Selective modification of tyrosine-68 in β1-bungarotoxin from the venom ofBungarus multicinctus (Taiwan banded krait)

β₁-Bungarotoxin (β₁-Bgt) fromBungarus multicinctus (Taiwan banded krait) snake venom was subjected to tyrosine modification withp-nitrobenzenesulfonyl fluoride (NBSF) atpH 8.0 and the NBS derivatives were separated by high-performance liquid chromatography. The results of amino acid analysis revealed that only one Tyr residue out of 14 was modified, and the modified residue was identified to be Tyr-68 in the A chain of β₁-Bgt. Spectrophotometric titration indicated that the phenolic group of Tyr-68 has apK of 10.1. Modification of Tyr-68 in the A chain caused a selective loss in lethal toxicity, but had no effect on either enzymatic or antigenic activities. The Ca²⁺-induced difference spectra and fluorescence study indicated that β₁-Bgt possesses at least two different types of Ca²⁺-binding sites. However, modification of Tyr-68 in β₁-Bgt did not cause any change of the Ca²⁺-induced difference spectra and fluorescence spectra in native toxin and the two types of Ca²⁺-binding sites were retained. Moreover, the affinity of Tyr-68-modified β₁-Bgt for 8-anilinonaphthalene sulfonate was also unaffected in both the presence and absence of Ca²⁺. All of the results indicated that Tyr-68 is not involved in the Ca²⁺ and substrate bindings in the A chain of β₁-Bgt. It is concluded that lethal toxicity is not necessarily associated with enzymatic, antigenic, and Ca²⁺-binding activities in β₁-Bgt.     

Calmodulin selectively modulates the guanylate cyclase activity by repressing the lipid phase separation temperature in the inner half of the bilayer of rat brain synaptosomal plasma membranes

The association of [¹²⁵I-]calmodulin with rat brain synaptosomal plasma membranes, when incubated for 1 h at 25° in the presence or in absence of 20 M Ca²⁺, follows a sigmoid path with a Hill coefficient h=1.79±0.12 and h=1.72±0.11, respectively. The total association of calmodulin with the membrane increased approx. 60%–80% at all the range of calmodulin concentrations used in the presence of 20 M Ca²⁺. A three fold increase of guanylate cyclase activity was shown in the presence of low concentrations of calmodulin (up to 10 mM); higher concentrations (up to 40 mM) however, led to a progressive inhibition of the enzyme activity with respect to maximal stimulation. Calmodulin increased the lipid fluidity of synaptosomal plasma membranes labeled with 1,6-diphenyl-1,3,5-hexatriene (DPH), as indicated by the steady-state fluorescence anisotropy [(r_o/r)-1]^–1. Arrhenius-type plots of [(r_o/r)-1]^–1 indicated that the lipid separation of the membrane at 22.7±1.2° was perturbed by calmodulin such that the temperature was reduced to 16.3±0.9° and 15.5±0.8° in the absence or in the presence of 20 M Ca²⁺. Arrhenius plots of guanylate cyclase and acetylcholinesterase activities exhibited brak points at 25.7±1.4° and 22.3±1.0° in control synaptosomal plasma membranes, respectively. The break point for the guanylate cyclase was reduced to 16.3±0.9° in calmodulin treated synaptosomal plasma membranes whereas that of acetylcholinesterase remained unaffected (21.1±0.9°). The allosteric properties of guanylate cyclase by Mn-GTP (as reflected by changes in the Hill coefficient) were modulated by calmodulin while those of acetylcholinesterase by fluoride (F^–) were not altered. We propose that calmodulin achieves these effects through asymmetric perturbations of the membrane lipid structure and that increase in membrane fluidity of the inner leaflet of the membrane induced by calmodulin may be an early key event to the process of neurotransmitter release.     

