ATP-sensitive voltage- and calcium-dependent chloride channels in sarcoplasmic reticulum vesicles from rabbit skeletal muscle

Chloride channels in the sarcoplasmic reticulum (SR) are thought to play an essential role in excitation-contraction (E-C) coupling by balancing charge movement during calcium release and uptake. In this study the nucleotide-sensitivity of Cl⁻ channels in the SR from rabbit skeletal muscle was investigated using the lipid bilayer technique. Two distinct ATP-sensitive Cl⁻ channels that differ in their conductance and kinetic properties and in the mechanism of ATP-induced channel inhibition were observed. The first, a nonfrequent 150 pS channel was inhibited by trans (luminal) ATP, and the second, a common 75 pS small chloride (SCl) channel was inhibited by cis (cytoplasmic) ATP. In the case of the SCl channel the ATP-induced reversible decline in the values of current (maximal current amplitude, I _max and integral current, I′) and kinetic parameters (frequency of opening F _O , probability of the channel being open P _O , mean open T _O and closed T _c times) show a nonspecific block of the voltage- and Ca²⁺-dependent SCl channel. ATP was a more potent blocker from the cytoplasmic side than from the luminal side of the channel. The SCl channel block was not due to Ca²⁺ chelation by ATP, nor to phosphorylation of the channel protein. The inhibitory action of ATP was mimicked by the nonhydrolyzable analogue adenylylimidodiphosphate (AMP-PNP) in the absence of Mg²⁺. The inhibitory potency of the adenine nucleotides was charge dependent in the following order ATP⁴⁻ > ADP³⁻ > > > AMP²⁻. The data suggest that ATP-induced effects are mediated via an open channel block mechanism. Modulation of the SCl channel by [ATP] _cis and [Ca²⁺] _cis indicates that (i) this channel senses the bioenergetic state of the muscle fiber and (ii) it is linked to the ATP-dependent cycling of the Ca²⁺ between the SR and the sarcoplasm. Received: 4 September 1996/Revised: 6 December 1996     

Tight Junction Dynamics: Oscillations and the Role of Protein Kinase C

The present study aimed to characterize the role of protein kinase C (PKC) on the dynamics of tight junction (TJ) opening and closing in the frog urinary bladder. The early events of TJ dynamics were evaluated by the fast Ca⁺⁺ switch assay (FCSA), which consisted in opening the TJs by removing basolateral Ca⁺⁺ ([Ca⁺⁺] _bl ), and closing them by returning [Ca⁺⁺] _bl to normal values. Changes in TJ permeability can be reliably gauged through changes of transepithelial electrical conductance (G) determined in the absence of apical Na⁺. The FCSA allows the appraisal of drugs and procedures acting upon the mechanism controlling the TJs. The time courses of TJ opening and closing in an FCSA were shown to follow single exponential time courses. PKC inhibition by H7 (100 μm) caused a reduction of the rate of junction opening in response to removing [Ca⁺⁺] _bl , without affecting junction closing, indicating that PKC is a key element in the control of TJ opening dynamics in this preparation. H7 at 250 μm almost completely inhibits TJ opening in response to basolateral Ca⁺⁺ withdrawal. Subsequent H7 removal caused a prompt inhibition release characterized by a sharp G increase which, however, once started cannot be stopped by H7 reintroduction, Ca⁺⁺ being necessary to allow TJ recovery. A step rise of apical Ca⁺⁺ concentration ([Ca⁺⁺] _ap ) causes a reduction of the rate of TJ opening in a FCSA, an effect that is believed to be mediated by apical Ca⁺⁺ entering the open TJs. The specific condition of having Ca⁺⁺ only in the apical solution and the TJs located midway between the Ca⁺⁺ source (apical solution) and the Ca⁺⁺-binding sites presumably located at the zonula adhaerens, might configure a situation in which a control feedback loop is set up. A rise of [Ca⁺⁺] _ap during the phase of G increase in an FCSA causes a transient recovery of G followed by a subsequent escape phase where G increases again. Oscillations of G also appear in response to a rise of apical Ca⁺⁺. Both escape and oscillations result from the properties of the TJ regulatory feedback loop. In conclusion, the present results indicate that PKC plays a key role in TJ opening in response to extracellular Ca⁺⁺ withdrawal without major effect on the reverse process. In addition, PKC inhibition by H7 not only prevents TJ opening in response to basolateral Ca⁺⁺ removal but induces a prompt blockade of TJ oscillations induced by apical Ca⁺⁺, oscillations which reappear again when H7 is removed. Received: 9 May 2000/Revised: 30 August 2000     

Identification, Characterization and Partial Purification of a Thiol-protease Which Cleaves Specifically the Skeletal Muscle Ryanodine Receptor/Ca2+ Release Channel

