KChAP/Kvbeta1.2 interactions and their effects on cardiac Kv channel expression.

KChAP and voltage-dependent K+ (Kv) beta-subunits are two different types of cytoplasmic proteins that interact with Kv channels. KChAP acts as a chaperone for Kv2.1 and Kv4.3 channels. It also binds to Kv1.x channels but, with the exception of Kv1.3, does not increase Kv1.x currents. Kvbeta-subunits are assembled with Kv1.x channels; they exhibit "chaperone-like" behavior and change gating properties. In addition, KChAP and Kvbeta-subunits interact with each other. Here we examine the consequences of this interaction on Kv currents in Xenopus oocytes injected with different combinations of cRNAs, including Kvbeta1.2, KChAP, and either Kv1.4, Kv1.5, Kv2.1, or Kv4.3. We found that KChAP attenuated the depression of Kv1.5 currents produced by Kvbeta1.2, and Kvbeta1.2 eliminated the increase of Kv2.1 and Kv4.3 currents produced by KChAP. Both KChAP and Kvbeta1.2 are expressed in cardiomyocytes, where Kv1.5 and Kv2.1 produce sustained outward currents and Kv4.3 and Kv1.4 generate transient outward currents. Because they interact, either KChAP or Kvbeta1.2 may alter both sustained and transient cardiac Kv currents. The interaction of these two different classes of modulatory proteins may constitute a novel mechanism for regulating cardiac K+ currents.

Increased release of arachidonic acid and eicosanoids in iron-overloaded cardiomyocytes.

BACKGROUND: Patients with transfusional iron overload may develop a life-limiting cardiomyopathy. The sensitivity of lipid-metabolizing enzymes to peroxidative injury, as well as the reported effects of arachidonic acid (AA) and metabolites on cardiac rhythm, led us to hypothesize that iron-overloaded cardiomyocytes display alterations in the release of AA and prostaglandins. METHODS AND RESULTS: Neonatal rat ventricular myocytes (NRVMs) cultured for 72 hours in the presence of 80 microgram/mL ferric ammonium citrate displayed an increased rate of AA release, both under resting conditions and after stimulation with agonists such as [Sar(1)]Ang II. Although iron treatment did not affect overall incorporation of [(3)H]AA into NRVM phospholipids, it caused a 2-fold increase in the distribution of precursor in phosphatidylcholine species, with a proportional decrease in phosphatidylinositol, phosphatidylserine, and phosphatidylethanolamine. Increased release of AA in iron-overloaded NRVMs was reduced by the diacylglycerol lipase inhibitor RHC80267 but was largely insensitive to inhibitors of phospholipases A(2) and C. Iron-overloaded cardiomyocytes also displayed increased production of eicosanoids and induction of cyclooxygenase-2 after stimulation with interleukin-1alpha. CONCLUSIONS: Iron overload enhances AA release and incorporation of AA into phosphatidylcholine, as well as cyclooxygenase-2 induction and eicosanoid production, in NRVMS: The effects of AA and metabolites on cardiomyocyte rhythmicity suggest a causal connection between these signals and electromechanical alterations in iron-overload-induced cardiomyopathy.

Interactions of the 5-hydroxytryptamine 3 antagonist class of antiemetic drugs with human cardiac ion channels.