In Vitro Stimulation of Protein Kinase C by Melatonin

It has been shown that melatonin through binding to calmodulin acts both in vitro and in vivo as a potent calmodulin antagonist. It is known that calmodulin antagonists both bind to the hydrophobic domain of Ca²⁺ activated calmodulin, and inhibit protein kinase C activity. In this work we explored the effects of melatonin on Ca²⁺ dependent protein kinase C activity in vitro using both a pure commercial rat brain protein kinase C, and a partially purified enzyme from MDCK and N1E-115 cell homogenates. The results showed that melatonin directly activated protein kinase C with a half stimulatory concentration of 1 nM. In addition the hormone augmented by 30% the phorbol ester stimulated protein kinase C activity and increased [³H] PDBu binding to the kinase. In contrast, calmodulin antagonists (500 M) and protein kinase C inhibitors (100 M) abolished the enzyme activity. Melatonin analogs tested were ineffective in increasing either protein kinase C activity or [³H] PDBu binding. Moreover, the hormone stimulated protein kinase C autophosphorylation directly and in the presence of phorbol ester and phosphatidylserine. The results show that besides the melatonin binding to calmodulin, the hormone also interacts with protein kinase C only in the presence of Ca²⁺. They also suggest that the melatonin mechanism of action may involve interactions with other intracellular hydrophobic and Ca²⁺ dependent proteins.     

Properties of the aminotyrosine derivatives of calmodulin

Derivatives of calmodulin have been prepared in which tyrosine-99 and tyrosine-138 have been converted to their aminotyrosine derivatives. Significant changes in microenvironment occur in the presence of Ca²⁺. Both groups have a significant degree of mobility with respect to the protein matrix; this is Ca²⁺ dependent.     

Paramecium Na+ channels activated by Ca2+-calmodulin: Calmodulin is the Ca2+ sensor in the channel gating mechanism

Paramecium Na⁺ channels, which were Ca²⁺-calmodulin activated, were studied in the inside-out mode of patch clamp. After excision of the membrane patch, they were active in the presence of 10^–5 to 10^–3 m Ca²⁺ in the bath. They became much less active in the presence of 10^–6 m Ca²⁺, and their activity subsided completely at 10^–8 m Ca²⁺. A Hill plot showed a dissociation constant of 6 m for Ca²⁺ binding. This dissociation constant shifted to a submicromolar range in the presence of 1 mm Mg²⁺. The channels also exhibited a mild voltage dependence. When exposed to 10^–8 m Ca²⁺ for an extended period of 2–4 min, channels were further inactivated even after bath Ca²⁺ was restored to 10^–4 m. Whereas neither high voltage (+100 mV) nor high Ca²⁺ (10^–3 m) was effective in reactivation of the inactive channels, addition of Paramecium wild-type calmodulin together with high Ca²⁺ to the bath restored channel activity without a requirement of additional Mg²⁺ and metabolites such as ATP. The channels reactivated by calmodulin had the same ion conductance, ion selectivity and Ca²⁺ sensitivity as those prior to inactivation. These inactivation and reactivation of the channels could be repeated, indicating that the direct calmodulin effect on the Na⁺ channel was reversible. Thus, calmodulin is a physiological factor critically required for Na⁺ channel activation, and is the Ca²⁺ sensor of the Na⁺-channel gating machinery.We thank C. Kung for his kind support, and A. Boileau for critical reading. Supported by grants from National Institutes of Health GM 22714-20 and 36386-09.     

Protein phosphorylation and its regulation by calcium and calmodulin in membrane fractions from zucchini hypocotyls

Protein-kinase activity has been found to be associated with a membrane fraction obtained from dark-grown zucchini (Cucurbita pepo L., cv. Senator) hypocotyl hooks. Proteins of this membrane fraction were used as protein substrates. The effects of Mg²⁺, Na⁺ and K⁺ on phosphorylation, measured as ³²P incorporation, was investigated. The kinetics of phosphorylation of the individual protein peptides indicate the presence of specific phosphatase activity. Phosphorylation activity is strongly influenced by Ca²⁺. One peptide (relative molecular weight: 180,000) exhibits strong inhibition of ³²P incorporation at physiological Ca²⁺ concentrations between 0.1 and 1 μM. Phosphorylation of about 10 other proteins was enhanced by Ca²⁺, being maximal in most cases at a concentration of about 3 μM free Ca²⁺. Five out of these 10 peptides show increased phosphorylation in the presence of 1 μM calmodulin. This calmodulin-dependent enhancement of phosphorylation could be completely inhibited by the calmodulin antagonist fluphenazine. Cyclic AMP was found to have no stimulating effect on protein phosphorylation.     