A 94 kDa large subunit thiol-protease, as identified by anti-calpain antibodies, has been isolated from skeletal muscle junctional sarcoplasmic reticulum (SR). This protease cleaves specifically the skeletal muscle ryanodine receptor (RyR)/Ca²⁺ release channel at one site resulting in the 375 kDa and 150 kDa fragments. The 94 kDa thiol-protease degrades neither other SR proteins nor the ryanodine receptor of cardiac nor brain membranes. The partially purified 94 kDa protease, like the SR associated protease, had an optimal pH of about 7.0, was absolutely dependent on the presence of thiol reducing reagents, and was completely inhibited by HgCl₂, leupeptin and the specific calpain I inhibitor. However, while the SR membrane-associated protease requires Ca²⁺ at a submicromolar concentration, the isolated thiol-protease has lost the Ca²⁺ requirement. The 94 kDa thiol-protease had no effect on ryanodine binding but modified the channel activity of RyR reconstituted into planar lipid bilayer: in a time-dependent manner, the channel activity decreases and within several minutes the channel is converted into a subconducting state. The protease-modified channel activity is still Ca²⁺-dependent and ryanodine sensitive. This 94 kDa thiol-protease cross react with anti-calpain antibodies thus, may represent the novel large subunit of the skeletal muscle specific calpain p94. Received: 10 December 1996/Revised: 11 August 1997     

Protein Kinase Inhibitors and the Dynamics of Tight Junction Opening and Closing in A6 Cell Monolayers

This study focuses, in A6 cell monolayers, on the role of protein kinases in the dynamics of tight junction (TJ) opening and closing. The early events of TJ dynamics were evaluated by the fast Ca⁺⁺-switch assay (FCSA), which consisted of opening the TJs by removing basolateral Ca⁺⁺ (Ca⁺⁺ _bl), and closing them by returning Ca⁺⁺ _bl to normal values. Changes in TJ permeability can be reliably gauged through changes of transepithelial electrical conductance (G) determined in the absence of apical Na⁺. The FCSA allows the evaluation of the effects of drugs and procedures acting upon the mechanism controlling the TJs. The time courses of TJ opening and closing in response to the FCSA followed single-exponential time courses. A rise of apical Ca⁺⁺ (Ca⁺⁺ _ap) causes a reduction of TJ opening rate in an FCSA or even a partial recuperation of G, an effect that is interpreted as mediated by Ca⁺⁺ _ap entering the open TJs. Protein kinase C (PKC) inhibition by H7 at low concentrations caused a reduction of the rate of junction opening in response to Ca⁺⁺ _bl removal, without affecting junction closing, indicating that PKC in this preparation is a key element in the control of TJ opening dynamics. H7 at 100 μm completely inhibits TJ opening in response to Ca⁺⁺ _bl withdrawal. Subsequent H7 removal caused a prompt inhibition release characterized by a sharp G increase, a process that can be halted again by H7 reintroduction into the bathing solution. Differently from the condition in which Ca⁺⁺ is absent from the apical solution, in which H7 halts the process of G increase in response to a FCSA, when Ca⁺⁺ is present in the apical solution, addition of H7 during G increase in an FCSA not only induces a halt of the G increase but causes a marked recuperation of the TJ seal, indicated by a drop of G, suggesting a cooperative effect of Ca⁺⁺ and H7 on the TJ sealing process. Staurosporine, another PKC inhibitor, differently from H7, slowed both G increase and G decrease in an FCSA. Even at high concentrations (400 nm) staurosporine did not completely block the effect of Ca⁺⁺ withdrawal. These discrepancies between H7 and staurosporine might result from distinct PKC isoforms participating in different steps of TJ dynamics, which might be differently affected by these inhibitors. Immunolocalizations of TJ proteins, carried out in conditions similar to the electrophysiological experiments, show a very nice correlation between ZO-1 and claudin-1 localizations and G alterations induced by Ca⁺⁺ removal from the basolateral solution, both in the absence and presence of H7. Received: 18 April 2001/Revised: 16 July 2001     

Properties and the Cytoskeletal Control of Ca++-independent Large Conductance K+ Channels in Neonatal Rat Hippocampal Neurons