Administration of the 5-hydroxytryptamine 3 receptor class of antiemetic agents has been associated with prolongation in the QRS, JT, and QT intervals of the ECG. To explore the mechanisms underlying these findings, we examined the effects of granisetron, ondansetron, dolasetron, and the active metabolite of dolasetron MDL 74,156 on the cloned human cardiac Na(+) channel hH1 and the human cardiac K(+) channel HERG and the slow delayed rectifier K(+) channel KvLQT1/minK. Using patch-clamp electrophysiology we found that all of the drugs blocked Na(+) channels in a frequency-dependent manner. At a frequency of 3 Hz, the IC(50) values for block of Na(+) current measured 2.6, 88.5, 38.0, and 8.5 microM for granisetron, ondansetron, dolasetron, and MDL 74,156, respectively. Block was relieved by strong hyperpolarizing potentials, suggesting a possible interaction with an inactivated channel state. Recovery from inactivation was impaired at -80 mV compared with -100 mV, and the fractional recovery was impaired by drug in a concentration-dependent manner. IC(50) values for block of the HERG cardiac K(+) channel measured 3.73, 0.81, 5.95, and 12.1 microM for granisetron, ondansetron, dolasetron, and MDL 74,156, respectively. Ondansetron (3 microM) also slowed decay of HERG tail currents. In contrast, none of these drugs (10 microM) produced greater than 30% block of the slow delayed rectifier K(+) channel KvLQT1/minK. We concluded that the antiemetic agents tested in this study block human cardiac Na(+) channels probably by interacting with the inactivated state. This may lead to clinically relevant Na(+) channel blockade, especially when high heart rates or depolarized/ischemic tissue is present. The submicromolar affinity of ondansetron for the HERG K(+) channel likely underlies the prolongation of cardiac repolarization reported for this drug.

KChAP as a chaperone for specific K(+) channels.

The concept of chaperones for K(+) channels is new. Recently, we discovered a novel molecular chaperone, KChAP, which increased total Kv2.1 protein and functional channels in Xenopus oocytes through a transient interaction with the Kv2.1 amino terminus. Here we report that KChAP is a chaperone for Kv1.3 and Kv4.3. KChAP increased the amplitude of Kv1.3 and Kv4.3 currents without affecting kinetics or voltage dependence, but had no such effect on Kv1.1, 1.2, 1.4, 1.5, 1.6, and 3.1 or Kir2.2, HERG, or KvLQT1. Although KChAP belongs to a family of proteins that interact with transcription factors, upregulation of channel currents was not blocked by the transcription inhibitor actinomycin D. A 98-amino acid fragment of KChAP binds to the channel and is indistinguishable from KChAP in its enhancement of Kv4.3 current and protein levels. Using a KChAP antibody, we have coimmunoprecipitated KChAP with Kv2.1 and Kv4.3 from heart. We propose that KChAP is a chaperone for specific Kv channels and may have this function in cardiomyocytes where Kv4.3 produces the transient outward current, I(to).

Decreased sodium and increased transient outward potassium currents in iron-loaded cardiac myocytes. Implications for the arrhythmogenesis of human siderotic heart disease.

BACKGROUND: Patients with chronic iron overload may develop a cardiomyopathy manifested by ventricular arrhythmias and heart failure. We hypothesized that iron-loaded cardiomyocytes may have abnormal excitability. METHODS AND RESULTS: We examined a new model of human iron overload, the Mongolian gerbil given repeated injections of iron dextran. In ventricular myocytes, we measured iron concentration and distribution, action potential, sodium and potassium currents, and sodium channel protein. We showed for the first time that (1) the iron content of gerbil ventricular cardiomyocytes was increased to amounts similar to those of patients with iron-induced cardiomyopathy; (2) the overshoot and duration of the cardiac action potential decreased; (3) sodium current was reduced, steady-state inactivation was enhanced, and single-channel currents were unchanged; and (4) transient outward potassium current was increased, but inwardly rectifying potassium current was unchanged. Neonatal rat cardiomyocytes incubated with iron for 1 to 3 days showed similar changes, and levels of cardiac sodium channel proteins were unchanged. CONCLUSIONS: Abnormal excitability and heterogeneous cardiac iron deposition may cause the arrhythmogenesis of human siderotic heart disease.

Separable effects of human Kvbeta1.2 N- and C-termini on inactivation and expression of human Kv1.4.