Determinants in CaV1 Channels That Regulate the Ca2+ Sensitivity of Bound Calmodulin

Calmodulin binds to IQ motifs in the α₁ subunit of Ca_V1.1 and Ca_V1.2, but the affinities of calmodulin for the motif and for Ca²⁺ are higher when bound to Ca_V1.2 IQ. The Ca_V1.1 IQ and Ca_V1.2 IQ sequences differ by four amino acids. We determined the structure of calmodulin bound to Ca_V1.1 IQ and compared it with that of calmodulin bound to Ca_V1.2 IQ. Four methionines in Ca²⁺-calmodulin form a hydrophobic binding pocket for the peptide, but only one of the four nonconserved amino acids (His-1532 of Ca_V1.1 and Tyr-1675 of Ca_V1.2) contacts this calmodulin pocket. However, Tyr-1675 in Ca_V1.2 contributes only modestly to the higher affinity of this peptide for calmodulin; the other three amino acids in Ca_V1.2 contribute significantly to the difference in the Ca²⁺ affinity of the bound calmodulin despite having no direct contact with calmodulin. Those residues appear to allow an interaction with calmodulin with one lobe Ca²⁺-bound and one lobe Ca²⁺-free. Our data also provide evidence for lobe-lobe interactions in calmodulin bound to Ca_V1.2.The complexity of eukaryotic Ca²⁺ signaling arises from the ability of cells to respond differently to Ca²⁺ signals that vary in amplitude, duration, and location. A variety of mechanisms decode these signals to drive the appropriate physiological responses. The Ca²⁺ sensor for many of these physiological responses is the Ca²⁺-binding protein calmodulin (CaM).² The primary sequence of CaM is tightly conserved in all eukaryotes, yet it binds and regulates a broad set of target proteins in response to Ca²⁺ binding. CaM has two domains that bind Ca²⁺ as follows: an amino-terminal domain (N-lobe) and a carboxyl-terminal domain (C-lobe) joined via a flexible α-helix. Each lobe of CaM binds two Ca²⁺ ions, and binding within each lobe is highly cooperative. The two lobes of CaM, however, have distinct Ca²⁺ binding properties; the C-lobe has higher Ca²⁺ affinity because of a slower rate of dissociation, whereas the N-lobe has weaker Ca²⁺ affinity and faster kinetics (1). CaM can also bind to some target proteins in both the presence and absence of Ca²⁺, and the preassociation of CaM in low Ca²⁺ modulates the apparent Ca²⁺ affinity of both the amino-terminal and carboxyl-terminal lobes. Differences in the Ca²⁺ binding properties of the lobes and in the interaction sites of the amino- and carboxyl-terminal lobes enable CaM to decode local versus global Ca²⁺ signals (2).Even though CaM is highly conserved, CaM target (or recognition) sites are quite heterogeneous. The ability of CaM to bind to very different targets is at least partially due to its flexibility, which allows it to assume