A member of the family of Ca⁺⁺-independent large conductance K⁺ channels (termed BK channels) was identified in patch clamp experiments with cultured neonatal rat hippocampal neurons. Permeation was characterized (at 5 mmol/l external, 140 mmol/l internal K⁺; 135 mmol/l external Na⁺) by a conductance of 107 pS, a ratio P_Na/P_K∼ 0.01, and outward rectification near the reversal potential. Channel activity was not voltage-dependent, could not be reduced by internal TEA or by a shift of internal pH from 7.4 to 6.8, i.e., discriminating features within the Ca⁺⁺-independent BK channel family. Cytosolic proteolysis abolished the functional state of hippocampal Ca⁺⁺-independent BK channels, in contrast to the pronase resistance of hippocampal Ca⁺⁺-activated BK channels which suggests structural dissimilarities between these related channels. Cytoskeletal alterations had an activating influence on Ca⁺⁺-independent BK channels and caused a 3–4-fold rise in P _o , but patch excision and channel isolation from the natural environment provoked the strongest increase in P _o , from 0.07 ± 0.03 to 0.73 ± 0.04. This activation process operated slowly, on a minute time scale and can be most easily explained with the loss of a membrane-associated inhibitory particle. Once activated, Ca⁺⁺-independent BK channels reacted sensitively to a Mg-ATP supplemented brain tissue extract with a P _o decline, from 0.60 ± 0.06 to 0.10 ± 0.05. Heated extracts failed to induce significant channel inhibition, providing evidence for a heat-unstable molecule with reassociates with the internal channel surface to reestablish channel inhibition. A dualistic channel control, by this membrane-associated molecule and by the cytoskeleton seems possible. Received: 16 July 1997/Revised: 3 November 1997     

Electrophoretic mobility of sarcoplasmic reticulum vesicles — Analytical model includes amino acid residues of A + P + N domain of Ca-ATPase and charged lipids

This work is an experimental and theoretical study of electrostatic and hydrodynamic properties of the surface of sarcoplasmic reticulum (SR) membrane using particle electrophoresis. The essential structural components of SR membrane include a lipid matrix and a dense layer of Ca^2 +-ATPases embedded in the matrix. The Ca^2 +-ATPase layer both drives and impedes vesicle mobility. To analyze the experimental mobility data, obtained at pH 4.0, 4.7, 5.0, 6.0, 7.5, and 9.0 in 0.1 M monovalent (1:1) electrolyte, an analytical solution for the vesicle mobility and electroosmotic flow velocity distribution was obtained by solving the Poisson–Boltzmann and the Navier–Stokes–Brinkman equations. The electrophoretic mobility model includes two sets of charges that represent: (a) charged lipids of the lipid matrix of the vesicle core, and (b) charged amino acid residues of APN domains of Ca^2 +-ATPases. APN domains are assumed to form a charged plane displaced from the surface of lipid matrix. The charged plane is embedded in a frictional layer that represents the surface layer of calcium pumps. Electrophoretic mobility is driven by the charged APN domain and by lipid matrix while the surface layer provides hydrodynamic friction. The charge of APN domain is determined by ionized amino acid residues obtained from the amino acid composition of SERCA1a Ca^2 +-ATPase. Agreement between the measured and the predicted mobility is evaluated by the weighted sum of mobility deviation squared. This model reproduces the experimental dependence of mobility on pH and predicts that APN domains are located in the upper half of the SR vesicle surface layer.     

pH-Modulation of Chloride Channels from the Sarcoplasmic Reticulum of Skeletal Muscle

The understanding of the role of cytoplasmic pH in modulating sarcoplasmic reticulum (SR) ion channels involved in Ca²⁺ regulation is important for the understanding of the function of normal and adversely affected muscles. The dependency of the SR small chloride (SCl) channel from rabbit skeletal muscle on cytoplasmic pH (pH _cis ) and luminal pH (pH _trans ) was investigated using the lipid bilayer-vesicle fusion technique. Low pH _cis 6.75–4.28 modifies the operational mode of this multiconductance channel (conductance levels between 5 and 75 pS). At pH _cis 7.26–7.37 the channel mode is dominated by the conductance and kinetics of the main conductance state (65–75 pS) whereas at low pH _cis 6.75–4.28 the channel mode is dominated by the conductance and kinetics of subconductance states (5–40 pS). Similarly, low pH _trans 4.07, but not pH _trans 6.28, modified the activity of SCl channels. The effects of low pH _cis are pronounced at 10⁻³ and 10⁻⁴ m [Ca²⁺] _cis but are not apparent at 10⁻⁵ m [Ca²⁺] _cis , where the subconductances of the channel are already prominent. Low pH _cis -induced mode shift in the SCl channel activity is due to modification of the channel proteins that cause the uncoupling of the subconductance states. The results in this study suggest that low pH _cis can modify the functional properties of the skeletal SR ion channels and hence contribute, at least partly, to the malfunction in the contraction-relaxation mechanism in skeletal muscle under low cytoplasmic pH levels. Received: 20 May 1998/Revised: 24 September 1998     