1. The Kvbeta subunits of voltage-gated K+ channels alter the functional expression and gating of non- or slowly inactivating Kvalpha1 subunits via two separate domains. To determine how Kvbeta subunits modulate a rapidly inactivating Kvalpha1 subunit, we did two-microelectrode voltage clamp experiments on human Kv1.4 voltage-gated K+ channels expressed heterologously in Xenopus oocytes. In addition we tested a slowly inactivating mutant of Kv1.4 lacking amino acids 2-146 of the N-terminal alpha-ball domain (Kv1. 4DeltaN2-146). Kv1.4 or Kv1.4DeltaN2-146 were co-expressed with either rat Kvbeta2 or human Kvbeta1.2. To separate domain effects, we also used a mutant of Kvbeta1.2 lacking the unique 79 amino acid N-terminal beta-ball domain (Kvbeta1-C). 2. For the mutant Kv1.4DeltaN2-146 we found that Kvbeta1-C or Kvbeta2 increased current amplitude without altering activation or inactivation. By contrast Kvbeta1.2 produced rapid inactivation and slowed deactivation due to block produced by the beta-ball. The beta-ball also increased the rate of C-type inactivation in 5 mM, but not 50 mM, external K+ consistent with an effect of blockade on K+ efflux. 3. For Kv1.4, Kvbeta1-C produced a voltage-independent increase in the rate of inactivation and shifted the inactivation curve to more hyperpolarized potentials, but had no effect on deactivation. Kvbeta1-C, Kvbeta2 and Kvbeta1.2 slowed recovery from inactivation similarly, thereby excluding involvement of the beta-ball. Kvbeta1.2 produced an additional more rapid, voltage-dependent component of inactivation, significantly reduced peak outward current and shifted steady-state inactivation towards hyperpolarized potentials. 4. Yeast two-hybrid studies showed that alpha-beta interaction was restricted to the N-terminus of Kv1.4 and the C-terminus of Kvbeta1. 2 or Kvbeta2. Direct interaction with the alpha-ball did not occur. Our interpretation is that Kvbeta1-C and Kvbeta2 enhanced N-type inactivation produced by the Kv1.4 alpha-ball allosterically. 5. We propose that Kvbeta1.2 has three effects on Kv1.4, the first two of which it shares with Kvbeta2. First, Kvbeta1-C and Kvbeta2 have a current-enhancing effect. Second, Kvbeta1-C and Kvbeta2 increase block by the alpha-ball allosterically. Third, the beta-ball of Kbeta1.2 directly blocks both Kv1.4 and Kv1.4DeltaN2-146. When both alpha- and beta-balls are present, competition for their respective binding sites slows the block produced by either ball.

Cloning and expression of a novel K+ channel regulatory protein, KChAP.

Voltage-gated K+ (Kv) channels are important in the physiology of both excitable and nonexcitable cells. The diversity in Kv currents is reflected in multiple Kv channel genes whose products may assemble as multisubunit heteromeric complexes. Given the fundamental importance and diversity of Kv channels, surprisingly little is known regarding the cellular mechanisms regulating their synthesis, assembly, and metabolism. To begin to dissect these processes, we have used the yeast two-hybrid system to identify cytoplasmic regulatory molecules that interact with Kv channel proteins. Here we report the cloning of a novel gene encoding a Kv channel binding protein (KChAP, for K+ channel-associated protein), which modulates the expression of Kv2 channels in heterologous expression system assays. KChAP interacts with the N termini of Kvalpha2 subunits, as well as the N termini of Kvalpha1 and the C termini of Kvbeta subunits. Kv2.1 and KChAP were coimmunoprecipitated from in vitro translation reactions supporting a direct interaction between the two proteins. The amplitudes of Kv2. 1 and Kv2.2 currents are enhanced dramatically in Xenopus oocytes coexpressing KChAP, but channel kinetics and gating are unaffected. Although KChAP binds to Kv1.5, it has no effect on Kv1.5 currents. We suggest that KChAP may act as a novel type of chaperone protein to facilitate the cell surface expression of Kv2 channels.

Corticotropin releasing hormone inhibits an inwardly rectifying potassium current in rat corticotropes.

