Stability of equine lysozyme. I. Thermal unfolding behaviour.

The thermal denaturation of Ca(2+)- and apo-forms of equine lysozyme was followed by using far and near UV circular dichroism and intrinsic fluorescence methods. The difference found between the temperature dependence of the ellipticity at 222 nm and 287 nm, which show two stages in the thermal transition, and those at 228 nm and 294 nm, which indicate only one stage over a wide range of temperatures reflects that different subdivisions of the protein molecule are characterized by a different stability, cooperativity and pathway of denaturation. The first transition, reflected in the increase of the ellipticity at 222 nm and 287 nm, coincides with the transition detected by fluorescence and occurs at 30-50 degrees C for the apo-form and at 50-60 degrees C for the Ca(2+)-form of lysozyme. It seems to correlate with the transfer of some tryptophan residues to a more hydrophobic environment and with a local rearrangement of the tertiary and secondary structures. The unfolding transition detected by the decrease of the ellipticity at all wavelengths occurs nearly in the same temperature region for the apo- and Ca(2+)-forms, i.e. 50-80 degrees C and 55-80 degrees C, respectively. The presence of a Ca(2+)-binding loop in equine lysozyme may be partly responsible for the drastic destabilization of its structure as a whole both in the presence but especially in the absence of Ca2+ in comparison with hen and human lysozymes.     

One of the Ca2+ binding sites of recoverin exclusively controls interaction with rhodopsin kinase

Recoverin is a neuronal calcium sensor protein that controls the activity of rhodopsin kinase in a Ca(2+)-dependent manner. Mutations in the EF-hand Ca2+ binding sites are valuable tools for investigating the functional properties of recoverin. In the recoverin mutant E121Q (Rec E121Q ) the high-affinity Ca2+ binding site is disabled. The non-myristoylated form of Rec E121Q binds one Ca2+ via its second Ca(2+)-binding site (EF-hand 2), whereas the myristoylated variant does not bind Ca2+ at all. Binding of Ca2+ to non-myristoylated Rec E121Q apparently triggers exposure of apolar side chains, allowing for association with hydrophobic matrices. Likewise, an interaction surface for the recoverin target rhodopsin kinase is constituted upon Ca2+ binding to the non-acylated mutant. Structural changes resulting from Ca(2+)-occupation of EF-hand 2 in myristoylated and non-myristoylated recoverin variants are discussed in terms of critical conditions required for biological activity.     

S100P, a novel Ca(2+)-binding protein from human placenta. cDNA cloning, recombinant protein expression and Ca2+ binding properties.

A novel member of the S100 protein family, present in human placenta, has been characterized by protein sequencing, cDNA cloning, and analysis of Ca(2+)-binding properties. Since the placenta protein of 95 amino acid residues shares about 50% sequence identity with the brain S100 proteins alpha and beta, we proposed the name S100P. The cDNA was expressed in Escherichia coli and recombinant S100P was purified in high yield. S100P is a homodimer and has two functional EF hands/polypeptide chain. The low-affinity site (Kd = 800 microM), which, in analogy to S100 beta, seems to involve the N-terminal EF hand, can be followed by the Ca(2+)-dependent decrease in tyrosine fluorescence. The high-affinity site, provided by the C-terminal EF hand, influences the reactivity of the sole cysteine which is located in the C-terminal extension (Cys85). Binding to the high-affinity site (Kd = 1.6 microM) can be monitored by fluorescence spectroscopy of S100P labelled at Cys85 with 6-proprionyl-2-dimethylaminonaphthalene (Prodan). The Prodan fluorescence shows a Ca(2+)-dependent red shift of the maximum emission wavelength from 485 nm to 502 nm, which is accompanied by an approximately twofold loss in integrated fluorescence intensity. This indicates that Cys85 becomes more exposed to the solvent in Ca(2+)-bound S100P, making this region of the molecule, the so-called C-terminal extension, an ideal candidate for a putative Ca(2+)-dependent interaction with a cellular target. In p11, a different member of the S100 family, the C-terminal extension which contains a corresponding cysteine (Cys82 in p11), is involved in a Ca(2+)-independent complex formation with the protein ligand annexin II. The combined results support the hypothesis that S100 proteins interact in general with their targets after a Ca(2+)-dependent conformational change which involves hydrophobic residues of the C-terminal extension.     