Regulatory Processes on the Cytoplasmic Surface of the Na+/Ca2+ Exchanger from Lobster Exoskeletal Muscle

A partially purified preparation of the lobster muscle Na⁺/Ca²⁺ exchanger was reconstituted with, presumably, random orientation in liposomes. Ca²⁺ efflux from ⁴⁵Ca-loaded vesicles was studied in exchanger molecules in which the transporter cytoplasmic surface was exposed to the extravesicular (ev) medium. Extravesicular Na⁺ (Na _ev )-dependent Ca²⁺ efflux depended directly upon the extravesicular Ca²⁺ concentration ([Ca²⁺] _ev ) with a half-maximal activation at [Ca²⁺] _ev = 0.6 μm. This suggests that the lobster muscle exchanger is catalytically upregulated by cytoplasmic Ca²⁺, as in most other species. In contrast, at low [Na⁺] _ev , the Ca _ev -binding site (i.e., on the cytoplasmic surface) for Ca²⁺ transported via Ca²⁺/Ca²⁺ exchange was half-maximally activated by about 7.5 μm Ca²⁺. Mild proteolysis of the Na⁺/Ca²⁺ exchanger by α-chymotrypsin also upregulated the Na _ev -dependent Ca²⁺ efflux. Following proteolytic digestion in Ca-free medium, the exchanger was no longer regulated by nontransported ev Ca²⁺. Proteolytic digestion in the presence of 1.9 μm free ev Ca²⁺, however, induced only a 1.6-fold augmentation of Ca²⁺ efflux, whereas, after digestion in nominally Ca-free medium, a 2.3-fold augmentation was observed; Ca²⁺ also inhibited proteolytic degradation of the Na⁺/Ca²⁺ exchanger measured by immunoblotting. These data suggest that Ca²⁺, bound to a high affinity binding site, protects against the activation of the Na⁺/Ca²⁺ exchanger by α-chymotrypsin. Additionally, we observed a 6-fold increase in the Na⁺/Ca²⁺ exchange rate, on average, when the intra- and extravesicular salt concentrations were increased from 160 to 450 mm, suggesting that the lobster muscle exchanger is optimized for transport at the high salt concentration present in lobster body fluids. Received: 20 October 1999/Revised: 13 January 2000     

An L-type Calcium Channel in Renal Epithelial Cells

A voltage-activated Ca⁺⁺ channel has been identified in the apical membranes of cultured rabbit proximal tubule cells using the patch-clamp technique. With 105 mm CaCl₂ solution in the pipette and 180 NaAsp in the bath, the channel had a conductance of 10.4 ± 1.0 pS (n= 8) in on-cell patches, and 9.8 ± 1.1 pS (n= 8) in inside-out patches. In both on-cell and inside-out patches, the channel is active by membrane depolarization. For this channel, the permeation to Ba⁺⁺ and Ca⁺⁺ is highly selective over Na⁺ and K⁺ (P_Ca(Ba):P_Na(K) >200:1). The sensitivity to dihydropyridines is similar to that for L-type channels where the channel was blocked by nifedipine (10 μm), and activated by Bay K 8644 (5 μm). When activated by Bay K 8644, the channel showed subconductance levels. Treatment with forskolin (12.5 μm), phorbol ester (1 μm), or stretching (40 cm water) did not activate this channel. These results indicate that this Ca⁺⁺ channel is mostly regulated by membrane voltage, and appears to be an epithelial class of L-type Ca⁺⁺ channel. As such, it may participate in calcium reabsorption during periods of enhanced sodium reabsorption, or calcium signaling in volume regulation, where membrane depolarization occurs for prolonged periods. Received: 1 April 1996/Revised: 5 August 1996     

Regulation of the skeletal sarcoplasmic reticulum Ca2+-ATPase by phospholamban and negatively charged phospholipids in reconstituted phospholipid vesicles

The Ca²⁺-ATPase of skeletal sarcoplasmic reticulum was purified and reconstituted in proteoliposomes containing phosphatidylcholine (PC). When reconstitution occurred in the presence of PC and the acidic phospholipids, phosphatidylserine (PS) or phosphatidylinositol phosphate (PIP), the Ca²⁺-uptake and Ca²⁺-ATPase activities were significantly increased (2–3 fold). The highest activation was obtained at a 50:50 molar ratio of PSYC and at a 10:90 molar ratio of PIP:PC. The skeletal SR Ca²⁺-ATPase, reconstituted into either PC or PC:PS proteoliposomes, was also found to be regulated by exogenous phospholamban (PLB), which is a regulatory protein specific for cardiac, slow-twitch skeletal, and smooth muscles. Inclusion of PLB into the proteoliposomes was associated with significant inhibition of the initial rates of Ca²⁺-uptake, while phosphorylation of PLB by the catalytic subunit of cAMP-dependent protein kinase reversed the inhibitory effects. The effects of PLB on the reconstituted Ca²⁺-ATPase were similar in either PC or PC: PS proteoliposomes, indicating that inclusion of negatively charged phospholipid may not affect the interaction of PLB with the skeletal SR Ca²⁺-ATPase. Regulation of the Ca²⁺-ATPase appeared to involve binding with the hydrophilic portion of phospholamban, as evidenced by crosslinking experiments, using a synthetic peptide which corresponded to amino acids 1–25 of phospholamban. These findings suggest that the fast-twitch isoform of the SR Ca²⁺-ATPase may be also regulated by phospholamban although this regulator is not expressed in fast-twitch skeletal muscles.     