1. The perforated-patch-clamp technique was used to identify an inwardly rectifying K+ current (IK(IR)) in cultured rat anterior pituitary cells highly enriched in corticotropes. IK(IR) was rapidly activating and highly selective for K+. The K+ conductance was approximately proportional to the square root of the extracellular K+ concentration. 2. IK(IR) was blocked in a voltage-dependent manner by external Ba2+ and Cs+, slightly attenuated by 5 mM 4-aminopyridine (15% inhibition) and insensitive to 10 mM tetraethylammonium, 2 mM Ca2+, 1 mM Cd2+ and 50 microM La3+. 3. In physiological saline, 100 microM Ba2+, which inhibits 86% of IK(IR) at the cell resting potential, depolarized cells by 6.1 +/- 0.7 mV from a mean resting potential of -59.6 +/- 0.8 mV. 4. Corticotropin releasing hormone (CRH), which activates adenylyl cyclase and stimulates adrenocorticotropic hormone (ACTH) secretion from corticotropes, inhibited IK(IR) by 25% and depolarized the cells by 10.2 +/- 1.0 mV. Dibutyryl cAMP ((Bu)2cAMP) mimicked these effects. 5. The membrane depolarization evoked by Ba2+ or CRH increased the cell firing frequency. Comparison of cells exhibiting a membrane potential of approximately -50 mV revealed that spike frequency in the presence of CRH (109 +/- 7 spikes (5 min)-1) was greater than in control (60 +/- 5 spikes (5 min)-1) or Ba(2+)-treated (77 +/- 15 spikes (5 min)-1) corticotropes. 6. The data suggest that IK(IR) contributes to maintenance of the resting membrane potential of rat corticotropes. Inhibition of IK(IR) plays a role in, but does not account for all of, the membrane depolarization and enhancement of firing frequency evoked by CRH.

Corticotropin-releasing hormone and calcium signaling in corticotropes.

Corticotropin-releasing hormone (CRH) stimulates ACTH secretion from anterior pituitary corticotropes, largely, but possibly not exclusively, via activation of the adenylyl cyclase cascade. CRH stimulates secretion by increasing Ca(2+) influx and by Ca(2+)-independent mechanisms. As Ca(2+) influx is largely regulated by membrane electrical properties, we review the effects of CRH on membrane excitability and changes in cytosolic Ca(2+). We also speculate on possible pathways for CRH modulation of exocytosis by Ca(2+) independent mechanisms.

Corticotropin-releasing hormone stimulates Ca2+ entry through L- and P-type Ca2+ channels in rat corticotropes.

CRH induces corticotrope membrane depolarization and facilitates action potential firing. The increase in electrical excitability causes large oscillatory increases in cytosolic Ca2+ levels. In this study on highly enriched populations of cultured rat corticotropes, inhibitors were used to determine the contribution of the Na+ channel and Ca2+ channel subtypes to membrane excitability and cytosolic Ca2+ levels. Tetrodotoxin, an inhibitor of the voltage-dependent Na+ channel, inhibited a rapid initial component of the action potential, but generally did not influence spontaneous or CRH-induced firing frequency. Tetrodotoxin also had no effect on spontaneous or CRH-induced cytosolic Ca2+ levels. The L-type Ca2+ channel inhibitor nifedipine abolished spontaneous and CRH-induced action potentials and cytosolic Ca2+ transients, but did not eliminate the CRH-induced membrane depolarization or completely restore cytosolic Ca2+ to basal levels. Inhibition of P-type Ca2+ channels with omega-agatoxin-IVA decreased action potential firing frequency and reduced the CRH-induced increase in cytosolic Ca2+. The combination of nifedipine and omega-agatoxin-IVA abolished the CRH-induced rise in Ca2+, but did not abolish the membrane depolarization. Thus, cytosolic Ca2+ is mainly increased by CRH-induced action potentials that are completely dependent on L-type Ca2+ channels and partially regulated by P-type Ca2+ channels. CRH-induced Ca2+ entry also occurs independently of action potentials and is due to P-type, and possibly L-type, Ca2+ channels activated by the CRH-induced membrane depolarization.

Selectivity of ATP-activated GTP-dependent Ca(2+)-permeable channels in rat macrophage plasma membrane.