Calelectrins are a ubiquitous family of Ca2+-binding proteins purified by Ca2+-dependent hydrophobic affinity chromatography by a mechanism distinct from that of calmodulin

The calelectrins, a heterogeneous group of three new Ca2+-binding proteins of M 67 000, 35 000 and 32 500, copurify with calmodulin during Ca2+-dependent hydrophobic affinity chromatography (Südhof et al., Biochemistry, in press, 1984). This property is exploited for the rapid purification of all three calelectrins including for the first time the Mr 35 000, from commercially available acetone powders from several bovine tissues (heart, liver, brain, pancreas and testis). The nature of the Ca2+-dependent interaction of the calelectrins with hydrophobic affinity matrices has been investigated. As with calmodulin, the Ca2+-binding sites of all three purified calelectrins can be probed with Tb3+ which binds to them in a stoichiometric, saturable and Ca2+-displaceable manner. However, using several hydrophobic fluorescence probes which bind to the proteins, contrary to calmodulin no Ca2+-dependent exposure of hydrophobic sites could be detected in any of the three purified proteins. Therefore the Ca2+-dependent purification of the calelectrins on hydrophobic affinity columns seems not to involve the surface exposure of hydrophobic sites and the calelectrins have in this respect little similarity to calmodulin.     

The effect of high pressure on the conformation, interactions and activity of the Ca(2+)-ATPase of sarcoplasmic reticulum.

High pressure (100-150 MPa) increases the intensity and polarization of fluorescence of FITC-labeled Ca(2+)-ATPase in a medium containing 0.1 mM Ca2+, suggesting a reversible pressure-induced transition from the E1 into an E2-like state with dissociation of ATPase oligomers. Under similar conditions but using unlabeled sarcoplasmic reticulum vesicles, high pressure caused the reversible release of Ca2+ from the high-affinity Ca2+ sites of Ca(2+)-ATPase, as indicated by changes in the fluorescence of the Ca2+ indicator, Fluo-3; this was accompanied by reversible inhibition of the Ca(2+)-stimulated ATPase activity measured in a coupled enzyme system of pyruvate kinase and lactate dehydrogenase, and by redistribution of Prodan in the lipid phase of the membrane, as shown by marked changes in its fluorescence emission characteristics. In a Ca(2+)-free medium where the equilibrium favors the E2 conformation of Ca(2+)-ATPase the fluorescence intensity of FITC-ATPase was not affected or only slightly reduced by high pressure. The enhancement of TNP-AMP fluorescence by 100 mM inorganic phosphate in the presence of EGTA and 20% dimethylsulfoxide was essentially unaffected by 150 MPa pressure at pH 6.0 and was only slightly reduced at pH 8.0. As the enhancement of TNP-AMP fluorescence by Pi is associated with the Mg(2+)-dependent phosphorylation of the enzyme and the formation of Mg.E2-P intermediate, it appears that the reactions of Ca(2+)-ATPase associated with the E2 state are relatively insensitive to high pressure. These observations suggest that high pressure stabilizes the enzyme in an E2-like state characterized by low reactivity with ATP and Ca2+ and high reactivity with Pi. The transition from the E1 to the E2-like state involves a decrease in the effective volume of Ca(2+)-ATPase.     