different conformations when bound to different targets. CaM also binds to various targets in distinct Ca²⁺ saturation states as follows: Ca²⁺-free (3), Ca²⁺ bound to only one of the two lobes, or fully Ca²⁺-bound (4–7). In addition, CaM may bind with both lobes bound to a target (5, 6) or with only a single lobe engaged (8). If a target site can bind multiple conformers of CaM, CaM may undergo several transitions that depend on Ca²⁺ concentration, thereby tuning the functional response. Identification of stable intermediate states of CaM bound to individual targets will help to elucidate the steps involved in this fine-tuned control.Both Ca_V1.1 and Ca_V1.2 belong to the L-type family of voltage-dependent Ca²⁺ channels, which bind apoCaM and Ca²⁺-CaM at carboxyl-terminal recognition sites in their α₁ subunits (9–14). Ca²⁺ binding to CaM, bound to Ca_V1.2 produces Ca²⁺-dependent facilitation (CDF) (14). Whether Ca_V1.1 undergoes CDF is not known. However, both Ca_V1.2 and Ca_V1.1 undergo Ca²⁺- and CaM-dependent inactivation (CDI) (14, 15). Ca_V1.1 CDI is slower and more sensitive to buffering by 1,2-bis(o-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid than Ca_V1.2 CDI (15). Ca²⁺ buffers are thought to influence CDI and/or CDF in voltage-dependent Ca²⁺ channels by competing with CaM for Ca²⁺ (16).The conformation of the carboxyl terminus of the α₁ subunit is critical for channel function and has been proposed to regulate the gating machinery of the channel (17, 18). Several interactions of this region include intramolecular contacts with the pore inactivation machinery and intermolecular contacts with CaM kinase II and ryanodine receptors (17, 19–22). Ca²⁺ regulation of Ca_V1.2 may involve several motifs within this highly conserved region, including an EF hand motif and three contiguous CaM-binding sequences (10, 12). ApoCaM and Ca²⁺-CaM-binding sites appear to overlap at the site designated as the “IQ motif” (9, 12, 13), which are critical for channel function at the molecular and cellular level (14, 23).Differences in the rate at which 1,2-bis(o-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid affects CDI of Ca_V1.1 and Ca_V1.2 could reflect differences in their interactions with CaM. In this study we describe the differences in CaM interactions with the IQ motifs of the Ca_V1.1 and the Ca_V1.2 channels in terms of crystal structure, CaM affinity, and Ca²⁺ binding to CaM. We find the structures of Ca²⁺-CaM-IQ complexes are similar except for a single amino acid change in the peptide that contributes to its affinity for CaM. We also find that the other three amino acids that differ in Ca_V1.2 and Ca_V1.1 contribute to the ability of Ca_V1.2 to bind a partially Ca²⁺-saturated form of CaM.     

