Altered synaptic plasticity and behavioral abnormalities in CNGA3-deficient mice.

The role of the cyclic nucleotide-gated (CNG) channel CNGA3 is well established in cone photoreceptors and guanylyl cyclase-D-expressing olfactory neurons. To assess a potential function of CNGA3 in the mouse amygdala and hippocampus, we examined synaptic plasticity and performed a comparative analysis of spatial learning, fear conditioning and step-down avoidance in wild-type mice and CNGA3 null mutants (CNGA3(-/-) ). CNGA3(-/-) mice showed normal basal synaptic transmission in the amygdala and the hippocampus. However, cornu Ammonis (CA1) hippocampal long-term potentiation (LTP) induced by a strong tetanus was significantly enhanced in CNGA3(-/-) mice as compared with their wild-type littermates. Unlike in the hippocampus, LTP was not significantly altered in the amygdala of CNGA3(-/-) mice. Enhanced hippocampal LTP did not coincide with changes in hippocampus-dependent learning, as both wild-type and mutant mice showed a similar performance in water maze tasks and contextual fear conditioning, except for a trend toward higher step-down latencies in a passive avoidance task. In contrast, CNGA3(-/-) mice showed markedly reduced freezing to the conditioned tone in the amygdala-dependent cued fear conditioning task. In conclusion, our study adds a new entry on the list of physiological functions of the CNGA3 channel. Despite the dissociation between physiological and behavioral parameters, our data describe a so far unrecognized role of CNGA3 in modulation of hippocampal plasticity and amygdala-dependent fear memory.

Analysis of calcium channels by conditional mutagenesis.

Ca2+ influx through various ion channels is an important determinant of the cytosolic Ca2+ concentration, which plays a pivotal role in countless cellular processes. The cardiac L-type Ca2+ channel, Ca(v)1.2, represents a major pathway for Ca2+ entry and is in many cells expressed together with other high- and low-voltage-activated Ca2+ channels. This article will focus on the use of conditional transgenic mouse models to clarify the roles of Ca2+ channels in several biological systems. The phenotypes of conditional Ca2+ channel transgenic mice have provided novel, and often unexpected, insights into the in vivo function of L-type and T-type Ca2+ channels as mediators of signaling between cell membrane and intracellular processes in blood pressure regulation, smooth muscle contractility, insulin secretion, cardiac function, sleep, learning, and memory.

Function of cGMP-dependent protein kinases as revealed by gene deletion.

Over the past few years, a wealth of biochemical and functional data have been gathered on mammalian cGMP-dependent protein kinases (cGKs). In mammals, three different kinases are encoded by two genes. Mutant and chimeric cGK proteins generated by molecular biology techniques yielded important biochemical knowledge, such as the function of the NH(2)-terminal domains of cGKI and cGKII, the identity of the cGMP-binding sites of cGKI, and the substrate specificity of the enzymes. Genetic approaches have proven especially useful for the analysis of the biological functions of cGKs. Recently, some of the in vivo targets and mechanisms leading to changes in neuronal adaptation, smooth muscle relaxation and growth, intestinal water secretion, bone growth, renin secretion, and other important functions have been identified. These data show that cGKs are signaling molecules involved in many biological functions.

G(alpha)q-deficient mice lack metabotropic glutamate receptor-dependent long-term depression but show normal long-term potentiation in the hippocampal CA1 region.

Long-term potentiation (LTP) and depression (LTD) are potential cellular mechanisms involved in learning and memory. Group I metabotropic glutamate receptors (mGluR), which are linked to heterotrimeric G-proteins of the G(q) family (G(q) and G(11)), have been reported to facilitate both hippocampal LTP and LTD. To evaluate their functional role in synaptic plasticity, we studied LTD and LTP in the CA1 region of the hippocampus from wild-type, Galpha(q)(-/-), and Galpha(11)(-/-) mice. Basic parameters of the synaptic transmission were not altered in Galpha(q)(-/-) and Galpha(11)(-/-) mice. Moreover, these mice showed normal LTP in response to a strong tetanus and to a weak tetanus. However, LTD induced either by a group I mGluRs agonist or by paired-pulse low-frequency stimulation (PP-LFS) was absent in Galpha(q)(-/-) mice. Moreover, PP-LFS caused potentiation of the synaptic transmission in these mice that was not affected by the NMDAR antagonist AP-5. These results show that G(q) plays a crucial role in the mGluR-dependent LTD, whereas hippocampal LTP is not affected by the lack of a single member of the G(q) family.