Target recognition of apocalmodulin by nitric oxide synthase I peptides

An increasing number of proteins are found that are regulated by the Ca(2+)-free state of calmodulin, apocalmodulin. Many of these targets harbor a so-called IQ motif within their primary sequence, but several target proteins of apocalmodulin lack this motif. We investigated whether the Ca(2+)-dependent calmodulin-binding site of nitric oxide synthase I could be transformed into a target site of apocalmodulin. Synthetic peptides representing the wild-type amino acid sequence and several peptides carrying mutations were studied by isothermal titration calorimetry and fluorescence spectroscopy. A single amino acid substitution of a negative charge to a positive charge can convert a classical Ca(2+)-dependent binding site of calmodulin into a target site for apocalmodulin. In addition, the introduction of hydrophobic amino acids increases the apparent binding affinity from the micromolar to the nanomolar range. Binding of wild-type and mutant peptides to Ca(2+)-calmodulin was enthalpically driven, and binding to apocalmodulin was entropically driven. Our data indicate that only a few selected amino acid positions in a calmodulin-binding site determine its Ca(2+) dependency.     

Identification of the Ca(2+)-dependent calmodulin-binding region of chromogranin A.

Chromogranin A (CGA), the most abundant protein in bovine adrenal chromaffin granules, is a high-capacity, low-affinity Ca(2+)-binding protein found in most neuroendocrine cells, and binds calmodulin (CaM) in a Ca(2+)-dependent manner. The binding of chromogranin A to calmodulin was determined by measuring the intrinsic tryptophan fluorescence of chromogranin A in the presence and absence of Ca2+. Binding was specifically Ca(2+)-dependent; neither Mg2+ nor Mn2+ could substitute for Ca2+. Chelation of Ca2+ by EGTA completely eliminated the chromogranin A-calmodulin interaction. CaM binding was demonstrated by a synthetic CGA peptide representing residues 40-65. When the CGA peptide and CaM were mixed in the presence of 15 mM CaCl2, the intrinsic tryptophan fluorescence emission underwent a substantial blue-shift, shifting from 350 to 330 nm. Like the intact CGA, the peptide-CaM binding was specifically Ca(2+)-dependent, and neither Mg2+ nor Mn2+ could induce the binding. Calmodulin bound both to CGA and to the synthetic CGA peptide with a stoichiometry of one to one. The dissociation constants (Kd) determined by fluorometric titration were 13 nM for the peptide-CaM binding and 17 nM for intact CGA-CaM binding. The Kd values are comparable to those (approximately 10(-9) M) of other CaM-binding proteins and peptides, demonstrating a tight binding of CaM by CGA. The CaM-binding CGA residues 40-65 are 100% conserved among all the sequenced CGAs in contrast to 50-60% conservation found in the entire sequence, implying essential roles of this region.     

Purification and characterization of S-modulin, a calcium-dependent regulator on cGMP phosphodiesterase in frog rod photoreceptors.

S-modulin is a 26 kDa protein that regulates light sensitivity of cGMP phosphodiesterase in a Ca(2+)-dependent manner in frog rod outer segments (ROSs). In the present study, we purified S-modulin by taking advantage of a hydrophobic interaction between Phenyl Sepharose and S-modulin at high Ca2+ concentrations. The yield was greater than 90%. 45Ca(2+)-binding experiment showed that S-modulin is a Ca(2+)-binding protein. At high Ca2+ concentrations, S-modulin binds to ROS membranes. The binding target of the Ca2+/S-modulin complex is possibly a ROS membrane lipid(s), but it was difficult to identify. The binding was observed mainly at greater than 1 microM Ca2+. The amino acid sequence deduced from proteolytic fragments of S-modulin was approximately 80% and 60% identical to those of recovering and visinin, respectively.     