Quantitative aspects of the development of a hydrophobic binding site on calmodulin by calcium binding

The interactive binding by calmodulin of Ca²⁺ and 1-anilinonaphthalene-8-sulfonate (1,8-ANS) has been examined. In the presence of saturating levels of Ca²⁺, calmodulin develops one moderately strong binding site for 1,8-ANS, plus one or more weaker sites. The binding of 1,8-ANS by unliganded, or singly liganded, calmodulin is slight; the development of a strong binding site, as well as the characteristic fluorescence enhancement and CD spectrum, requires the binding of two Ca²⁺ ions. Little further change occurs on binding additional Ca²⁺ ions.     

Opiates inhibit calmodulin activation of a high-affinity Ca2+-stimulated Mg2+-dependent ATPase in synaptic membranes

A high affinity Ca²⁺/Mg²⁺ ATPase has been identified and localized in synaptic membrane subfractions. This enzyme is stimulated by low concentrations of Ca²⁺ (1 M) believed to approximate the range of Ca²⁺ in the synaptosomal cytosol (0.1 to 5.0 M). The opiate agonist levorphanol, in a concentration-dependent fashion, inhibited Ca²⁺-stimulated ATP hydrolysis in lysed synaptic membranes. This inhibition was reversed by naloxone, while dextrorphan, the inactive opiate isomer, was without effect. Inhibition by levorphanol was most pronounced in a subfraction of synaptic membranes (SPM-1). The inhibition of Ca²⁺-stimulated ATP hydrolysis was characterized by a reduction inV _max for Ca²⁺. Levorphanol pretreatment reduced the Hill coefficient (H_N) of 1.5 to 0.7, suggesting cooperative interaction between the opiate receptor and the enzyme protein. Levorphanol, but not dextrorphan, also inhibited (28%) ATP-dependent Ca²⁺ uptake by synaptic membranes. Opiate ligand stereoisomers were tested for their effects on calmodulin stimulating of high affinity Ca²⁺/Mg²⁺ ATPase in synaptic membranes. Levorphanol (10 M), but not the inactive stereoisomer (+)dextrorphan, significantly inhibited (35%) the calmodulin-activated Ca²⁺-dependent ATP hydrolysis activity in a preparation of lysed synaptic membranes. Both Ca²⁺-dependent and calmodulin-dependent stimulation of the enzyme in the presence of optimal concentrations of the other co-substrate were inhibited by levorphanol (35–40%) but not dextrorphan. Inhibition of ATP hydrolysis was characterized by a reduction inV _max for both Ca²⁺ and calmodulin stimulation of the enzyme. Calmodulin stimulation of enzyme activity was most pronounced in SPM-1, the membrane fraction which also exhibits the maximal opiate inhibition (40%) of the Ca²⁺-ATPase. The results demonstrate that opiate receptor activation inhibits a high affinity Ca²⁺/Mg²⁺ ATPase in synaptic plasma membranes in a stereospecific fashion. The inhibition of the enzyme may occur by a mechanism involving both Ca²⁺ and calmodulin. Inhibition of calmodulin activation may contribute to the mechanism by which opiate ligands disrupt synaptosomal Ca²⁺ buffering mechanisms. Changes in the cytosolic distribution of synaptosomal Ca²⁺ following inhibition of Ca²⁺/Mg²⁺ ATPase may underlie some of the pharmacological effects of opiate drugs.     

Studies on the status of tyrosyl residues in phospholipases A2 fromNaja naja atra andNaja nigricollis snake venoms

Two phospholipases A₂ (PLA₂) fromNaja naja atra andNaja nigricollis snake venoms were subjected to tyrosine modification withp-nitrobenzenesulfonyl fluoride (NBSF) atpH 8.0. Three major NBS derivatives from each PLA₂ were separated by high-performance liquid chromatography. The results of amino acid analysis showed that only two Tyr residues out of nine were modified, and the modified residues were identified to be Tyr-3 and Tyr-63 (or Tyr-62) in the sequence. Spectrophotometric titration indicated that the phenolic group of Tyr-3 and Tyr-63 (or Tyr-62) had apK of 10.1 and 11.0, respectively. The reactivity of Tyr-3 toward NBSF was not affected in the presence or absence of Ca ²⁺; however, the reactivity of Tyr-63 (or Tyr-62) toward NBSF was greatly enhanced by Ca²⁺. Modification of Tyr-63 (or Tyr-62) resulted in a marked decrease in both lethality and enzymatic activity. Conversely, modification of Tyr-3 inN. naja atra PLA₂ could cause more than a sixfold increase in lethal potency, in sharp contrast to the loss of enzymatic activity. Tyrosine-63-modifiedN. naja atra PLA₂ exhibited the same Ca²⁺-induced difference spectra as that of native PLA₂, indicating that the Ca²⁺-binding ability of Tyr-63-modifiedN. naja atra PLA₂ was not impaired. However, Tyr-3-modified PLA₂ and all Tyr-modifiedN. nigricollis CMS-9 were not perturbed by Ca²⁺, revealing that the Ca²⁺-binding ability have been lost after tyrosine modification. These results suggest that Tyr-62 inN. nigricollis CMS-9 and Tyr-3 in both enzymes are involved in Ca²⁺ binding. AtpH 8.0, both native PLA₂ enzymes enhance the emission intensity of 8-anilinonaphthalene sulfonate (ANS) dramatically, while all of the Tyr-modified derivatives did not enhance the emission intensity at all either in the presence or absence of Ca²⁺, suggesting that the hydrophobic pocket that interacts with ANS might be the substrate binding site, in which Tyr-3 and Tyr-63 (or Tyr-62) are involved.     