Mechanisms of NO/cGMP-dependent vasorelaxation.

Both cGMP-dependent and -independent mechanisms have been implicated in the regulation of vascular tone by NO. We analyzed acetylcholine (ACh)- and NO-induced relaxation in pressurized small arteries and aortic rings from wild-type (wt) and cGMP kinase I-deficient (cGKI(-/-)) mice. Low concentrations of NO and ACh decreased the spontaneous myogenic tone in wt but not in cGKI(-/-) arteries. However, contractions of cGKI(-/-) arteries and aortic rings were reduced by high concentrations (10 micromol/L) of 2-(N:, N-diethylamino)-diazenolate-2-oxide (DEA-NO). Iberiotoxin, a specific blocker of Ca(2+)-activated K(+) (BK(Ca)) channels, only partially prevented the relaxation induced by DEA-NO or ACh in pressurized vessels and aortic rings. DEA-NO increased the activity of BK(Ca) channels only in vascular smooth muscle cells isolated from wt cGKI(+/+) mice. These results suggest that low physiological concentrations of NO decrease vascular tone through activation of cGKI, whereas high concentrations of DEA-NO relax vascular smooth muscle independent of cGKI and BK(Ca). NO-stimulated, cGKI-independent relaxation was antagonized by the inhibition of soluble guanylyl cyclase or cAMP kinase (cAK). DEA-NO increased cGMP to levels that are sufficient to activate cAK. cAMP-dependent relaxation was unperturbed in cGKI(-/-) vessels. In conclusion, low concentrations of NO relax vessels by activation of cGKI, whereas in the absence of cGKI, NO can relax small and large vessels by cGMP-dependent activation of cAK.

Long-term potentiation in the hippocampal CA1 region of mice lacking cGMP-dependent kinases is normal and susceptible to inhibition of nitric oxide synthase.

Long-term potentiation (LTP) is a potential cellular mechanism for learning and memory. The retrograde messenger nitric oxide (NO) is thought to induce LTP in the CA1 region of the hippocampus via activation of soluble guanylyl cyclase (sGC) and, ultimately, cGMP-dependent protein kinase (cGK). Two genes code for the isozymes cGKI and cGKII in vertebrates. The functional role of cGKs in LTP was analyzed using mice lacking the gene(s) for cGKI, cGKII, or both. LTP was not altered in the mutant mice lineages. However, LTP was reduced by inhibition of NO synthase and NMDA receptor antagonists, respectively. The reduced LTP was not recovered by the cGK-activator 8-(4 chlorophenylthio)-cGMP. Moreover, LTP was not affected by the sGC inhibitor 1H-[1,2,4]oxadiazolo[4,3-a]-quiloxalin-1-one. In contrast, it was effectively suppressed by nicotinamide, a blocker of the ADP-ribosyltransferase. These results show that cGKs are not involved in LTP in mice and that NO induces LTP through an alternative cGMP-independent pathway, possibly ADP-ribosylation.

Frequency modulation of Ca2+ sparks is involved in regulation of arterial diameter by cyclic nucleotides.