Calcium-binding and temperature induced transitions in equine lysozyme: new insights from the pCa-temperature "phase diagrams"

The most universal approach to the studies of metal binding properties of single-site metal binding proteins, i.e., construction of a "phase diagram" in coordinates of free metal ion concentration-temperature, has been applied to equine lysozyme (EQL). EQL has one relatively strong calcium binding site and shows two thermal transitions, but only one of them is Ca(2+)-dependent. It has been found that the Ca(2+)-dependent behavior of the low temperature thermal transition (I) of EQL can be adequately described based upon the simplest four-states scheme of metal- and temperature-induced structural changes in a protein. All thermodynamic parameters of this scheme were determined experimentally and used for construction of the EQL phase diagram in the pCa-temperature space. Comparison of the phase diagram with that for alpha-lactalbumin (alpha-LA), a close homologue of lysozyme, allows visualization of the differences in thermodynamic behavior of the two proteins. The thermal stability of apo-EQL (transition I) closely resembles that for apo-alpha-LA (mid-temperature 25 degrees C), while the thermal stabilities of their Ca(2+)-bound forms are almost indistinguishable. The native state of EQL has three orders of magnitude lower affinity for Ca(2+) in comparison with alpha-LA while its thermally unfolded state (after the I transition) has about one order lower (K = 15M(-1)) affinity for calcium. Circular dichroism studies of the apo-lysozyme state after the first thermal transition show that it shares common features with the molten globule state of alpha-LA.     

A fluorescent calmodulin that reports the binding of hydrophobic inhibitory ligands.

Ca2+ binding to calmodulin in the pCa range 5.5-7.0 exposes hydrophobic sites that bind hydrophobic inhibitory ligands, including calmodulin antagonists, some Ca2+-antagonists and calmodulin-binding proteins. The binding of these hydrophobic ligands to calmodulin can be followed by the approx. 80% fluorescence increase they produce in dansylated (5-dimethylaminonaphthalene-1-sulphonylated) calmodulin (CDRDANS). In the presence of Ca2+, calmodulin binds the calmodulin inhibitor, R24571, with an affinity of approx. 2-3 nM and hydrophobic ligands, including trifluoperazine (TFP), W-7 [N-(6-aminohexyl)-5-chloronaphthalene-1-sulphonamide], fendiline, felodipine and prenylamine, with affinities in the micromolar range. This binding is strongly Ca2+-dependent and Mg2+-independent. Calmodulin shows a reasonably high degree of specificity in its binding of these ligands over other ligands tested. CDRDANS, therefore, provides a convenient and simple means of monitoring the interaction of a variety of hydrophobic ligands with the Ca2+-dependent regulatory protein, calmodulin. CDRDANS binds to phospholipid vesicles made of (dimyristoyl)phosphatidylcholine (DMPC) or (dipalmitoyl)phosphatidylcholine (DPPC) and produces fluorescence increases only in the presence of Ca2+ and at temperatures above their gel-to-liquid crystalline phase transition. Although the fluorescence changes in CDRDANS accurately report phase transitions in these liposomes, its binding to these vesicles is weak. Calmodulin probably requires a high-affinity lipid-bound receptor protein for its high-affinity binding to natural membranes.     

A novel 145 kd brain cytosolic protein reconstitutes Ca(2+)-regulated secretion in permeable neuroendocrine cells.

The regulated secretory pathway is activated by elevated cytoplasmic Ca2+; however, the components mediating Ca2+ regulation have not been identified. In semi-intact neuroendocrine cells, Ca(2+)-activated secretion is ATP- and cytosol protein-dependent. We have identified a novel brain protein, p145, as a cytosolic factor that reconstitutes Ca(2+)-activated secretion in two neuroendocrine cell types. The protein is a dimer of 145 kd subunits, exhibits Ca(2+)-dependent interaction with a hydrophobic matrix, and binds phospholipid vesicles, suggesting a membrane-associated function. A p145-specific antibody inhibits the reconstitution of Ca(2+)-activated secretion by cytosol, indicating an essential role for p145. The restricted expression of p145 in tissues exhibiting a regulated secretory pathway suggests a key role for this protein in the transduction of Ca2+ signals into vectorial membrane fusion events.     

Static and kinetic studies of calmodulin and melittin complex.