Calcium-dependent Regulation of SNARE-mediated Membrane Fusion by Calmodulin

Neuroexocytosis requires SNARE proteins, which assemble into trans complexes at the synaptic vesicle/plasma membrane interface and mediate bilayer fusion. Ca²⁺ sensitivity is thought to be conferred by synaptotagmin, although the ubiquitous Ca²⁺-effector calmodulin has also been implicated in SNARE-dependent membrane fusion. To examine the molecular mechanisms involved, we examined the direct action of calmodulin and synaptotagmin in vitro, using fluorescence resonance energy transfer to assay lipid mixing between target- and vesicle-SNARE liposomes. Ca²⁺/calmodulin inhibited SNARE assembly and membrane fusion by binding to two distinct motifs located in the membrane-proximal regions of VAMP2 (K_D = 500 nm) and syntaxin 1 (K_D = 2 μm). In contrast, fusion was increased by full-length synaptotagmin 1 anchored in vesicle-SNARE liposomes. When synaptotagmin and calmodulin were combined, synaptotagmin overcame the inhibitory effects of calmodulin. Furthermore, synaptotagmin displaced calmodulin binding to target-SNAREs. These findings suggest that two distinct Ca²⁺ sensors act antagonistically in SNARE-mediated fusion.     

Calcium-dependent Properties of Peptidylarginine Deiminase from Rabbit Skeletal Muscle

Peptidylarginine deiminase, which catalyzes the deimination of arginyl residues in protein, required Ca²⁺ as an essential cofactor and the half-maximal activity was attained at 40—60 μm Ca²⁺. Other divalent cations were practically inactive except for Sr²⁺, which was about 50% as active as Ca²⁺ when tested at 10 mm. However, Sr²⁺ at less than the concentration of 100 μm had little or no activity. The direct Ca²⁺-binding for the enzyme showed a sigmoidal curve with a transition midpoint of about 110 μm, indicating that the binding is cooperative. Analysis of Hill plots of the data revealed that the enzyme binds 3 mol of Ca²⁺/mol of protein with an apparent dissociation constant of llO μm. A conformational change upon Ca²⁺-binding was also described for the enzyme using UV-difference spectra. The alteration could be attributed to an increased exposure of the aromatic residues to a more aqueous environment, as has been described for Ca²⁺-binding proteins such as calmodulin. Phosphatidylserine enhanced the reaction velocity and concomitantly reduced the Ca²⁺-requirement for the enzyme. These effects were stimulated by the addition of diacylglycerol. Diacylglycerol alone had little or no effect. On the other hand, calmodulin had no effect on the enzymatic activity over a wide range of Ca²⁺ concentrations. These suggest that the activity and Ca²⁺-sensitivity of peptidylarginine deiminase is increased at the cell membrane.     

Phospholamban stoichiometry in canine cardiac muscle sarcoplasmic reticulum

Treatment of cardiac sarcoplasmic reticulum with the crosslinking reagent dithiobis (succinimidyl propionate) in the presence of¹²⁵I-calmodulin, resulted in the formation of a 40,000-dalton affinity labeled component, consisting of a 11, phospholamban:¹²⁵I-calmodulin complex. In parallel experiments, sarcoplasmic reticulum was phosphorylated in the presence of calmodulin and [-³²P]ATP, and then treated with the crosslinking reagent to produce an affinity labeled component consisting of a 11, calmodulin:³²P-phospholamban complex. These experiments permitted determination of the amount of¹²⁵I and³²P incorporated into the 40,000-dalton complexes, as well as the amount of³²P incorporated into the 23,000-dalton form of phospholamban. If 1 mol of Ca²⁺-dependent ATPase phosphoprotein represents 1 mol of 100,000-dalton Ca²⁺-dependent ATPase monomer, then there are 4.88±1.33 mol Ca²⁺-dependent ATPase/mol of phospholamba. If there are 2 mol of Ca²⁺-dependent ATPase phosphoprotein/mol of 100,000-dalton Ca²⁺-dependent ATPase monomer, then there are 9.76±2.66 mol Ca²⁺-dependent ATPase/mol phospholamban.Special issue dedicated to Dr. E. M. Shooter and Dr. S. Varon.     