Forskolin, which elevates cAMP levels, and sodium nitroprusside (SNP) and nicorandil, which elevate cGMP levels, increased, by two- to threefold, the frequency of subcellular Ca2+ release ("Ca2+ sparks") through ryanodine-sensitive Ca2+ release (RyR) channels in the sarcoplasmic reticulum (SR) of myocytes isolated from cerebral and coronary arteries of rats. Forskolin, SNP, nicorandil, dibutyryl-cAMP, and adenosine increased the frequency of Ca(2+)-sensitive K+ (KCa) currents ["spontaneous transient outward currents" (STOCs)] by two- to threefold, consistent with Ca2+ sparks activating STOCs. These agents also increased the mean amplitude of STOCs by 1.3-fold, an effect that could be explained by activation of KCa channels, independent of effects on Ca2+ sparks. To test the hypothesis that cAMP could act to dilate arteries through activation of the Ca2+ spark-->KCa channel pathway, the effects of blockers of KCa channels (iberiotoxin) and of Ca2+ sparks (ryanodine) on forskolin-induced dilations of pressurized cerebral arteries were examined. Forskolin-induced dilations were partially inhibited by iberiotoxin and ryanodine (with no additive effects) and were entirely prevented by elevating external K+. Forskolin lowered average Ca2+ in pressurized arteries while increasing ryanodine-sensitive, caffeine-induced Ca2+ transients. These experiments suggest a new mechanism for cyclic nucleotide-mediated dilations through an increase in Ca2+ spark frequency, caused by effects on SR Ca2+ load and possibly on the RyR channel, which leads to increased STOC frequency, membrane potential hyperpolarization, closure of voltage-dependent Ca2+ channels, decrease in arterial wall Ca2+, and, ultimately, vasodilation.

Formation of postsynaptic-like membranes during differentiation of embryonic stem cells in vitro.

To analyze the formation of neuromuscular junctions, mouse pluripotent embryonic stem (ES) cells were differentiated via embryoid bodies into skeletal muscle and neuronal cells. The developmentally controlled expression of skeletal muscle-specific genes coding for myf5, myogenin, myoD and myf6, alpha 1 subunit of the L-type calcium channel, cell adhesion molecule M-cadherin, and neuron-specific genes encoding the 68-, 160-, and 200-kDa neurofilament proteins, synaptic vesicle protein synaptophysin, brain-specific proteoglycan neurocan, and microtubule-associated protein tau was demonstrated by RT-PCR analysis. In addition, genes specifically expressed at neuromuscular junctions, the gamma- and epsilon-subunits of the nicotinic acetylcholine receptor (AChR) and the extracellular matrix protein S-laminin, were found. At the terminal differentiation stage characterized by the formation of multinucleated spontaneously contracting myotubes, the myogenic regulatory gene myf6 and the AChR epsilon-subunit gene, both specifically expressed in mature adult skeletal muscle, were found to be coexpressed. Only the terminally differentiated myotubes showed a clustering of nicotinic acetylcholine receptors (AChR) and a colocalization with agrin and synaptophysin. The formation of AChRs was also demonstrated on a functional level by using the patch clamp technique. Taken together, our results showed that during ES cell differentiation in vitro neuron- and muscle-specific genes are expressed in a developmentally controlled manner, resulting in the formation of postsynaptic-like membranes. Thus, the embryonic stem cell differentiation model will be helpful for studying cellular interactions at neuromuscular junctions by "loss of function" analysis in vitro.

Ca2+ channels, ryanodine receptors and Ca(2+)-activated K+ channels: a functional unit for regulating arterial tone.

