ATP-dependent activation of the intermediate conductance, Ca2+-activated K+ channel, hIK1, is conferred by a C-terminal domain

We previously demonstrated that hIK1 is activated directly by ATP in excised, inside-out patches in a protein kinase A inhibitor 5-24 dependent manner, suggesting a role for phosphorylation in the regulation of this Ca(2+)-dependent channel. However, mutation of the single consensus cAMP-dependent protein kinase phosphorylation site (S334A) failed to modify the response of hIK1 to ATP (Gerlach, A. C., Gangopadhyay, N. N., and Devor, D. C. (2000) J. Biol. Chem. 275, 585-598). Here we demonstrate that ATP does not similarly activate the highly homologous Ca(2+)-dependent K(+) channels, hSK1, rSK2, and rSK3. To define the region of hIK1 responsible for the ATP-dependent regulation, we generated a series of hIK1 truncations and hIK1/rSK2 chimeras. ATP did not activate a chimera containing the N terminus plus S1-S4 from hIK1. In contrast, ATP activated a chimera containing the hIK1 C-terminal amino acids His(299)-Lys(427). Furthermore, truncation of hIK1 at Leu(414) resulted in an ATP-dependent channel, whereas larger truncations of hIK1 failed to express. Additional hIK1/rSK2 chimeras defined the minimal region of hIK1 required to confer complete ATP sensitivity as including amino acids Arg(355)-Ala(413). An alanine scan of all non-conserved serines and threonines within this region failed to alter the response of hIK1 to ATP, suggesting that hIK1 itself is not directly phosphorylated. Additionally, substitution of amino acids Arg(355)-Met(368) of hIK1 into the corresponding region of rSK2 resulted in an ATP-dependent activation, which was approximately 50% of that of hIK1. These results demonstrate that amino acids Arg(355)-Ala(413) within the C terminus of hIK1 confer sensitivity to ATP. Finally, we demonstrate that the ATP-dependent phosphorylation of hIK1 or an associated protein is independent of Ca(2+).     

ATP-dependent activation of the intermediate conductance, Ca2+-activated K+ channel, hIK1, is conferred by a C-terminal domain.

We previously demonstrated that hIK1 is activated directly by ATP in excised, inside-out patches in a protein kinase A inhibitor 5-24 dependent manner, suggesting a role for phosphorylation in the regulation of this Ca(2+)-dependent channel. However, mutation of the single consensus cAMP-dependent protein kinase phosphorylation site (S334A) failed to modify the response of hIK1 to ATP (Gerlach, A. C., Gangopadhyay, N. N., and Devor, D. C. (2000) J. Biol. Chem. 275, 585-598). Here we demonstrate that ATP does not similarly activate the highly homologous Ca(2+)-dependent K(+) channels, hSK1, rSK2, and rSK3. To define the region of hIK1 responsible for the ATP-dependent regulation, we generated a series of hIK1 truncations and hIK1/rSK2 chimeras. ATP did not activate a chimera containing the N terminus plus S1-S4 from hIK1. In contrast, ATP activated a chimera containing the hIK1 C-terminal amino acids His(299)-Lys(427). Furthermore, truncation of hIK1 at Leu(414) resulted in an ATP-dependent channel, whereas larger truncations of hIK1 failed to express. Additional hIK1/rSK2 chimeras defined the minimal region of hIK1 required to confer complete ATP sensitivity as including amino acids Arg(355)-Ala(413). An alanine scan of all non-conserved serines and threonines within this region failed to alter the response of hIK1 to ATP, suggesting that hIK1 itself is not directly phosphorylated. Additionally, substitution of amino acids Arg(355)-Met(368) of hIK1 into the corresponding region of rSK2 resulted in an ATP-dependent activation, which was approximately 50% of that of hIK1. These results demonstrate that amino acids Arg(355)-Ala(413) within the C terminus of hIK1 confer sensitivity to ATP. Finally, we demonstrate that the ATP-dependent phosphorylation of hIK1 or an associated protein is independent of Ca(2+).     