Molecular Characterization of the Glycated Plasma Membrane Calcium Pump

We have previously demonstrated (Diabetes 39:707–711, 1990) that in vitro glycation of the red cell Ca²⁺ pump diminishes the Ca²⁺-ATPase activity of the enzyme up to 50%. Such effect is due to the reaction of glucose with lysine residues of the Ca²⁺ pump (Biochem. J. 293:369–375, 1993). The aim of this work was to determine whether the effect of glucose is due to a full inactivation of a fraction of the total population of Ca²⁺ pump, or to a partial inactivation of all the molecules. Glycation decreased the V _max for the ATPase activity leaving unaffected the apparent affinities for Ca²⁺, calmodulin or ATP. The apparent turnover was identical in both, the glycated and the native enzyme. Glycation decreased the V _max for the ATP-dependent but not for the calmodulin-activated phosphatase activities. Concomitantly with the inhibition, up to 6.5% of the lysine residues were randomly glycated. The probabilistic analysis of the relation between the enzyme activity and the fraction of nonmodified residues indicates that only one Lys residue is responsible for the inhibition. We suggest that glucose decreases the Ca²⁺-ATPase activity by reacting with one essential Lys residue probably located in the vicinity of the catalytic site, which results in the full inactivation of the enzyme. Thus, Ca²⁺-ATPase activity measured in erythrocyte membranes or purified enzyme preparations preincubated with glucose depends on the remaining enzyme molecules in which the essential Lys residue stays unglycated. Received: 9 March 1999/Revised: 11 May 1999     

Technical considerations for assessing alterations in skeletal muscle sarcoplasmic reticulum Ca++-sequestration functionin vitro

A multiple measurement system for assessing sarcoplasmic reticulum (SR) Ca⁺⁺-ATPase activity and Ca⁺⁺-uptake was used to examine the effects of SR fractionation and quick freezing on rat white (WG) and red (RG) gastrocnemius muscle.In vitro measurements were performed on whole muscle homogenates (HOM) and crude microsomal fractions (CM) enriched in SR vesicles before and after quick freezing in liquid nitrogen. Isolation of the CM fraction resulted in protein yields of 0.96±0.1 and 0.99±0.1 mg/g in WG and RG, respectively. The percent Ca⁺⁺-ATPase recovery for CM compared to HOM was 14.5% (WG) and 10.1% (RG). SR Ca⁺⁺-activated Ca⁺⁺-ATPase activity was not affected by quick freezing of HOM or CM, but basal ATPase was reduced (P<0.05) in frozen HOM (5.12±0.18–3.98±0.20 mole/g tissue/min in WG and from 5.39±0.20–4.48±0.24 mole/g tissue/min in RG). Ca⁺⁺-uptake was measured at a range of physiological free [Ca⁺⁺] using the Ca⁺⁺ fluorescent dye Indo-1. Maximum Ca⁺⁺-uptake rates when corrected for initial [Ca⁺⁺]_f were not altered in HOM or CM by quick freezing but uptake between 300 and 400nM free Ca⁺⁺ was reduced (P<0.05) in quick frozen HOM (1.30±0.1–0.66±0.1 mole/g tissue/min in WG and 1.04±0.2–0.60±0.1 mole/g tissue/min in RG). Linear correlations between Ca⁺⁺-uptake and Ca⁺⁺-ATPase activity measured in the presence of the Ca⁺⁺ ionophore A23187 were r=+0.25, (P<0.05) and r=+0.74 (P<0.05) in HOM and CM preparations, respectively, and were not altered by freezing. The linear relationships between HOM and CM maximum Ca⁺⁺-uptake (r=+0.44, P<0.05) and between HOM and CM Ca⁺⁺-ATPase activity (r=+0.34, P<0.05) were also not altered by tissue freezing. These data suggest that alterations in maximal SR Ca⁺⁺-uptake function and maximal Ca⁺⁺-ATPase activity may be measured in both HOM and CM fractions following freezing and short term storage. (Mol Cell Biochem139, 41–52, 1994)     