Ca2+ binding to calmodulin triggers conformational change of the protein which induces exposure of hydrophobic surfaces. Melittin has been believed to bind to Ca(2+)-bound calmodulin through the exposed hydrophobic surfaces. However, tryptophan fluorescence measurements and gel chromatography experiments with the melittin-calmodulin system revealed that melittin bound to calmodulin at zero salt concentration even in the absence of Ca2+; addition of salt removed melittin from Ca(2+)-free calmodulin. This means not only the hydrophobic interaction but also the electrostatic interaction contributes to the melittin-calmodulin binding. The fluorescence stopped-flow studies of the dissociation reaction of melittin-calmodulin complex revealed that Ca2+ removal from the complex induced a conformational change of calmodulin, resulting in reduction of the hydrophobic interaction between melittin and calmodulin, but the electrostatic interaction kept melittin still bound to calmodulin for a subsecond lag period, after which melittin dissociated from calmodulin. The fluorescence stopped-flow experiments on the dissociation reaction of complex of melittin and tryptic fragment(s) of calmodulin revealed that the lag period of the melittin dissociation reaction was attributable to the interaction between the C-terminal half of calmodulin and the C-terminal region of melittin.     

Ca2+ differently affects hydrophobic properties of guanylyl cyclase-activating proteins (GCAPs) and recoverin

Guanylyl cyclase-activating proteins (GCAPs) and recoverin are retina-specific Ca(2+)-binding proteins involved in phototransduction. We provide here evidence that in spite of structural similarities GCAPs and recoverin differently change their overall hydrophobic properties in response to Ca(2+). Using native bovine GCAP1, GCAP2 and recoverin we show that: i) the Ca(2+)-dependent binding of recoverin to Phenyl-Sepharose is distinct from such interactions of GCAPs; ii) fluorescence intensity of 1-anilinonaphthalene-8-sulfonate (ANS) is markedly higher at high [Ca(2+)](free) (10 microM) than at low [Ca(2+)](free) (10 nM) in the presence of recoverin, while an opposing effect is observed in the presence of GCAPs; iii) fluorescence resonance energy transfer from tryptophane residues to ANS is more efficient at high [Ca(2+)](free) in recoverin and at low [Ca(2+)](free) in GCAP2. Such different changes of hydrophobicity evoked by Ca(2+) appear to be the precondition for possible mechanisms by which GCAPs and recoverin control the activities of their target enzymes.     

Ultraviolet light activates blocking actions of dantrolene on intracellular Ca2+ release in bullfrog sympathetic neurones

Effects of dantrolene, a blocker of intracellular Ca2+ release, on the oscillation of the intracellular Ca2+ ([Ca2+]i) induced by caffeine were studied in bullfrog sympathetic ganglion cells, using a Fura-2 fluorescence technique. Dantrolene blocked the Ca2+ oscillation only in the cell illuminated by ultraviolet light (335-385 nm). Likewise, the blocking effects on rhythmic Ca(2+)-dependent hyperpolarizations, representing Ca2+ oscillations via activation of Ca(2+)-dependent K+ channel, occurred only under the illumination with ultraviolet light (335-385 nm), but not with visible light (404-417 nm). This wavelength dependence differs from the absorbance spectrum of dantrolene. On the other hand, dantrolene preirradiated with ultraviolet light under dark condition or ultraviolet light itself did not affect the [Ca2+]i oscillation. The blocking action was not prevented by the pretreatment of the cells with reducing agents. These results indicate that illumination of the Ca2+ release channel or dantrolene itself with ultraviolet light (possibly the former) is necessary for the drug to exert its blocking effect. Furthermore, dantrolene was found to decrease Fura-2 fluorescence and to increase cell autofluorescence, leading sometimes to a false decrease in the basal [Ca2+]i.     

Isolation and characterization of recoverin-like Ca(2+)-binding protein from rat brain.