Outside-out configuration of the patch clamp technique was used to test whether an intracellular application of G protein activator (GTP gamma S) affects ATP-activated Ca(2+)-permeable channels in rat macrophages without any agonist in the bath solution. With 145 mM K+ (pCa 8.0) in the pipette solution, activity of channels permeable to a variety of divalent cations and Na+ was observed and general channel characteristics were found to be identical to those of ATP-activated ones. Absence of extracellular ATP makes it possible to avoid the influence of ATP receptor desensitization and to study the channel selectivity using a number of divalent cations (105 mM) and Na+ (145 mM) as the charge carriers. Permeability sequence estimated by extrapolated reversal potential measurements was: Ca2+:Ba2+:Mn2+:Sr2+: Na+:K+ = 68:30:26:10:3.5:1. Slope conductances (in pS) for permeant ions rank as follows: Ca2+:Sr2+: Na+:Mn2+:Ba2+ = 19:18:14:12:10. Unitary Ca2+ currents display a tendency to saturate with the Ca2+ concentration increase with apparent dissociation constant (Kd) of 10 mM. No block of Na+ permeation by extracellular Ca2+ in millimolar range was found. The data obtained suggest that (i) activation of some G protein is sufficient to gate the channels without the ATP receptor being occupied, (ii) the ATP receptor activation results in the gating of a special channel with the properties that differ markedly from those of the receptor-operated or voltage-gated Ca(2+)-permeable channels on the other cell types.

Three high threshold calcium channel subtypes in rat corticotropes.

In this study on highly enriched populations of cultured rat corticotropes, Ca2+ channel inhibitors were used to identify subtypes of the high threshold Ca2+ channel current under voltage clamp conditions. From a holding potential (-50 mV) that eliminated the low threshold T-type current, 52 +/- 4% of the total current in 10 mM Ba2+ was mediated by dihydropyridine-sensitive L-type Ca2+ channels. Blockade of this current was half-maximal at a nifedipine concentration of 187 nM. omega-Agatoxin-IVA (20 nM) maximally inhibited 28 +/- 3% of the total current. This high sensitivity to omega-agatoxin-IVA indicates that this noninactivating current is mediated by P-type Ca2+ channels. A very high threshold, noninactivating current (23 +/- 4% of the total Ba2+ current) remained after maximal inhibition of L- and P-type Ca2+ channels. This current was also resistant to toxins that inhibit N (omega-conotoxin-GVIA)- and Q (omega-conotoxin-MVIIC)-type Ca2+ channels. Because this current had slow activation kinetics and voltage dependence very different from those of the L- and P-type currents in these cells, it was probably mediated by a third unclassified Ca2+ channel subtype (or subtypes). It is concluded that the high threshold current in corticotropes is due to the presence of at least three different Ca2+ channel subtypes.

Corticotropin-releasing hormone stimulation of Ca2+ entry in corticotropes is partially dependent on protein kinase A.

The modulation of membrane excitability and cytosolic Ca2+ levels by corticotropin-releasing hormone (CRH), (Bu)2cAMP (dBcAMP), and forskolin was examined in enriched populations of cultured rat anterior pituitary corticotropes. CRH (2 or 20 nM), dBcAMP (1 and 5 mM), and forskolin (10 microM) caused a long lasting membrane depolarization accompanied by the onset of cell firing in quiescent cells or by increased firing frequency in spontaneously active cells. All three substances also increased cytosolic Ca2+ levels by increasing the frequency and amplitude of cytosolic Ca2+ transients. These results are consistent with a previous report on human corticotrope tumor cells demonstrating that CRH-induced action potentials lead to enhancement of Ca2+ uptake through voltage-dependent Ca2+ channels. Preincubation with (N-[2-(p-bromocinnamylamino)ethyl]-5-isoquinolinesulfonamide (H-89), an inhibitor of cAMP-dependent protein kinase A, did not inhibit the CRH-induced depolarization, but attenuated the CRH-induced increase in action potential frequency. H-89 inhibited CRH-induced changes in cytosolic Ca2+ by 69% in spontaneously active cells and by 83% in quiescent cells. In contrast, H-89 completely abolished the effects of dBcAMP and forskolin on membrane potential and cytosolic Ca2+ levels. It is concluded that activation of protein kinase A mediates all of the response to dBcAMP and forskolin, but only a portion of the response to CRH. The portion of the response to CRH that is resistant to H-89 is mediated by a cAMP-independent mechanism.

ATP-activated inward current and calcium-permeable channels in rat macrophage plasma membranes.