Calcium ion-dependent p-nitrophenyl phosphate phosphatase activity and calcium ion-dependent adenosine triphosphatase activity from human erythrocyte membranes

In the presence of ATP and of Mg(2+), human erythrocyte membranes show a phosphatase activity towards p-nitrophenyl phosphate which is activated by low concentrations of Ca(2+). The effect of Ca(2+) is strongly enhanced if either K(+) or Na(+) is also present. Activation of the p-nitrophenyl phosphate phosphatase by Ca(2+) reaches a half-maximum at about 8mum-Ca(2+) and is apparent only when the ion has access to the inner surface of the cell membrane. Ca(2+)-dependent phosphatase activity can only be observed if ATP is at the inner surface of the cell membrane, and the presence of ATP seems to be absolutely necessary, since either its removal or its replacement by other nucleoside triphosphates abolishes the activating effect of Ca(2+). The properties of the (ATP+Ca(2+))-dependent phosphatase are very similar to those of the Ca(2+)-dependent ATPase (adenosine triphosphatase), also present in erythrocyte membranes, which probably is involved in Ca(2+) transport in erythrocytes. The similarities suggest that both activities may be properties of the same molecular system. This view is further supported by the fact that p-nitrophenyl phosphate inhibits to a similar extent Ca(2+)-dependent ATPase activity and ATP-dependent Ca(2+) extrusion from erythrocytes.     

Activation of the human intermediate-conductance Ca(2+)-activated K(+) channel by 1-ethyl-2-benzimidazolinone is strongly Ca(2+)-dependent.

Modulation of the cloned human intermediate-conductance Ca(2+)-activated K(+) channel (hIK) by the compound 1-ethyl-2-benzimidazolinone (EBIO) was studied by patch-clamp technique using human embryonic kidney cells (HEK 293) stably expressing the hIK channels. In whole-cell studies, intracellular concentrations of free Ca(2+) were systematically varied, by buffering the pipette solutions. In voltage-clamp, the hIK specific currents increased gradually from 0 to approximately 300 pA/pF without reaching saturation even at the highest Ca(2+) concentration tested (300 nM). In the presence of EBIO (100 microM), the Ca(2+)-activation curve was shifted leftwards, and maximal currents were attained at 100 nM Ca(2+). In current-clamp, steeply Ca(2+)-dependent membrane potentials were recorded and the cells gradually hyperpolarised from -20 to -85 mV when Ca(2+) was augmented from 0 to 300 nM. EBIO strongly hyperpolarised cells buffered at intermediate Ca(2+) concentrations. In contrast, no effects were detected either below 10 nM (no basic channel activation) or at 300 nM Ca(2+) (V(m) close to E(K)). Without Ca(2+), EBIO-induced hyperpolarisations were not obtainable, indicating an obligatory Ca(2+)-dependent mechanism of action. When applied to inside-out patches, EBIO exerted a Ca(2+)-dependent increase in the single-channel open-state probability, showing that the compound modulates hIK channels by a direct action on the alpha-subunit or on a closely associated protein. In conclusion, EBIO activates hIK channels in whole-cell and inside-out patches by a direct mechanism, which requires the presence of internal Ca(2+).     

Activation of erythrocyte Ca2+-plus-Mg2+-stimulated adenosine triphosphatase by protein kinase (cyclic AMP-dependent) inhibitor. Comparison with calmodulin