Calcium-induced protein phosphorylation and changes in levels of calmodulin and calreticulin in maize sperm cells

 To examine possible calcium (Ca²⁺)-mediated prefertilization events in male gametes of higher plants, we studied protein phosphorylation and the Ca²⁺-binding proteins, calmodulin and calreticulin, in sperm cells isolated from maize (Zea mays L.) pollen in the presence and absence of Ca²⁺. Using immunoblotting, we detected calmodulin and calreticulin and Ca²⁺-induced variations. Exposure of sperm cells to 1 mM Ca²⁺ for 1 h increased calmodulin content by 136% compared with the control. Ca²⁺ had little effect on calreticulin at 1 h, but induced a 34% increase after 3 h. Phosphorylation of proteins was low in 1 h-control and Ca²⁺-treated cells. However, a 13-fold increase in phosphorylation of a 18-kDa protein was found at 12 h in the presence of Ca²⁺. Ca²⁺-induced changes in calmodulin, calreticulin and protein phosphorylation observed in maize sperm cells may reflect prefertilization changes in vivo that facilitate sperm cell fusion with egg and central cells. Received: 26 July 1996 / Revision accepted: 7 February 1997     

Expression and regulation of insulin-like growth factor binding protein-1 in the rat uterus throughout estrous cycle

The role of Ca²⁺-stimulated adenosine 5-triphosphatase (Ca²⁺-ATPase) in Ca²⁺ sequestering of rat liver nuclei was investigated. Ca²⁺-ATPase activity was calculated by subtracting Mg²⁺-ATPase activity from (Ca²⁺–Mg²⁺)-ATPase activity. Ca²⁺ uptake and release were determined with a Ca²⁺ electrode. Nuclear Ca²⁺-ATPase activity increased linearly in the range of 10–40 M Ca²⁺ addition. With those concentrations, Ca²⁺ was completely taken up by the nuclei dependently on ATP (2 mM). Nuclear Ca²⁺-ATPase activity was decreased significantly by the presence of arachidonic acid (25 and 50 M), nicotinamide-adenine dinucleotide (NAD⁺; 2 mM) and zinc sulfate (2.5 and 5.0 M). These reagents caused a significant decrease in the nuclear Ca²⁺ uptake and a corresponding elevation in Ca²⁺ release from the nuclei. Moreover, calmodulin (10 g/ml) increased significantly nuclear Ca²⁺-ATPase activity, and this increase was not seen in the presence of trifluoperazine (10 M), an antogonist of calmodulin. The present findings suggest that Ca²⁺-ATPase plays a role in Ca²⁺ sequestering by rat liver nuclei, and that calmodulin is an activator. Moreover, the inhibition of Ca²⁺-ATPase may evoke Ca²⁺ release from the Ca²⁺-loaded nuclei.     

Investigation of the Ca2+-dependent interaction of trifluoperazine with S100a: A19F NMR and circular dichroism study