1. To study mechanisms of receptor-operated Ca2+ influx in non-excitable cells, membrane currents of rat peritoneal macrophages were recorded using whole-cell cell-attached and outside-out configurations of the patch clamp technique. Under whole-cell recording conditions, ATP applied in micromolar concentrations elicited an inward current response when the bath solution contained Ba2+, Ca2+ or Na+ as the only permeant cations. 2. Increasing the Mg2+ concentration had an inhibitory effect on the ATP-induced inward current indicating that the active form of ATP responsible for the cation entry is ATP4-. The nucleotide potency order was ATP > ATP gamma S > ADP. UTP was completely ineffective (n = 19). The data obtained are consistent with the ATP receptor being of the P2Z type. 3. The macrophage plasma membrane was impermeable to Tris+ during the ATP-induced current at ATP4- concentrations varying from 0.07 to 500 microM. At higher concentrations, ATP produced a large inward steady-state current, which could be attributed to membrane permeabilization. 4. Activity of single channels was recorded when ATP was applied to the external surface of the patch membrane both in cell-attached and outside-out experiments. A specific property of the channels appeared to be the existence of at least four conductance sublevels. With 105 mM Ba2+ as the permeant cation, the conductance sublevels were 3.5, 7, 10 and 15 pS. With 10 mM Ca2+ the sublevel conductances were equal to 4, 9, 13 and 17 pS. 5. The unitary conductance estimated from the whole-cell current noise analysis (3.5-4.5 pS for 105 mM Ba2+) was significantly lower than that obtained from single channel measurements at the main (3rd) current level, but it was very close to the conductance of the minimum (1st) level. 6. Extrapolated reversal potential values estimated from current-voltage curves for predominant conductance levels were equal to +40 and +26 mV for 105 mM Ba2+ and 10 mM Ca2+, respectively. The permeability ratios fell in the sequence: PCa:PBa:PK = 71.:29:1. Thus, ATP-activated channels in the macrophage membrane are rather selective for divalent vs. monovalent cations, with the predominant permeability being for Ca2+.

ATP-operated calcium-permeable channels activated via a guanine nucleotide-dependent mechanism in rat macrophages.

1. To elucidate the possible involvement of a G protein in ATP-evoked Ca(2+)-permeable channel activity, membrane currents of rat peritoneal macrophages were recorded using inside-out and cell-attached configurations of the patch clamp technique. 2. In inside-out experiments with a pipette solution containing 105 mM Ba2+, application of 100 microM GTP or GTP gamma S to the internal surface of the membrane elicited a rise in channel activity. This effect was observed in 49% of the patches investigated (n = 69). The mean value of NPo (N, number of open channels; Po, channel open probability) was equal to 0.49 +/- 0.27 (mean +/- S.E.M.; n = 16). The delay in the activity development was 21 +/- 8 s (n = 18) with 200 microM ATP added to the pipette solution and about 4 min (n = 5) without agonist in the pipette. Similar results were obtained with 10 mM Ca2+ as the only permeant cation. 3. Properties of GTP gamma S-evoked channels were identical to those of channels activated by extracellular application of ATP. The channels exhibited at least four conductance sublevels, the 4th one being the least frequent. With 105 mM Ba2+ as a permeant cation, sublevel conductances were 3.5, 7, 10 and 15 pS. Corresponding values for 10 mM Ca2+ were about 4, 9, 13 and 17 pS. Extrapolated reversal potential (Er) values were about +40 and +25 mV for Ba2+ and Ca2+, respectively. 4. The activity of channels with similar characteristics could be induced by the extracellular application of fluoride in cell-attached experiments without any agonist in the pipette solution.(ABSTRACT TRUNCATED AT 250 WORDS)

Evidence for involvement of a GTP-binding protein in activation of Ca2+ influx by epidermal growth factor in A431 cells: effects of fluoride and bacterial toxins.