Local calcium transients ('Ca2+ sparks') are thought to be elementary Ca2+ signals in heart, skeletal and smooth muscle cells. Ca2+ sparks result from the opening of a single, or the coordinated opening of many, tightly clustered ryanodine receptor (RyR) channels in the sarcoplasmic reticulum (SR). In arterial smooth muscle, Ca2+ sparks appear to be involved in opposing the tonic contraction of the blood vessel. Intravascular pressure causes a graded membrane potential depolarization to approximately -40 mV, an elevation of arterial wall [Ca2+]i and contraction ('myogenic tone') of arteries. Ca2+ sparks activate calcium-sensitive K+ (KCa) channels in the sarcolemmal membrane to cause membrane hyperpolarization, which opposes the pressure induced depolarization. Thus, inhibition of Ca2+ sparks by ryanodine, or of KCa channels by iberiotoxin, leads to membrane depolarization, activation of L-type voltage-gated Ca2+ channels, and vasoconstriction. Conversely, activation of Ca2+ sparks can lead to vasodilation through activation of KCa channels. Our recent work is aimed at studying the properties and roles of Ca2+ sparks in the regulation of arterial smooth muscle function. The modulation of Ca2+ spark frequency and amplitude by membrane potential, cyclic nucleotides and protein kinase C will be explored. The role of local Ca2+ entry through voltage-dependent Ca2+ channels in the regulation of Ca2+ spark properties will also be examined. Finally, using functional evidence from cardiac myocytes, and histological evidence from smooth muscle, we shall explore whether Ca2+ channels, RyR channels, and KCa channels function as a coupled unit, through Ca2+ and voltage, to regulate arterial smooth muscle membrane potential and vascular tone.

ATP-sensitive potassium channels in cultured arterial segments.

Organ cultures of arteries have been used to study growth responses, proliferation, and contractility. However, the function of specific-ion channels in cultured arteries has not been investigated. ATP-sensitive K+ (KATP) channels play an important role in the control of arterial tone. The goal of this study was to determine the functional state of KATP channels in arteries kept in culture. Segments from rabbit mesenteric arteries were cultured in for 2-7 days. To explore the properties of KATP channels, the effects of KATP-channel modulators and other vasoactive substances on isometric force, density, and modulation of KATP currents in single smooth muscle cells isolated from cultured vessels were examined. Isometric contractions were measured with a resistance-vessel myograph. Whole cell KATP currents were recorded with the patch-clamp technique. Membrane capacitance and KATP-current density in single smooth muscle cells from freshly dissected (control) and cultured arteries were not altered. At -60 mV, glibenclamide-sensitive currents in the presence of the K(+)-channel opener pinacidil were -4.7 +/- 1.2, -4.7 +/- 0.6, and -4.6 +/- 0.7 pA/pF for control and 2- and 4-day arteries, respectively. Inhibitory modulation of KATP currents in arterial smooth muscle also remained intact for 4 days in culture; the vasoconstrictor histamine (10 microM) reduced glibenclamide-sensitive currents in the presence of pinacidil by 61.2 +/- 2.8, 42.4 +/- 10.1, and 41.2 +/- 6.1% for control and 2- and 4-day arteries, respectively. Pinacidil relaxed control and cultured arteries (1-7 days) in a dose-dependent manner. Half-maximal effective concentrations of pinacidil were 0.42, 0.24, 0.23, and 0.51 microM for control and 2-, 4-, and 7-day arteries, respectively, whereas maximal relaxations to pinacidil were 62.9, 47.5, 37.5, and 55.7% for control and 2-, 5-, and 7-day arteries, respectively. Histamine, norepinephrine, and serotonin constricted cultured arteries, although responses to histamine and norepinephrine diminished by 30-50% after 5 days in culture. The relaxant effect of acetylcholine was not maintained in cultured arteries. Sodium nitroprusside, however, effectively relaxed arteries cultured for 2-7 days. The data indicate that with the culture model described, KATP channels in arterial smooth muscle remained functional and contractile responses in arterial segments were maintained for up to 7 days. These results suggest that this approach can be used to study either long-term regulation of KATP channels or the role of this channel type in growth responses.

Adenosine activates ATP-sensitive potassium channels in arterial myocytes via A2 receptors and cAMP-dependent protein kinase.