Kinetic Differences in the Phospholamban-Regulated Calcium Pump When Studied in Crude and Purified Cardiac Sarcoplasmic Reticulum Vesicles

Phospholamban (PLN) phosphorylation contributes largely to the inotropic and lusitropic effects of beta-adrenergic agonists on the heart. The mechanical effects of PLN phosphorylation on the heart are generally attributed solely to an increase in the apparent affinity of the Ca pump in the sarcoplasmic reticulum (SR) membranes for Ca²⁺ with little or no effect on V _max(Ca). In the present report, we compare the kinetic properties of the cardiac SR Ca pump in commonly studied crude microsomes with those of our recently developed preparation of light SR vesicles. We demonstrate that in crude microsomes, the increase in the apparent affinity of the pump for Ca²⁺ is larger, while the increase in V _max(Ca) is smaller, than in purified vesicles. The greater phosphorylation-induced increase in apparent Ca²⁺ affinity in crude microsomes may be further enhanced by an ATP-sensitive inhibitory effect of ruthenium red on the activity of the pump at subsaturating, but not saturating, Ca²⁺ concentrations as a result of a greater inhibition in unphosphorylated microsomes. Upon increasing the ATP concentration from 1 to 5 mm, an inhibition by 10 μm ruthenium red is eliminated in phosphorylated microsomes and reduced in control microsomes. Addition of the phosphoprotein phosphatase inhibitor okadaic acid produces a considerable increase in the phosphorylation-induced effects in both crude and purified microsomes. We conclude that the use of purified cardiac SR vesicles is critical for the demonstration of a major increase in V _max(Ca) in addition to an increase in the pump's apparent affinity for Ca²⁺ in response to phosphorylation of PLN by protein kinase A. Received: 20 May 1998/Revised: 13 November 1998     

Magnesium Inhibition of Ryanodine-Receptor Calcium Channels: Evidence for Two Independent Mechanisms

The gating of ryanodine receptor calcium release channels (RyRs) depends on myoplasmic Ca²⁺ and Mg²⁺ concentrations. RyRs from skeletal and cardiac muscle are activated by μm Ca²⁺ and inhibited by mm Ca²⁺ and Mg²⁺. ⁴⁵Ca²⁺ release from skeletal SR vesicles suggests two mechanisms for Mg²⁺-inhibition (Meissner, Darling & Eveleth, 1986, Biochemistry 25:236–244). The present study investigates the nature of these mechanisms using measurements of single-channel activity from cardiac- and skeletal RyRs incorporated into planar lipid bilayers. Our measurements of Mg²⁺- and Ca²⁺-dependent gating kinetics confirm that there are two mechanisms for Mg²⁺ inhibition (Type I and II inhibition) in skeletal and cardiac RyRs. The mechanisms operate concurrently, are independent and are associated with different parts of the channel protein. Mg²⁺ reduces P _o by competing with Ca²⁺ for the activation site (Type-I) or binding to more than one, and probably two low affinity inhibition sites which do not discriminate between Ca²⁺ and Mg²⁺ (Type-II). The relative contributions of the two inhibition mechanisms to the total Mg²⁺ effect depend on cytoplasmic [Ca²⁺] in such a way that Mg²⁺ inhibition has the properties of Types-I and II inhibition at low and high [Ca²⁺] respectively. Both mechanisms are equally important when [Ca²⁺] = 10 μm in cardiac RyRs or 1 μm in skeletal RyRs. We show that Type-I inhibition is not the sole mechanism responsible for Mg²⁺ inhibition, as is often assumed, and we discuss the physiological implications of this finding. Received: 1 January 1996/Revised: 14 November 1996     

An Endogenous Inhibitor of Ca++-ATPase from Human Placenta

Intracellular free calcium is regulated by Ca⁺⁺-ATPase, one form present on the plasma membrane (PM Ca⁺⁺-ATPase) and the other on sarcoplasmic (endoplasmic) reticulum (SR/ER Ca⁺⁺-ATPase). An endogenous inhibitor of SR Ca⁺⁺-ATPase from human placenta was shown to be present in normal placenta and the activity was not detectable in placenta from preeclamptic patients. The inhibitor was distributed in cytosol and microsomes. The inhibition of Ca⁺⁺-ATPase by this inhibitor was concentration-and time-dependent. The inhibitor neither bound to DEAE-nor CM-sepharose resins at pH 7.5 and 8.5. Furthermore, it was heat stable for 15min up to 55°C and completely destroyed at 80°C in a few minutes. It was also observed to be stable at room temperature for at least 3 months. The purification and characterization of this inhibitor would be valuable in achieving an understanding of the normal regulation of Ca⁺⁺-ATPase in the placenta during pregnancy.     

