 2 microM ouabain prior to EGF stimulation produced responses that were similar to those obtained without ouabain; however, under these conditions the EGF-induced current showed a reversal potential of -96.6 +/- 3.2 mV, very close to VK. Simultaneous application of both 2 microM ouabain and 50 nM ChTx completely abolished the response. It can be concluded that the response to EGF stimulation in EGFR-T17 cells consists of two components: the first is a current carried through Ca(2+)-activated K+ channels; the second is due to the acceleration of the operation of the Na+/K(+)-ATPase.