The mechanism by which the endogenous vasodilator adenosine causes ATP-sensitive potassium (KATP) channels in arterial smooth muscle to open was investigated by the whole-cell patch-clamp technique. Adenosine induced voltage-independent, potassium-selective currents, which were inhibited by glibenclamide, a blocker of KATP currents. Glibenclamide-sensitive currents were also activated by the selective adenosine A2-receptor agonist 2-p-(2-carboxethyl)-phenethylamino-5'-N- ethylcarboxamidoadenosine hydrochloride (CGS-21680), whereas 2-chloro-N6-cyclopentyladenosine (CCPA), a selective adenosine A1-receptor agonist, failed to induce potassium currents. Glibenclamide-sensitive currents induced by adenosine and CGS-21680 were largely reduced by blockers of the cAMP-dependent protein kinase (Rp-cAMP[S], H-89, protein kinase A inhibitor peptide). Therefore, we conclude that adenosine can activate KATP currents in arterial smooth muscle through the following pathway: (i) Adenosine stimulates A2 receptors, which activates adenylyl cyclase; (ii) the resulting increase intracellular cAMP stimulates protein kinase A, which, probably through a phosphorylation step, opens KATP channels.

ATP-sensitive K+ currents in cerebral arterial smooth muscle: pharmacological and hormonal modulation.

Calcitonin gene-related peptide (CGRP), hypoxia, and synthetic activators of ATP-sensitive potassium (KATP) channels (e.g., pinacidil and levcromakalim) cause dilation of cerebral arteries that are attenuated by the KATP channel inhibitor glibenclamide. We have identified and characterized KATP currents in smooth muscle cells isolated from rabbit cerebral arteries, using the whole cell configuration of the patch-clamp technique. Pinacidil (10 microM) and levcromakalim (10 microM) increased glibenclamide-sensitive currents about sixfold in cells dialyzed with 0.1 mM ATP. Glibenclamide-sensitive currents in the presence of pinacidil were potassium selective, voltage independent, and reduced about threefold by elevating intracellular ATP from 0.1 to 3.0 mM. External tetraethylammonium and 4-aminopyridine at millimolar concentrations reduced pinacidil-induced currents, whereas iberiotoxin, a blocker of calcium-activated potassium channels, had no effect. The vasoconstrictors serotonin and histamine also inhibited pinacidil-induced currents. The vasodilators CGRP and adenosine, in contrast, increased glibenclamide-sensitive potassium currents. We conclude that cerebral artery smooth muscle cells have KATP channels that are regulated by endogenous vasoconstrictors and vasodilators. We propose that these channels are involved in the dilation of cerebral arteries to CGRP and synthetic vasodilators.

Cardiomyocyte-like cells differentiated in vitro from embryonic carcinoma cells P19 are characterized by functional expression of adrenoceptors and Ca2+ channels.

P19 embryonal carcinoma cells were differentiated via embryolike aggregates (embryoid bodies) into spontaneously beating myocytes. During the whole process of differentiation the functional expression of cardiac-specific receptors and ionic channels was characterized by measuring the chronotropic reactivity, action potentials, and ionic currents in response to various cardioactive drugs. Positive chronotropic effects obtained at different maximal effective concentrations of adrenoceptor-mediated agonists indicated differential adrenoceptor expression during the in vitro development of cardiomyocyte-like cells. No cardiac-specific response was obtained with the muscarinic cholinoceptor agonist carbachol. Single beating cells were enzymatically isolated and investigated by the patch-clamp technique. Pacemaker action potentials similar to those of embryonal cardiomyocytes exhibited amplitudes ranging from 50 to 85 mV. The action potentials were synchronous to the mechanical contractions and, comparable to the chronotropic effects, were modulated by BayK 8644, isradipine, and adrenaline. The functional expression of L-type Ca2+ channels was demonstrated by the Ca2+ channel blockers isradipine, nisoldipine, gallopamil, and diltiazem causing negative chronotropic responses, as well as by the Ca2+ channel activator BayK 8644 causing positive chronotropic responses. These effects gradually increased with time of differentiation. The expression of L-type Ca2+ channels and of nicotinic acetylcholine receptors was confirmed in voltage-clamp experiments. The study demonstrates that P19 embryonal carcinoma cells can be induced to differentiate into cardiomyocyte-like cells comparable to embryonal and neonatal heart cells lacking the muscarinic cholinoceptor response only.

Double-pulse facilitation of smooth muscle alpha 1-subunit Ca2+ channels expressed in CHO cells.