pH-Sensitive Gating Kinetics of the Maxi-K Channel in the Tonoplast of Chara australis

The most frequently observed K⁺ channel in the tonoplast of Characean giant internodal cells with a large conductance (ca. 170 pS; Lühring, 1986; Laver & Walker, 1987) behaves, although inwardly rectifying, like animal maxi-K channels. This channel is accessible for patch–clamp techniques by preparation of cytoplasmic droplets, where the tonoplast forms the membrane delineating the droplet. Lowering the pH of the bathing solution, that virtually mimicks the vacuolar environment, from an almost neutral level to values below pH 7, induced a significant but reversible decrease in channel activity, whereas channel conductance remained largely unaffected. Acidification (pH 5) on both sides of the membrane decreased open probability from a maximum of 80% to less than 20%. Decreasing pH at the cytosolic side inhibited channel activity cooperatively with a slope of 2.05 and a pK _a 6.56. In addition, low pH at the vacuolar face shifted the activating voltage into a positive direction by almost 100 mV. This is the first report about an effect of extraplasmatic pH on gating of a maxi-K channel. It is suggested that the Chara maxi-K channel possesses an S4-like voltage sensor and negatively charged residues in neighboring transmembrane domains whose S4-stabilizing function may be altered by protonation. It was previously shown that gating kinetics of this channel respond to cytosolic Ca²⁺ (Laver & Walker, 1991). With regard to natural conditions, pH effects are discussed as contributing mainly to channel regulation at the vacuolar membrane face, whereas at the cytosolic side Ca²⁺ affects the channel. An attempt was made to ascribe structural mechanisms to different states of a presumptive gating reaction scheme. Received: 8 May 1998/Revised: 18 September 1998     

Chloride-induced Ca2+ Release from the Sarcoplasmic Reticulum of Chemically Skinned Rabbit Psoas Fibers and Isolated Vesicles of Terminal Cisternae

There is increasing evidence that Ca²⁺ release from sarcoplasmic reticulum (SR) of mammalian skeletal muscle is regulated or modified by several factors including ionic composition of the myoplasm. We have studied the effect of Cl⁻ on the release of Ca²⁺ from the SR of rabbit skeletal muscle in both skinned psoas fibers and in isolated terminal cisternae vesicles. Ca²⁺ release from the SR in skinned fibers was inferred from increases in isometric tension and the amount of release was assessed by integrating the area under each tension transient. Ca²⁺ release from isolated SR was measured by rapid filtration of vesicles passively loaded with ⁴⁵Ca²⁺. Ca²⁺ release from SR was stimulated in both preparations by exposure to a solution containing 191 mm choline-Cl, following pre-equilibration in Ca²⁺-loading solution that had propionate as the major anion. Controls using saponin (50 μg/ml), indicated that the release of Ca²⁺ was due to direct action of Cl⁻ on the SR rather than via depolarization of T-tubules. Procaine (10 mm) totally blocked Cl⁻- and caffeine-elicited tension transients recorded using loading and release solutions having ([Na⁺] + [K⁺]) × [Cl⁻] product of 6487.69 mm ² and 12361.52 mm ², respectively, and blocked 60% of Ca²⁺ release in isolated SR vesicles. Surprisingly, procaine had only a minor effect on tension transients elicited by Cl⁻ and caffeine together. The data from both preparations suggests that Cl⁻ induces a relatively small amount of Ca²⁺ release from the SR by activating receptors other than RYR-1. In addition, Cl⁻ may increase the Ca²⁺ sensitivity of RYR-1, which would then allow the small initial release of Ca²⁺ to facilitate further release of Ca²⁺ from the SR by Ca²⁺-induced Ca²⁺ release. Received: 6 February 1996/Revised: 17 July 1996     

Polyamine Triggering of Exocytosis in Paramecium Involves an Extracellular Ca2+/(Polyvalent Cation)-Sensing Receptor, Subplasmalemmal Ca-Store Mobilization and Store-Operated Ca2+-Influx via Unspecific Cation Channels