Rat brain was found, by immunoblot analysis, to have a protein of Mr 23,000 (P23k) that was clearly different from recoverin and was labeled with an antiserum raised against the NH2-terminus of recoverin. P23k could not be detected by an antiserum raised against the COOH-terminus of recoverin. Blots with 45Ca demonstrated that P23k bound Ca2+. This calciprotein was further purified by Ca(2+)-dependent hydrophobic interaction and ion-exchange chromatography. In SDS polyacrylamide gel electrophoresis, P23k had an apparent Mr of 21,000 in the presence of 10 microM Ca2+ and 23,000 in the absence of Ca2+ (0.1 mM EGTA). The isoelectric point of P23k was 5.6. Ca(2+)-binding analysis indicated that P23k bound 2 moles of Ca2+ per mole of protein and had two binding sites with dissociation constants of 13 microM and 0.2 microM. Purified P23k bound to the crude membrane fractions from the cerebellum, cerebrum and retina in a Ca(2+)-dependent manner. Partial amino acid sequence analysis of proteolytic fragments of P23k revealed the sequence homology between P23k and recoverin. These results suggested that P23k may act as a Ca(2+)-sensitive regulator by forming a complex with its target on the membrane.     

Calcium release in HSY cells conforms to a steady-state mechanism involving regulation of the inositol 1,4,5-trisphosphate receptor Ca2+ channel by luminal [Ca2+]

In many cell types, low concentrations of inositol 1,4,5-trisphosphate (IP3) release only a portion of the intracellular IP3-sensitive Ca2+ store, a phenomenon known as "quantal" Ca2+ release. It has been suggested that this effect is a result of reduced activity of the IP3- dependent Ca2+ channel with decreasing calcium concentration within the IP3-sensitive store ([Ca2+]s). To test this hypothesis, the properties of IP3-dependent Ca2+ release in single saponin-permeabilized HSY cells were studied by monitoring [Ca2+]s using the Ca(2+)-sensitive fluorescent dye mag-fura-2. In permeabilized cells, blockade of the sarco/ER Ca(2+)-ATPase pump in stores partially depleted by IP3 induced further Ca2+ release via an IP3-dependent route, indicating that Ca2+ entry via the sarco/ER Ca(2+)-ATPase pump had been balanced by Ca2+ loss via the IP3-sensitive channel before pump inhibition. IP3- dependent Mn2+ entry, monitored via quenching of luminal mag-fura-2 fluorescence, was readily apparent in filled stores but undetectable in Ca(2+)-depleted stores, indicating markedly reduced IP3-sensitive channel activity in the latter. Also consistent with reduced responsiveness of Ca(2+)-depleted stores to IP3, the initial rate of refilling of these stores was unaffected by the presence of 0.3 microM IP3, a concentration that was clearly effective in eliciting Ca2+ release from filled stores. Analysis of the rate of Ca2+ release at various IP3 concentrations indicated a significant shift of the IP3 dose response toward higher [IP3] with decreasing [Ca2+]s. We conclude that IP3-dependent Ca2+ release in HSY cells is a steady-state process wherein Ca2+ efflux via the IP3 receptor Ca2+ channel is regulated by [Ca2+]s, apparently via changes in the sensitivity of the channel to IP3.     

The calcium-binding property of equine lysozyme

It was found that equine lysozyme binds one Ca2+. It was eluted with equimolar Ca2+ from a Bio-Gel P-4 column. Human lysozyme did not behave similarly. Equine lysozyme is concluded to be a calcium metallo-protein like alpha-lactalbumin, which is a homologue of hen egg white lysozyme.     

Neutrophil recognition requires a Ca(2+)-induced conformational change in the lectin domain of GMP-140.