Frequent strong depolarizations facilitate Ca2+ channels in various cell types by shifting their gating behavior towards mode 2, which is characterized by long openings and high probability of being open. In cardiac cells, the same type of gating behavior is potentiated by beta-adrenoceptors presumably acting via phosphorylation of a protein identical to or associated with the channel. Voltage-dependent phosphorylation has also been reported to underlie Ca2+ channel facilitation in chromaffin adrenal medulla and in skeletal muscle cells. We studied a possible voltage-dependent facilitation of the principal channel forming alpha 1-subunit of the dihydropyridine-sensitive smooth muscle Ca2+ channel. Single channel and whole-cell Ca2+ currents were recorded in Chinese hamster ovary cells stably expressing the class Cb Ca2+ channel alpha 1-subunit. Strong depolarizing voltage-clamp steps preceding the test pulse resulted in a 2- to 3-fold increase of the single Ca2+ channel activity and induction of mode 2-like gating behavior. Accordingly we observed a significant potentiation of the whole-cell current by approximately 50%. In contrast to the previous suggestions we found no experimental evidence for involvement of channel phosphorylation by protein kinases (cAMP-dependent protein kinase, protein kinase C and other protein kinases utilizing ATP gamma S) in the control and facilitated current. The data demonstrate that the L-type Ca2+ channel alpha 1-subunit solely expressed in Chinese hamster ovary cells is subject to a voltage-dependent facilitation but not to phosphorylation.(ABSTRACT TRUNCATED AT 250 WORDS)

Involvement of A pertussis Toxin Sensitive G-Protein in the Inhibition of Inwardly Rectifying K Currents by Platelet-Activating Factor in Guinea-Pig Atrial Cardiomyocytes.

Platelet-activating factor (PAF) inhibits single inwardly rectifying K(+) channels in guinea-pig ventricular cells. There is currently little information as to the mechanism by which these channels are modulated. The effect of PAF on quasi steady-state inwardly rectifying K(+) currents (presumably of the I(K1) type) of auricular, atrial and ventricular cardiomyocytes from guinea-pig were studied. Applying the patch-clamp technique in the whole-cell configuration, PAF (10 nM) reduced the K(+) currents in all three cell types. The inhibitory effect of PAF occurred within seconds and was reversible upon wash-out. It was almost completely abolished by the PAF receptor antagonist BN 50730. Intracellular infusion of atrial cells with guanine 5'-(beta-thio)diphosphate (GDPS) or pretreatment of cells with pertussis toxin abolished the PAF dependent reduction of the currents. Neither extracellularly applied isoproterenol nor intracellularly applied adenosine 3',5'-cyclic monophosphate (cyclic AMP) attenuated the PAF effect. In multicellular preparations of auricles, PAF (10 nM) induced arrhythmias. The arrhythmogenic activity was also reduced by BN 50730. The data indicate that activated PAF receptors inhibit inwardly rectifying K(+) currents via a pertussis toxin sensitive G-protein without involvement of a cyclic AMP-dependent step. Since I(K1) is a major component in stabilizing the resting membrane potential, the observed inhibition of this type of channel could play an important role in PAF dependent arrhythmogenesis in guinea-pig heart.

Voltage-dependent L-type Ca channels and a novel type of non-selective cation channel activated by cAMP-dependent phosphorylation in mesoderm-like (MES-1) cells.

