A slowly inactivating calcium current works as a calcium sensor in calcitonin-secreting cells

AbstractCalcitonin (CT)-secreting cells (C-cells) are remarkably sensitive to changes in the extracellular Ca2+ concentration. In order to detect the mechanism by which C-cells monitor Ca2+, we compared a C-cell line responding to Ca2+ (rMTC cells) with another one known to have a defect in this Ca2+ signal transduction (TT cells). Rises of the Ca2+ concentration caused rMTC cells to depolarize and/or elicited spontaneous action potentials. Under voltage-clamp conditions, rMTC cells showed a slowly decaying Ca2+ inward current which was sensitive to dihydropyridines but not to Ni2+ at a low concentration. In contrast, the ‘defective’ TT cells neither depolarized nor fired action potentials with high Ca2+; they only exhibited an Ni2+-sensitive, transient Ca2+ current. The data strongly suggest that the slowly inactivating Ca2+ current is a prerequisite for Ca2+-sensitivity of C-cells and that fast inactivating channels are not sufficient to act as sensors of the extracellular Ca2+ concentration

Formyl peptides and ATP stimulate Ca2+ and Na+ inward currents through non-selective cation channels via G-proteins in dibutyryl cyclic AMP-differentiated HL-60 cells. Involvement of Ca2+ and Na+ in the activation of beta-glucuronidase release and superoxide production.

In human neutrophils, the chemotactic peptide N-formyl-L-methionyl-L-leucyl-L-phenylalanine (fMLP) induces increases in the intracellular free Ca2+ concentration ([Ca2+]i) with subsequent activation of beta-glucuronidase release and superoxide (O2-) production. Results from several laboratories suggest that the increase in [Ca2+]i is due to activation of non-selective cation (NSC) channels. We studied the biophysical characteristics, pharmacological modulation and functional role of NSC channels in dibutyryl cyclic AMP (Bt2cAMP)-differentiated HL-60 cells. fMLP increased [Ca2+]i by release of Ca2+ from intracellular stores and influx of Ca2+ from the extracellular space. fMLP also induced Mn2+ influx. Ca2+ and Mn2+ influxes were inhibited by 1-(beta-[3-(4-methoxyphenyl)propoxy]-4-methoxyphenethyl)-1H-imidazole hydrochloride (SK&F 96365). Under whole-cell voltage-clamp conditions, fMLP and ATP (a purinoceptor agonist) activated inward currents characterized by a linear current-voltage relationship and a reversal potential near 0 mV. NSC channels were substantially more permeable to Na+ than to Ca2+. SK&F 96365 inhibited fMLP- and ATP-stimulated currents with a half-maximal effect at about 3 microM. Pertussis toxin prevented stimulation by fMLP of NSC currents and reduced ATP-stimulated currents by about 80%. Intracellular application of the stable GDP analogue, guanosine 5'-O-[2-thio]diphosphate, completely blocked stimulation by agonists of NSC currents. In excised inside-out patches, single channel openings with an amplitude of 0.24 pA were observed in the presence of fMLP and the GTP analogue, guanosine 5'-O-[3-thio]triphosphate. The bath solution contained neither Ca2+ nor ATP. The current/voltage relationship was linear with a conductance of 4-5 pS and reversed at about 0 mV. fMLP-induced beta-glucuronidase release and O2- production were substantially reduced by replacement of extracellular CaCl2 or NaCl by ethylenebis(oxyethylenenitrilo)tetra-acetic acid and choline chloride respectively. In the absence of Ca2+ and Na+, fMLP was ineffective. SK&F 96365 inhibited fMLP-induced beta-glucuronidase release and O2- production in the presence of both Ca2+ and Na+, and in the presence of Ca2+ or Na+ alone. NaCl (25-50 mM) enhanced the basal and absolute extent of fMLP-stimulated GTP hydrolysis of heterotrimeric regulatory G-proteins in HL-60 membranes. The order of effectiveness of salts in enhancing GTP hydrolysis was LiCl > KCl > NaCl > choline chloride.(ABSTRACT TRUNCATED AT 400 WORDS

Bidirektionale hormonale Modulation spannungsabhängiger Ca2+-Kanle [Bidirectional hormonal modulation of voltage dependent ca2+ channels]

The role of guanine nucleotide-binding proteins (G-proteins), acting as transducers between membranous receptors activated by extracellular signals and enzymatic effectors controlling the concentrations of intracellular signal molecules, is well established. G-proteins are also involved in the hormonal modulation of voltage-dependent Ca2+ channels. In various cell types, the increase in intracellular signal molecules via G-protein-coupled receptors causes activation of protein kinases which may stimulate or inhibit voltage-dependent Ca2+ channels. For example, voltage-dependent Ca2+ channels of cardiac and skeletal myocytes are stimulated by cyclic adenosine monophosphate (cAMP)-dependent protein kinase. Other protein kinases, i.e., cyclic guanosine monophosphate (cGMP)-dependent protein kinase and Ca2+/phospholipid-dependent protein kinase C, also appear to be involved in the hormonal modulation of Ca2+ channels. According to this principle, G-proteins exert a distant control of ion channel activity. In addition, there appears to exist another mechanism which does not involve intracellular signal molecules or protein kinases stimulated by intracellular signal molecules. The only signal transduction components identified so far include receptors, G-protein and Ca2+ channels. Ca2+ channel modulations following this apparently membrane-confined mechanism have been described to occur in neuronal, endocrine and cardiac cells. Hormonal inhibition of Ca2+ channels in neuronal and endocrine cells is mediated by a pertussis-toxin-sensitive G-protein, possibly G0. The G-protein involved in the hormonal stimulation of Ca2+ channels in adrenocortical and pituitary cells may represent a pertussis-toxin-sensitive G-protein of the Gi-type. The choleratoxin-sensitive G-protein, Gs, may stimulate cardiac Ca2+ channels without the involvement of a cAMP-dependent intermediate step

Control of voltage-dependent Ca2+ channels by G protein-coupled receptors

G proteins act as transducers between membrane receptors activated by extracellular signals and enzymatic effectors controlling the concentration of cytosolic signal molecules such as cAMP, cGMP, inositol phosphates and Ca2+. In some instances, the receptor/G protein-induced changes in the concentration of cytosolic signal molecules correlate with activity changes of voltage-dependent Ca2+ channels. Ca2+ channel modulation, in these cases, requires the participation of protein kinases whose activity is stimulated by cytosolic signal molecules. The respective protein kinases phosphorylate Ca2+ channel-forming proteins or unknown regulatory components. More recent findings suggest another membrane-confined mechanism that does not involve cytosolic signal molecules but rather a more direct control of voltage-dependent Ca2+ channels by G proteins. Modulation of Ca2+ channel activity that follows this apparently membrane-confined mechanism has been described to occur in neuronal, cardiac, and endocrine cells. The G protein involved in the hormonal stimulation of Ca2+ channels in endocrine cells may belong to the family of Gi-type G proteins, which are functionally uncoupled from activating receptors by pertussis toxin. The G protein Gs, which is activated by cholera toxin, may stimulate cardiac Ca2+ channels without the involvement of a cAMP-dependent intermediate step. Hormonal inhibition of Ca2+ channels in neuronal and endocrine cells is mediated by a pertussis toxin-sensitive G protein, possibly Go. Whether G proteins act by binding directly to Ca2+ channels or through interaction with as yet undetermined regulatory components of the plasma membrane remains to be clarified