Purified protein kinase (cyclic AMP-dependent) inhibitor (PKI) from bovine heart stimulated Ca(2+)+Mg(2+)-stimulated ATPase activity in human erythrocytes, the stimulation being maximal at 2mug/0.6ml. By contrast, PKI from rabbit skeletal muscle had no effect. Bovine heart PKI stimulated Ca(2+)+Mg(2+)-stimulated ATPase by increasing the Ca(2+)-sensitivity of the enzyme. This contrasted with the stimulation by calmodulin, which increased the maximum velocity of the Ca(2+)+Mg(2+)-dependent ATPase in addition to its effect on the Ca(2+)-sensitivity. Both membrane-bound and Triton X-100-solubilized Ca(2+)+Mg(2+)-stimulated ATPase activities were stimulated by PKI, indicating that the stimulation did not require an intact membrane structure. At low Ca(2+) concentration the stimulation by PKI and saturating concentrations of calmodulin were additive, suggesting that the two effectors acted by distinct mechanisms. Although 5mum-cyclic AMP inhibited Ca(2+)+Mg(2+)-stimulated ATPase activity by about 20% when measured at low ATP concentrations, probably by stimulation of phosphorylation by an endogenous protein kinase, the stimulation by PKI (about 100%) was not solely due to its antagonism of the protein kinase. This interpretation was supported by a number of observations. First, modification of arginine residues of bovine heart PKI abolished its inhibition of cyclic AMP-dependent protein kinase, but had no effect on the stimulation of Ca(2+)+Mg(2+)-stimulated ATPase. Secondly, trifluoperazine (20mum) antagonized the stimulation of Ca(2+)+Mg(2+)-dependent ATPase by PKI, similarly to its antagonism of calmodulin stimulation, but it did not affect the inhibition of protein kinase by PKI. We conclude that different mechanisms are involved in the inhibition of protein kinase and the stimulation of Ca(2+)+Mg(2+)-stimulated ATPase by PKI.     

Calcium inhibition of the ATPase and phosphatase activities of (Na+ + K+)-ATPase

In experiments performed at 37 degrees C, Ca2+ reversibly inhibits the Na+-and (Na+ + K+)-ATPase activities and the K+-dependent phosphatase activity of (Na+ + K+)-ATPase. With 3 mM ATP, the Na+-ATPase was less sensitive to CaCl2 than the (Na+ + K+)-ATPase activity. With 0.02 mM ATP, the Na+-ATPase and the (Na+ + K+)-ATPase activities were similarly inhibited by CaCl2. The K0.5 for Ca2+ as (Na+ + K+)-ATPase inhibitor depended on the total MgCl2 and ATP concentrations. This Ca2+ inhibition could be a consequence of Ca2+-Mg2+ competition, Ca . ATP-Mg . ATP competition or a combination of both mechanisms. In the presence of Na+ and Mg2+, Ca2+ inhibited the K+-dependent dephosphorylation of the phosphoenzyme formed from ATP, had no effect on the dephosphorylation in the absence of K+ and inhibited the rephosphorylation of the enzyme. In addition, the steady-state levels of phosphoenzyme were reduced in the presence both of NaCl and of NaCl plus KCl. With 3 mM ATP, Ca2+ alone sustained no more than 2% of the (Na+ + K+)-ATPase activity and about 23% of the Na+-ATPase activity observed with Mg2+ and no Ca2+. With 0.003 mM ATP, Ca2+ was able to maintain about 40% of the (Na+ + K+)-ATPase activity and 27% of the Na+-ATPase activity seen in the presence of Mg2+ alone. However, the E2(K)-E1K conformational change did not seem to be affected. Ca2+ inhibition of the K+-dependent rho-nitrophenylphosphatase activity of the (Na+ + K+)-ATPase followed competition kinetics between Ca2+ and Mg2+. In the presence of 10 mM NaCl and 0.75 mM KCl, the fractional inhibition of the K+-dependent rho-nitrophenylphosphatase activity as a function of Ca2+ concentration was the same with and without ATP, suggesting that Ca2+ indeed plays the important role in this process. In the absence of Mg2+, Ca2+ was unable to sustain any detectable ouabain-sensitive phosphatase activity, either with rho-nitrophenylphosphate or with acetyl phosphate as substrate.     

Regulation of a human chloride channel. a paradigm for integrating input from calcium, type ii calmodulin-dependent protein kinase, and inositol 3,4,5,6-tetrakisphosphate