Aluminium fluoride (AlF4-), a G protein activator, was used to study a possible role of G protein in the control of the pathways for Ca2+ influx through plasma membrane of human carcinoma A431 cells. Fluorimetric measurements with the Ca2+ indicator Indo-1 have shown that addition of fluoride induces an increase in concentration of cytosolic free calcium ([Ca2+]in) due to both release of Ca2+ from intracellular stores and Ca2+ influx from the extracellular medium. The cells stimulated by fluoride became unresponsive to subsequent addition of epidermal growth factor (EGF), histamine and bradykinin. The Ca2+ signal induced by fluoride as well as one induced by EGF was inhibited by the pretreatment of cells with protein kinase C activator, phorbol myristate acetate (PMA). The pretreatment of the cells with pertussis toxin produced no effect on EGF-induced calcium response. In contrast, the pretreatment with cholera toxin (CTX) increased the basal level of [Ca2+]in and abolished the effect of EGF. The effects of CTX could not be reproduced by treating the cells with forskolin or IBMX, agents known to elevate cAMP content in the cell. Patch clamp experiments have shown that fluoride increases the activity of Ca(2+)-permeable channels identical to those activated by EGF from the extracellular side of the membrane [Mozhayeva et al. (1991) J. Membr. Biol. 124, 113-126]. The results obtained suggest the involvement of GTP-binding protein in signal transduction from the EGF receptor to Ca(2+)-permeable channel of plasma membrane in A431 cells.

Multiple conductance levels of calcium-permeable channels activated by epidermal growth factor in A431 carcinoma cells.

Single Ca(2+)-permeable channels were studied in membrane patches from A431 carcinoma cells. Amplitudes of channel openings fell into three major groups with mean unitary conductances of 1.3, 2.4 and 5.1 pS (105 mM Ca2+ in the pipette as charge carrier). All three groups of events were activated with epidermal growth factor (EGF) from the outside and by GTP non-hydrolyzable analogues from the inside of the patch membrane. As a rule, channel openings were uniform in amplitude in each individual patch but sometimes transitions between openings of different conductance levels were seen. It is concluded that the plasma membrane of A431 cells contains a single type of EGF- and GTP-dependent Ca(2+)-permeable channel (or channel complex) that can display, at least, three conductance levels.

ATP-activated Ca(2+)-permeable channels in rat peritoneal macrophages.

The patch-clamp technique was used to study mechanisms of ATP-induced Ca2+ influx in rat peritoneal macrophages. The experiments on whole-cell and patch membranes have shown that extracellular ATP activates channels permeable to di- and monovalent inorganic cations. Ratios of unitary channel conductances in 105 mM Ca2+, Sr2+, Mn2+, Ba2+ and normal sodium solutions were 1.0, 0.95, 0.75, 0.55 and 0.85, respectively. The channels could open in the presence of non-hydrolyzable GTP analogues in artificial intracellular solution. The data are consistent with the hypothesis that a GTP-binding protein is involved in receptor-to-channel coupling.

Calcium-permeable channels activated via guanine nucleotide-dependent mechanism in human carcinoma cells.

Patch clamp experiments on human carcinoma A431 cells have revealed two types of Ca2(+)-permeable channels, the activity of which can be increased by the application of non-hydrolyzable analogues of GTP to the intracellular side of the membrane. With 105 mM Ca2+ in recording pipette at 30-33 degrees C their unitary conductances (in pS) are 1.3 (SG-channels) and 2.4 (G-channels). G- and, possibly, SG-channels are activated from the extracellular side of the membrane with epidermal growth factor (EGF). The data are consistent with the hypothesis that both channels are activated via guanine nucleotide binding (G) proteins.

Inositol 1,4,5-trisphosphate activates two types of Ca2(+)-permeable channels in human carcinoma cells.

Ca2(+)-permeable channels in human carcinoma A431 cells were studied using the patch clamp technique. We have found two types of Ca2(+)-permeable channels which are activated by inositol 1,4,5-trisphosphate (IP3) applied to the intracellular side of the plasma membrane. Unitary conductances of these channels are 3.7 and 13 pS (105 mM Ca2+ in recording pipette, 30-33 degrees C). From the extracellular side of the membrane the channels are activated by EGF. It is assumed that extracellular agonists open both channel types by stimulating the release of IP3 from the membrane.