Undifferentiated P19 embryonal carcinoma cells (ECC P19), the P19-derived clonal cell lines END-2 (visceral endoderm-like), EPI-7 (epithelioid ectoderm-like), MES-1 (mesoderm-like) and a parietal yolk sac cell line (PYS-2) were used as cellular models to examine the functional expression of voltage-dependent Ca channels and other Ca-permeable cation channels at various stages of early embryonic development. Whole-cell currents were recorded by means of the patch clamp technique. Whereas more than 75% of MES-1 cells possessed Ca channel currents, neither P19, END-2, EPI-7 nor PYS-2 cells had detectable voltage-dependent inward currents. Ca channel currents of MES-1 cells were highly sensitive towards 1,4-dihydropyridines and blocked by cadmium. Adrenaline (10 microM) caused Ca channel stimulation in only 14% of MES-1 cells examined. However, in 62% of the cells adrenaline activated a linear current component which under physiological conditions reversed close to 0 mV. Removal of extracellular Na+ suppressed the adrenaline-induced inward current, while reducing extracellular Cl- had no significant effect. These findings suggest that the adrenaline-induced current is carried through non-selective cation channels which were found to be permeable for Na+, K+, Cs+ >> Ca2+. Remarkably, the intracellular signalling pathway for activation of the non-selective cation current involved the cascade of reactions leading to cAMP-dependent phosphorylation, a regulatory pathway well known for cardiac Ca channels. A possible functional role of adrenaline-induced non-selective cation currents and Ca channels in embryonal development is discussed.

Major role of dihydropyridine-sensitive Ca2+ channels in Ca(2+)-induced calcitonin secretion.

Endocrine cells are known to possess multiple types of Ca2+ channels. In neurons, omega-conotoxin-sensitive N-type Ca2+ channels have been shown to play a dominant role in neurotransmitter release, but uncertainty remains about the types of Ca2+ channels involved in stimulus-secretion coupling in endocrine cells. We investigated the relative contribution of 1,4-dihydropyridine-sensitive and omega-conotoxin-sensitive Ca2+ channels to Ca(2+)-induced calcitonin release in parafollicular cells of the thyroid (C cells). In whole cell voltage-clamp experiments, both 1,4-dihydropyridine-sensitive and omega-conotoxin-sensitive Ca2+ channel currents were identified. The dihydropyridine isradipine (1 microM) but not omega-conotoxin (1 microM) inhibited the steady-state Ca2+ influx at physiological membrane potentials, the spontaneous electrical activity, and calcitonin secretion (at 2-h incubations). Moreover, suppression of the spontaneous electrical activity by the Na+ channel blocker tetrodotoxin did not affect calcitonin release. We conclude that 1,4-dihydropyridine-sensitive Ca2+ channels play a major role in Ca(2+)-dependent calcitonin release and that calcitonin secretion due to Ca2+ influx proceeds even in the absence of action potentials.

Dihydropyridine binding and Ca(2+)-channel characterization in clonal calcitonin-secreting cells.

1,4-Dihydropyridine-sensitive voltage-dependent Ca2+ channels play a crucial role in the extracellular Ca(2+)-sensing of calcitonin-secreting parafollicular cells of the thyroid (C-cells). To characterize the Ca2+ channels in C-cells, we studied 1,4-dihydropyridine binding and performed electrophysiological experiments with Ca(2+)-sensitive C-cells (rat C-cell line rMTC 44-2) in comparison with 'defective' Ca(2+)-insensitive C-cells (human C-cell line TT). In membranes of rMTC cells, we detected a high-affinity, stereoselective and Ca(2+)-dependent binding site for the Ca(2+)-channel-blocking 1,4-dihydropyridine, (+)-[3H]PN 200-110. Radioligand binding was saturable (Bmax. = 18 +/- 2 fmol/mg of protein), reversible [Ki for (+)-PN 200-110 = 37 +/- 1 pM) and allosterically modulated by the phenylalkylamine (-)-desmethoxyverapamil [(-)-D888] as well as the bis-benzylisoquinoline alkaloid (+)-tetrandrine. Thus the 1,4-dihydropyridine binding in rMTC cells featured all characteristics of binding to the alpha 1-subunit of L-type Ca2+ channels. In contrast, in membranes of TT cells, which are known to lack Ca(2+)-sensitivity, no Ca(2+)-channel-specific (+)-[3H]PN 200-110 binding was detected. In voltage-clamp experiments, rMTC cells exhibited slowly inactivating Ca2+ currents which proved sensitive to (+)-PN 200-110, (-)-D888 and (+)-tetrandrine. These L-type Ca(2+)-channel blockers did not affect the Ca2+ currents in TT cells. The numbers of 1,4-dihydropyridine-sensitive Ca2+ channels in rMTC cells as calculated from both the binding studies and the whole-cell/single-channel recordings were 2000 and 7000/cell respectively. Thus qualitative and quantitative detection of 1,4-dihydropyridine-sensitive Ca2+ channels by radioligand-binding in Ca(2+)-sensitive rMTC cells, but not in Ca(2+)-insensitive TT cells, reflects the electrophysiological detection of functional Ca2+ channel in rMTC cells, but not in TT cells.