We have studied the regulation of Ca(2+)-dependent chloride (Cl(Ca)) channels in a human pancreatoma epithelial cell line (CFPAC-1), which does not express functional cAMP-dependent cystic fibrosis transmembrane conductance regulator chloride channels. In cell-free patches from these cells, physiological Ca(2+) concentrations activated a single class of 1-picosiemens Cl(-)-selective channels. The same channels were also stimulated by a purified type II calmodulin-dependent protein kinase (CaMKII), and in cell-attached patches by purinergic agonists. In whole-cell recordings, both Ca(2+)- and CaMKII-dependent mechanisms contributed to chloride channel stimulation by Ca(2+), but the CaMKII-dependent pathway was selectively inhibited by inositol 3,4,5,6-tetrakisphosphate (Ins(3,4,5,6)P(4)). This inhibitory effect of Ins(3,4,5,6)P(4) on Cl(Ca) channel stimulation by CaMKII was reduced by raising [Ca(2+)] and prevented by inhibition of protein phosphatase activity with 100 nm okadaic acid. These data provide a new context for understanding the physiological relevance of Ins(3,4,5,6)P(4) in the longer term regulation of Ca(2+)-dependent Cl(-) fluxes in epithelial cells.     

The evaluation of the role of endogenous Ca-dependent regulators and protein kinases in activating and inhibiting ion-transport ATPases]

The data on hormonal regulation of ATP-driving ion pumps are contradictory depending on the object used: whether native cells or isolated membranes. To eliminate this contrariety, we studied the ion transporting ATPases in saponin-permeabilized cells in the presence of all endogenous regulators. In permeabilized erythrocytes we obtained the presence of Ca(2+)-dependent activation of Ca(2+)-ATPase by factor(s) not affected by calmodulin antagonist R24571. We obtained also Ca(2+)-dependent activation and inhibition of Na+,K(+)-ATPase. At a concentration of Mg(2+)-ions corresponding to the intracellular level (370 microM), the 0.5-0.7 microM Ca(2+)-activated Na+,K(+)-ATPase (up to 3-fold), whereas the 1-5 microM Ca2+ inhibited it. The cyclic AMP (10(-5) M) inhibited or eliminated Ca(2+)-dependent activation. The decrease in Mg(2+)-ion concentration to 50 microM eliminated the activation and strengthened the inhibition, which reached 100% at the 1-2 microM Ca2+ concentration. The washing of membranes with EGTA eliminated Ca2+ effects on Na+,K(+)-ATPase. These data suggest that the ion-transporting ATPases are activated or inhibited by Ca(2+)-dependent regulators whose activities may be changed by protein kinase catalysed phosphorylation.     

Reversible inhibition of (Na+, K+) ATPase by Mg2+, adenosine triphosphate, and K+.

Adenosine triphosphate (ATP) hydrolysis catalyzed by the plasma membrane (Na+,K+)ATPase isolated from several sources was inhibited by Mg+, provided that K+ and ATP were also present. Phosphorylation of the adenosine triphosphatase (ATPase) by ATP and by inorganic phosphate was also inhibited, as was p-nitrophenyl phosphatase activity. (Ethylenedinitrilo)tetraacetic acid (EDTA) and catecholamines protected from and reversed the inhibition of ATP hydrolysis by Mg2+, K+ and ATP. EDTA was protected by chelation of Mg2+ but catecholamines acted by some other mechanism. The specificities of various nucleotides as inhibitors (in conjunction with Mg2+ and K+) and as substrates for the (Na+, K+) ATPase were strikingly different. ATP, ADP, beta,gamma-CH2-ATP and alpha,beta-CH2-ADP were active as inhibitors, whereas inosine, cytidine, uridine, and guanosine triphosphates (ITP, CTP, UTP, and GTP) and adenosine monophosphate (AMP) were not. On the other hand, ATP and CTP were substrates and beta,gamma-NH-ATP was a competitive inhibitor of ATP hydrolysis, but not an inhibitor in conjunction with Mg2+ and K+. The Ca2+-ATPase from sarcoplasmic reticulum and F1, the Mg2+-ATPase from the inner mitochondrial membrane, were also inhibited by Mg2+. Catecholamines reversed inhibition of the Ca2+-ATPase, but not that of F1.     

ATPase and phosphatase activities from human red cell membranes: I. The effects of N-ethylmaleimide.