The polyamine secretagogue, aminoethyldextran (AED), causes a cortical [Ca²⁺] transient in Paramecium cells, as analyzed by fluorochrome imaging. Our most essential findings are: (i) Cortical Ca²⁺ signals also occur when AED is applied in presence of the fast Ca²⁺ chelator, BAPTA. (ii) Extracellular La³⁺ application causes within seconds a rapid, reversible fluorescence signal whose reversibility can be attributed to a physiological [Ca²⁺] _i transient (while injected La³⁺ causes a sustained fluorescence signal). (iii) Simply increasing [Ca²⁺] _o causes a similar rapid, short-lived [Ca²⁺] _i transient. All these phenomena, (i–iii), are compatible with activation of an extracellular ``Ca<sup>2+</sup>/(polyvalent cation)-sensing receptor' known from some higher eukaryotic systems, where this sensor (responding to Ca<sup>2+</sup>, La<sup>3+</sup> and some multiply charged cations) is linked to cortical calcium stores which, thus, are activated. In Paramecium, such subplasmalemmal stores (``alveolar sacs') are physically linked to the cell membrane and they can also be activated by the Ca²⁺ releasing agent, 4-chloro-m-cresol, just like in Sarcoplasmic Reticulum. Since this drug causes a cortical Ca²⁺ signal also in absence of Ca²⁺ _o we largely exclude a ``Ca<sup>2+</sup>-induced Ca<sup>2+</sup> release' (CICR) mechanism. Our finding of increased cortical Ca<sup>2+</sup> signals after store depletion and re-addition of extracellular Ca<sup>2+</sup> can be explained by a ``store-operated Ca²⁺ influx' (SOC), i.e., a Ca²⁺ influx superimposing store activation. AED stimulation in presence of Mn²⁺ _o causes fluorescence quenching in Fura-2 loaded cells, indicating involvement of unspecific cation channels. Such channels, known to occur in Paramecium, share some general characteristics of SOC-type Ca²⁺ influx channels. In conclusion, we assume the following sequence of events during AED stimulated exocytosis: (i) activation of an extracellular Ca²⁺/polyamine-sensing receptor, (ii) release of Ca²⁺ from subplasmalemmal stores, (iii) and Ca²⁺ influx via unspecific cation channels. All three steps are required to produce a steep cortical [Ca²⁺] signal increase to a level required for full exocytosis activation. In addition, we show formation of [Ca²⁺] microdomains (≤0.5 μm, ≤33 msec) upon stimulation. Received: 30 August 1999/Revised: 1 December 1999     

A Novel Large Conductance, Nonselective Cation Channel in Pheochromocytoma (PC12) Cells

A new type of nonselective cation channel was identified and characterized in pheochromocytoma (PC12) cells using inside-out and cell-attached patch-clamp recordings. The channel shows a large unitary conductance (274 pS in symmetric 145 mm K⁺) and selectivity for Na⁺≈ K⁺ > Li⁺, and is practically impermeable to Cl⁻. The channel activity-voltage relationship is bell-shaped, showing maximal activation at ≈−10 mV. The overall activity of this channel is unmodified by [Na⁺] _ic , or [Ca⁺⁺] _ic . However, increases in [Ca⁺⁺] _ic lead to a decrease in the unitary current amplitude. In addition, overall activity is mildly increased when suction is applied to the back of the patch pipette. Together, these characteristics distinguish the present channel from all other large conductance nonselective cation channels reported so far in a variety of preparations. The frequency of appearance of this channel type is similar in undifferentiated and NGF-treated PC12 cells (≈8–27% of patches). The combination of large conductance, permeability to Na⁺, and existence of conducting states at negative potentials, may provide a significant pathway for inward current and depolarization in PC12 cells. Received: 14 February 1997/Revised: 28 July 1997     

Clustered Distribution of Calcium Sensitivities: An Indication of Hetero-tetrameric Gating Components in Ca2+-activated K+ Channels Reconstituted from Avian Nasal Gland Cells

High-conductance, Ca²⁺-activated K⁺ channels from the basolateral membrane of rabbit distal colon epithelial cells were reconstituted into planar phospholipid bilayers to examine the effect of Mg²⁺ on the single-channel properties. Mg²⁺ decreases channel current and conductance in a concentration-dependent manner from both the cytoplasmic and the extracellular side of the channel. In contrast to other K⁺ channels, Mg²⁺ does not cause rectification of current through colonic Ca²⁺-activated K⁺ channels. In addition, cytoplasmic Mg²⁺ decreases the reversal potential of the channel. The Mg²⁺-induced decrease in channel conductance is relieved by high K⁺ concentrations, indicating competitive interaction between K⁺ and Mg²⁺. The monovalent organic cation choline also decreases channel conductance and reversal potential, suggesting that the effect is unspecific. The inhibition of channel current by Mg²⁺ and choline most likely is a result of electrostatic screening of negative charges located superficially in the channel entrance. But in addition to charge, other properties appear to be necessary for channel inhibition, as Na⁺ and Ba²⁺ are no (or only weak) inhibitors. Mg²⁺ and possibly other cations may play a role in the regulation of current through these channels. Received: 25 August 1995/Revised: 16 November 1995