Cation channels in oocytes and early states of development: a novel type of nonselective cation channel activated by adrenaline in a clonal mesoderm-like cell line (MES-1).

The expression of receptors and ion channels alters during growth, maturation, and after fertilization of oocytes reflecting functional changes. Besides voltage-dependent ion channels, oocyte membranes possess an IP3-activated cation channel mediating a prolonged Ca2+ influx. The Ca2+ is thought to be involved in maturation and fertilization. Alternatively, mono- and divalent cations can enter oocytes via stretch-activated channels. The oocyte channel population is further modified during subsequent embryogenesis, suggesting that ionic channels obviously become expressed at specific states of embryological differentiation and in tissue-specific manner. The resulting differences in functional ion channel populations of adult cells underlie the large diversity of cells and their function. Conversely, differentiation and cell proliferation themselves depend on ion transport. Ca2+ ions have been shown to play a pivotal role in these processes. Nonselective cation channels represent one possible pathway for Ca2+ entry into the cell and, therefore, might be involved in the regulation of embryological development. Undifferentiated embryonal carcinoma cells (P19), visceral endoderm-like cells (END-2), epithelioid ectoderm-like cells (EPI-7), mesoderm-like cells (MES-1), and parietal yolk sac cells (PYS-2) have been used as a model to study the expression of ionic channels during early development. In MES-1 cells a nonselective cation current was activated by adrenaline. Interestingly, the intracellular pathway for activation of these channels involved the cascade of activation of the cAMP-dependent protein kinase (PKA) resulting in protein phosphorylation. This mechanism is well known for Ca2+ channel stimulation in cardiac and skeletal muscle both originating from the mesoderm.

Insulin-like growth factor I modulates voltage-dependent Ca2+ channels in neuronal cells.

Insulin and insulin-like growth factors are neuroactive peptides. We investigated the effect of insulin-like growth factor I (IGF-I) on Ca2+ channel currents in 108CC15 neuroblastoma x glioma (N x G) cells and a possible role of protein kinase C (PKC). Whereas the native IGF-I enhanced the Ca2+ channel current density in N x G cells, the boiled IGF-I had no effect. The effect of IGF-I occurred after 1-2 h incubation and reversed within 24 h. Ca2+ channel currents recorded in control cells were mainly of a low-threshold fast inactivating type and showed a mean density of 5.9 +/- 0.3 pA/pF. Current density in cells incubated with IGF-I (0.2 micrograms/ml) for 2 h increased to 9.2 +/- 0.8 pA/pF. Ca2+ channel currents in cells treated with IGF-I showed an enhanced amount of a high-threshold slowly inactivating Ca2+ current type sensitive to the dihydropyridine isradipine and the snail toxin omega-conotoxin. The effect of IGF-I was suppressed by coincubation with the PKC inhibitors 1-(5-isoquinolinylsulfonyl)-2-methyl-piperazine (H-7) and staurosporin which were both without effect on current density in control cells. Whereas the inactive phorbol ester phorbol 12-myristate 13-acetate (PMA) failed to modulate Ca2+ channels in N x G cells, stimulation of PKC by the active phorbol ester PMA mimicked the effect of IGF-I. The effects of IGF-I and phorbol ester were not additive. Our data suggest an intracellular mechanism dependent on PKC and we propose a physiological relevance of the observed Ca2+ channel modulation by IGF-I in the neuroactivity of the peptide.