In human red cell membranes the sensitivity to N-ethylmaleimide of Ca2+-dependent ATPase and phosphatase activities is at least ten times larger than the sensitivity to N-ethylmaleimide of (Na+ + K+)-ATPase and K+-activated phosphatase activities. All activities are partially protected against N-ethylmaleimide by ATP but not by inorganic phosphate or by p-nitrophenylphosphate. (ii) Protection by ATP of (Na+ + K+)-ATPase is impeded by either Na+ or K+ whereas only K+ impedes protection by ATP of K+-activated phosphatase. On the other hand, Na+ or K+ slightly protects Ca2+-dependent activities against N-ethylmaleimide, this effect being independent of ATP. (iii) The sensitivity to N-ethylmaleimide of Ca2+-dependent ATPase and phosphatase activities is markedly enhanced by low concentrations of Ca2+. This effect is half-maximal at less than 1 micron Ca2+ and does not require ATP, which suggests that sites with high affinity for Ca2+ exist in the Ca2+-ATPase in the absence of ATP. (IV) Under all conditions tested the response to N-ethylmaleimide of the ATPase and phosphatase activities stimulated by K+ or Na+ in the presence of Ca2+ parallels that of the Ca2+-dependent activities, suggesting that the Ca2+-ATPase system possesses sites at which monovalent cations bind to increase its activity.     

AlF4- reversibly inhibits ''P''-type cation-transport ATPases, possibly by interacting with the phosphate-binding site of the ATPase.

The only known cellular action of AlF4- is to stimulate the G-proteins. The aim of the present work is to demonstrate that AlF4- also inhibits 'P'-type cation-transport ATPases. NaF plus AlCl3 completely and reversibly inhibits the activity of the purified (Na+ + K+)-ATPase (Na+- and K+-activated ATPase) and of the purified plasmalemmal (Ca2+ + Mg2+)-ATPase (Ca2+-stimulated and Mg2+-dependent ATPase). It partially inhibits the activity of the sarcoplasmic-reticulum (Ca2+ + Mg2+)-ATPase, whereas it does not affect the mitochondrial H+-transporting ATPase. The inhibitory substances are neither F- nor Al3+ but rather fluoroaluminate complexes. Because AlF4- still inhibits the ATPase in the presence of guanosine 5'-[beta-thio]diphosphate, and because guanosine 5'-[beta gamma-imido]triphosphate does not inhibit the ATPase, it is unlikely that the inhibition could be due to the activation of an unknown G-protein. The time course of inhibition and the concentrations of NaF and AlCl3 required for this inhibition differ for the different ATPases. AlF4- inhibits the (Na+ + K+)-ATPase and the plasmalemmal (Ca2+ + Mg2+)-ATPase noncompetitively with respect to ATP and to their respective cationic substrates, Na+ and Ca2+. AlF4- probably binds to the phosphate-binding site of the ATPase, as the Ki for inhibition of the (Na+ + K+)-ATPase and of the plasmalemmal (Ca2+ + Mg2+)-ATPase is shifted in the presence of respectively 5 and 50 mM-Pi to higher concentrations of NaF. Moreover, AlF4- inhibits the K+-activated p-nitrophenylphosphatase of the (Na+ + K+)-ATPase competitively with respect to p-nitrophenyl phosphate. This AlF4- -induced inhibition of 'P'-type cation-transport ATPases warns us against explaining all the effects of AlF4- on intact cells by an activation of G-proteins.     

Calmodulin and ATP dependence of the high and low calcium affinity p-nitrophenylphosphatase from human erythrocyte membranes

In calmodulin depleted membranes from human erythrocytes, the Ca2+-dependent phosphatase showed different sensitivity to calmodulin and ATP with variable affinity towards free calcium concentrations: a calmodulin-dependent activity with high calcium affinity, K1/2 = 1.2 X 10(-7) mol/l calcium, that was fully activated at submicromolar calcium concentrations, higher concentrations being rather inhibitory; an ATP-dependent activity with lower calcium affinity, K1/2 = 10(-6) mol/l calcium, that was fully activated at 10(-5) mol/l calcium in the presence of 50-200 mumol/l ATP and was insensitive to calmodulin, and a calcium dependent phosphatase that was active at a wider ranger of free calcium, 10(-8)-10(-5) mol/l, and required the presence of both calmodulin and ATP.     