GMP-140, a receptor for myeloid cells that is expressed on surfaces of thrombin-activated platelets and endothelial cells, is a member of the selectin family of adhesion molecules that regulate leukocyte interactions with the blood vessel wall. Each selectin contains an N-terminal domain homologous to Ca(2+)-dependent lectins and mediates cell-cell contact by binding to oligosaccharide ligands in a Ca(2+)-dependent manner. The mechanisms by which Ca2+ promotes selectin-dependent cellular interactions have not been defined. We demonstrate that purified GMP-140 contains two high affinity binding sites for Ca2+ as measured by equilibrium dialysis (Kd = 22 +/- 2 microM). Occupancy of these sites by Ca2+ alters the conformation of the protein as detected by a reduction in intrinsic fluorescence emission intensity (Kd = 4.8 +/- 0.2 microM). This Ca(2+)-dependent conformational change exposes an epitope spanning residues 19-34 of the lectin domain that is recognized by a monoclonal antibody capable of blocking neutrophil adhesion to GMP-140 (half-maximal antibody binding at approximately 20 microM Ca2+). Furthermore, a synthetic peptide encoding this epitope, CQNRYTDLVAIQNKNE, inhibits neutrophil binding to GMP-140. Mg2+ also alters the conformation of the protein, but not in a manner that will support leukocyte recognition in the absence of Ca2+. There is a strong correlation between the Ca2+ levels required for neutrophil adhesion to GMP-140, for occupancy of the two Ca(2+)-binding sites, for the fluorescence-detected conformational change, and for exposure of the antibody epitope in the lectin domain. We conclude that binding of Ca2+ to high affinity sites on GMP-140 modulates the conformation of the lectin domain in a manner that is essential for leukocyte recognition.     

Effect of shear stress on cytosolic Ca2+ of calf pulmonary artery endothelial cells.

The purpose of the present study was to determine if hemodynamic shear stress increases free cytosolic Ca2+ concentration ([Ca2+]i) of cultured pulmonary artery endothelial cells exposed to steady laminar fluid flow in a parallel plate chamber. Average [Ca2+]i was estimated by measuring cell-associated fura-2 fluorescence using microfluorimetric analysis. To determine [Ca2+]i close to the membrane surface, 86Rb+ efflux via Ca(2+)-dependent K+ channels was measured. Upon initiation of flow or upon step increases in flow, no change in [Ca2+]i was observed using fura-2. However, increases in shear stress produced a large, transient increase in 86Rb+ efflux. The shear stress-dependent increase in 86Rb+ efflux was not blocked by either tetrabutylammonium ions (20 mM) or by charybdotoxin (10 nM), two specific inhibitors of the Ca(2+)-dependent K+ channel of vascular endothelial cells. These results demonstrate that shear stress per se has little effect on either the average cytosolic [Ca2+]i as measured by fura-2 or on [Ca2+]i close to the cytoplasmic surface of the plasmalemma as measured by the activity of Ca(2+)-dependent K+ channels.     

μ-Calpain-mediated deregulation of cardiac, brain, and kidney NCX1 splice variants

μ-Calpain is a Ca(2+)-activated protease abundant in mammalian tissues. Here, we examined the effects of μ-calpain on three alternatively spliced variants of NCX1 using the giant, excised patch technique. Membrane patches from Xenopus oocytes expressing either heart (NCX1.1), kidney (NCX1.3), or brain (NCX1.4) variants of NCX1 were exposed to μ-calpain and their Na(+)-dependent (I(1)) and Ca(2+)-dependent (I(2)) regulatory phenotypes were assessed. For these exchangers, I(1) inactivation is evident as a Na(+)(i)-dependent decay of peak outward currents whereas I(2) regulation manifests as outward current activation by micromolar Ca(2+)(i) concentrations. Notably, with NCX1.1 and NCX1.4 but not in NCX1.3, higher Ca(2+)(i) levels alleviate I(1) inactivation. Our results show that (i) μ-calpain selectively ablates Ca(2+)-dependent (I(2)) regulation leading to a constitutive activation of exchange current, (ii) μ-calpain has much smaller effects on Na(+)-dependent (I(1)) regulation, produced by a slight destabilization of the I(1) state, and (iii) Ca(2+)-dependent regulation (I(2)) and Ca(2+)-mediated alleviation of I(1) appear to be functionally distinct mechanisms, the latter of which is left largely intact after μ-calpain treatment. The ability of μ-calpain to selectively and constitutively activate Na(+)-Ca(2+) exchange currents may have important pathophysiological implications in tissue where these splice variants are expressed.