The phosphatase activity of the plasma membrane Ca2+ pump. Activation by acidic lipids in the absence of Ca2+ increases the apparent affinity for Mg2+

The purified PMCA supplemented with phosphatidylcholine was able to hydrolyze pNPP in a reaction media containing only Mg(2+) and K(+). Micromolar concentrations of Ca(2+) inhibited about 75% of the pNPPase activity while the inhibition of the remainder 25% required higher Ca(2+) concentrations. Acidic lipids increased 5-10 fold the pNPPase activity either in the presence or in the absence of Ca(2+). The activation by acidic lipids took place without a significant change in the apparent affinities for pNPP or K(+) but the apparent affinity of the enzyme for Mg(2+) increased about 10 fold. Thus, the stimulation of the pNPPase activity of the PMCA by acidic lipids was maximal at low concentrations of Mg(2+). Although with differing apparent affinities vanadate, phosphate, ATP and ADP were all inhibitors of the pNPPase activity and their effects were not significantly affected by acidic lipids. These results indicate that (a) the phosphatase function of the PMCA is optimal when the enzyme is in its activated Ca(2+) free conformation (E2) and (b) the PMCA can be activated by acidic lipids in the absence of Ca(2+) and the activation improves the interaction of the enzyme with Mg(2+).     

An NH2-terminal multi-basic RKR motif is required for the ATP-dependent regulation of hIK1

We previously demonstrated that the ATP/PKA-dependent activation of the human intermediate conductance, Ca2+-activated K+ channel, hIK1, is dependent upon a C-terminal motif. The NH2-terminus of hIK1 contains a multi-basic 13RRRKR17 motif, known to be important in the trafficking and function of ion channels. While individual mutations within this domain have no effect on channel function, the triple mutation (15RKR17/AAA), as well as additional double mutations, result in a near complete loss of functional channels, as assessed by whole-cell patch-clamp. However, cell-surface immunoprecipitation studies confirmed expression of these mutated channels at the plasma membrane. To elucidate the functional consequences of the (15)RKR(17)/AAA mutation we performed inside-out patch clamp recordings where we observed no difference in Ca2+ affinity between the wild-type and mutated channels. However, in contrast to wild-type hIK1, channels expressing the 15RKR17/AAA mutation exhibited rundown, which could not be reversed by the addition of ATP. Wild-type hIK1 channel activity was reduced by alkaline phosphatase both in the presence and absence of ATP, indicative of a phosphorylation event, whereas the 15RKR17/AAA mutation eliminated this effect of alkaline phosphatase. Further, single channel analysis demonstrated that the 15RKR17/AAA mutation resulted in a four-fold lower channel open probability (P(o)), in the presence of saturating Ca2+ and ATP, compared to wild-type hIK1. In conclusion, these results represent the first demonstration for a role of the NH2-terminus in the second messenger-dependent regulation of hIK1 and, in combination with our previous findings, suggest that this regulation is dependent upon a close NH2/C-terminal association.     

Characterisation of an ATP-dependent Ca2+ transport system in a plasma membrane enriched fraction from rat parotid

A membrane fraction enriched in plasma membrane marker enzymes K+-dependent p-nitrophenyl phosphatase, 5'-nucleotidase and alkaline phosphatase was prepared from rat parotid glands using Percoll self-forming gradient. This fraction contained an ATP-dependent CA2+ transport system which was distinct from those located on the endoplasmic reticulum and mitochondria of parotid glands. The Km for ATP was 0.57 +/- 0.07 mM (n = 3). Nucleotides other than ATP such as ADP, AMP, GTP, CTP, UTP or ITP were unable to support significant Ca2+ uptake. ATP-dependent Ca2+ uptake displayed sigmoidal kinetics with respect to free Ca2+ concentration with a Hill coefficient of 2.02. The K0.5 for Ca2+ was 44 +/- 3.1 nM (n = 3) and the average Vmax was 13.5 +/- 1.1 nmol/min per mg of protein. The pH optimum was 7.2. Trifluorperazine inhibited Ca2+ transport with half maximal inhibition observed at 30.8 microM. Complete inhibition was observed at 70 microM trifluorperazine. Exogenous calmodulin however had no effect on the rate of transport. Na+ and K+ ions activated Ca2+ transport at 20 to 30 mM ion concentrations. Higher concentrations of Na+ or K+ were inhibitory.     

The uptake and release of calcium by heart mitochondria

The kinetics of uptake of Ca(2+) by rat heart mitochondria were studied by a spectrophotometric method with Arsenazo III indicator. The exponential rate coefficients measured with or without added phosphate increase with the amount of Ca(2+) added up to about 24mum. Evidence is given that the effect is attributable to a combination of formation of chelates at low concentrations to act as Ca(2+) buffers, with co-transport of substrate to provide more respiratory fuel. The inhibitory effect of Mg(2+) depends on the Ca(2+) concentration, so with a constant [Mg(2+)] the low concentrations of Ca(2+) are most inhibited, and the rate coefficients are still more Ca(2+)-dependent. Ca(2+) uptake is slowed by local anaesthetics such as butacaine and dibucaine, and also by propranolol and palmitoyl-CoA. After an uptake, the release of Ca(2+) was investigated. The spontaneous release involves an initially slow and small appearance of free Ca(2+) and is followed by an auto-accelerated phase. The release is accompanied by a gradual decrease in internal ATP; it is initiated by palmitoyl-CoA (reversed by carnitine), by lysophosphatidylcholine, by Na(+) salts (reversed by oligomycin) and by K(+) salts added to a K(+)-free medium containing valinomycin. The process is probably a response to an increased energy load imposed on the mitochondria by the various conditions, which include the spontaneous action of phospholipase activated by traces of Ca(2+). The problem of how much mitochondrial activity is participating in normal heart Ca(2+) turnover is discussed, and experiments showing only 7-14% exchange of the mitochondrial Ca(2+) occurring in vivo in 10 or 20min are reported.     

Modeling regulation of cardiac KATP and L-type Ca2+ currents by ATP, ADP, and Mg2+

Changes in cytosolic free Mg(2+) and adenosine nucleotide phosphates affect cardiac excitability and contractility. To investigate how modulation by Mg(2+), ATP, and ADP of K(ATP) and L-type Ca(2+) channels influences excitation-contraction coupling, we incorporated equations for intracellular ATP and MgADP regulation of the K(ATP) current and MgATP regulation of the L-type Ca(2+) current in an ionic-metabolic model of the canine ventricular myocyte. The new model: 1), quantitatively reproduces a dose-response relationship for the effects of changes in ATP on K(ATP) current, 2), simulates effects of ADP in modulating ATP sensitivity of K(ATP) channel, 3), predicts activation of Ca(2+) current during rapid increase in MgATP, and 4), demonstrates that decreased ATP/ADP ratio with normal total Mg(2+) or increased free Mg(2+) with normal ATP and ADP activate K(ATP) current, shorten action potential, and alter ionic currents and intracellular Ca(2+) signals. The model predictions are in agreement with experimental data measured under normal and a variety of pathological conditions.     

Functional properties of sarcoplasmic reticulum Ca(2+)-ATPase after proteolytic cleavage at Leu119-Lys120, close to the A-domain

By measuring the phosphorylation levels of individual proteolytic fragments of SERCA1a separated by electrophoresis after their phosphorylation, we were able to study the catalytic properties of a p95C-p14N complex arising from SERCA1a cleavage by proteinase K between Leu(119) and Lys(120), in the loop linking the A-domain with the second transmembrane segment. ATP hydrolysis by the complex was very strongly inhibited, although ATP-dependent phosphorylation and the conversion of the ADP-sensitive E1P form to E2P still occurred at appreciable rates. However, the rate of subsequent dephosphorylation of E2P was inhibited to a dramatic extent, and this was also the case for the rate of "backdoor" formation of E2P from E2 and P(i). E2P formation from E2 at equilibrium nevertheless indicated little change in the apparent affinity for P(i) or Mg(2+), while binding of orthovanadate was weaker. The p95C-p14N complex also had a slightly reduced affinity for Ca(2+) and exhibited a reduced rate for its Ca(2+)-dependent transition from E2 to Ca(2)E1. Thus, disruption of the N-terminal link of the A-domain with the transmembrane region seems to shift the conformational equilibria of Ca(2+)-ATPase from the E1/E1P toward the E2/E2P states and to increase the activation energy for dephosphorylation of Ca(2+)-ATPase, reviving the old idea of the A-domain being a phosphatase domain as part of the transduction machinery.     

Regulation of the calcium release channel from skeletal muscle by suramin and the disulfonated stilbene derivatives DIDS,DBDS, and DNDS

Activation of skeletal muscle ryanodine receptors (RyRs) by suramin and disulfonic stilbene derivatives (Diisothiocyanostilbene-2',2'-disulfonic acid (DIDS), 4,4'-dibenzamidostilbene-2,2'-disulfonic acid (DBDS),and 4,4'-dinitrostilbene-2,2'-disulfonic acid (DNDS)) was investigated using planar bilayers. One reversible and two nonreversible mechanisms were identified. K(a) for reversible activation (approximately 100 micro M) depended on cytoplasmic [Ca(2+)] and the bilayer composition. Replacement of neutral lipids by negative phosphatidylserine increased K(a) fourfold, suggesting that reversible binding sites are near the bilayer surface. Suramin and the stilbene derivatives adsorbed to neutral bilayers with maximal mole fractions between 1-8% and with affinities approximately 100 micro M but did not adsorb to negative lipids. DIDS activated RyRs by two nonreversible mechanisms, distinguishable by their disparate DIDS binding rates (10(5) and 60 M(-1) s(-1)) and actions. Both mechanisms activated RyRs via several jumps in open probability, indicating several DIDS binding events. The fast and slow mechanisms are independent of each other, the reversible mechanism and ATP binding. The fast mechanism confers DIDS sensitivity approximately 1000-fold greater than previously reported, increases Ca(2+) activation and increases K(i) for Ca(2+)/Mg(2+) inhibition 10-fold. The slow mechanism activates RyRs in the absence of Ca(2+) and ATP, increases ATP activation without altering K(a), and slightly increases activity at pH < 6.5. These findings explain how different types of DIDS activation are observed under different conditions.     

Regulation of a calcium-sensitive K+ channel (cIK1) by protein kinase C

Ca2+-sensitive K+ channels (IK1 channels) are required for many physiological functions such as cell proliferation, epithelial transport or cell migration. They are regulated by the intracellular Ca2+ concentration and by phosphorylation-dependent reactions. Here, we investigate by means of the patch-clamp technique mechanisms by which protein kinase C (PKC) regulates the canine isoform, cIK1, cloned from transformed renal epithelial (MDCK-F) cells. cIK1 elicits a K+-selective, inwardly rectifying, and Ca2+-dependent current when expressed in HEK293 or CHO cells. It is inhibited by charybdotoxin, clotrimazole, and activated by 1-ethyl-2-benzimidazolone. cIK1 is activated by intracellular application of ATP or ATP[gS]. ATP-dependent activation is reversed by PKC inhibitors (bisindolylmaleimide, calphostin C), while stimulation with ATP[gS] resists PKC inhibition. Stimulation of protein kinase C with phorbol 12-myristate 13-acetate (PMA) leads to the acute activation of cIK1 currents, which are blocked by PKC inhibitors. In contrast, PKC depletion by overnight incubation with PMA prevents ATP-dependent cIK1 activation. Neither single mutations nor the simultaneous mutation of all PKC sites (T101, S178, T329) to alanine alter the acute regulation of cIK1 channels by PKC. However, current amplitudes of CIK1-T329A and the triple mutant are dramatically increased upon long-term treatment with PMA. These mutations thereby disclose an inhibitory effect on cIKl current of the PKC site at T329. Our results indicate that cIK1 channel activity is regulated in two ways. PKC-dependent activation of cIK1 channels occurs indirectly, while the inhibitory effect probably requires a direct interaction with the channel protein.