S100a is a heterodimeric, acidic calcium-binding protein that interacts with calmodulin antagonists in a Ca²⁺-dependent manner. In order to study the behavior of the hydrophobic domain on S100a when bound to Ca²⁺, its interaction with trifluoperazine (TFP) was investigated using¹⁶F nuclear magnetic resonance (NMR) and circular dichroism (CD) spectroscopy. The dissociation constant (K _d) values of TFP, as estimated from the chemical shifts of¹⁹F NMR, were 191 and 29 m in the absence and presence of Ca²⁺, respectively, and were similar to those previously reported for S100b. However, the TFP linewidth in the presence of Ca²⁺-bound S100a was 65 Hz greater than in the presence of Ca²⁺-bound S100b. This suggests a slower TFP exchange rate for S100a than for S100b. Thus, the TFP linewidths observed for each isoform may reflect differences in structural and modulatory properties of the Ca²⁺-dependent hydrophobic domains on S100a and S100b. Additionally, the presence of magnesium had no effect on the observed Ca²⁺-induced TFP spectral changes in S100a solutions. Circular dichroism studies indicate that Ca²⁺ induces a small transition from -helix to random coil in S100a; in contrast, the opposite transition is reported for calmodulin (Hennesseyet al., 1987). However, TFP did not significantly alter the secondary structure of Ca²⁺-bound S100a; this observation is similar to the effect of TFP on Ca²⁺-bound calmodulin and troponin C (Shimizu and Hatano, 1984; Gariépy and Hodges, 1983). It is, therefore, proposed that TFP binds to a hydrophobic domain on S100a in a fashion similar to other calcium-modulated proteins.     

Fluorescence study on transmembrane Ca2+ gradient-mediated conformation changes of sarcoplasmic reticulum Ca2+-ATPase

The conformational states of Ca²⁺-ATPase in sarcoplasmic reticulum (SR) vesicles with or without a thousand-fold transmembrane Ca²⁺ gradient have been studied by fluorescence spectroscopy and fluorescence quenching. In consequence of the establishment of the transmembrane Ca²⁺ gradient, the steady-state fluorescence results revealed a reproducible 8% decrease in the intrinsic fluorescence while time-resolved fluorescence measurements showed that 13 tryptophan residues in SR · Ca²⁺-ATPase could be divided into three groups. The fluorescence lifetime of one of these groups increased from 5.5 ns to 5.95 ns in the presence of a Ca²⁺ gradient. Using KI and hypocrellin B (a photosensitive pigment obtained from a parasitic fungus, growing in Yunnan, China), the fluorescence quenching further indicated that the dynamic change of this tryptophan group, located at the protein-lipid interface, is a characteristic of transmembrane Ca²⁺ gradient-mediated conformational changes in SR · Ca²⁺-ATPase.Abbreviations SR sarcoplasmic reticulum - HB hypocrellin B - Trp tryptophan - DMSO dimethysulfoxide - Hepes N-2-hydroxyethyl piperazine-N-ethanesulfonic acad - SR(50005) SR vesicles with 1000-fold transmembrane Ca²⁺ gradient - SR(5050) SR vesicles without Ca²⁺ gradient - K_sv(app) apparent Stern-Volmer constant - K_svi Stern-Volmer constant of component i for dynamic quenching     

Calcium transport affinity,ion competition and cholera toxin effects on cytosolic Ca concentration

Summary The physiological relevance of an apparent ionophore activity of cholera toxin towards Ca²⁺ has been examined in several different systems designed to measure affinity, specificity, rates of ion transfer, and effects on intracellular ion concentrations. Half-maximal transfer rates across porcine jejunal brush-border vesicles were obtained at a concentration of 0.20 M Ca²⁺. When examined in the presence of competing ions the transfer process was blocked by very low concentrations of La³⁺ or Cd²⁺. Sr²⁺, Ba²⁺ and Mg²⁺ were relatively inefficient competitors for Ca²⁺ transport mediated by cholera toxin. The relative affinities observed would be compatible with a selectivity for Ca²⁺ transfer at physiological ion concentrations, as well as an inhibition of this ionophore activity by recognized antagonists of cholera toxin such as lanthanum ions. Entry rates of Ca²⁺ into brush-border vesicles exposed to cholera toxin were large enough to accelerate the collapse of a Ca²⁺ gradient generated by endogenous Ca, Mg-ATPase activity. The treatment of isolated jejunal enterocytes with cholera toxin caused a significant elevation in cytosolic Ca²⁺ concentrations as measured by Quin-2 fluorescence. This effect was specifically prevented by prior exposure of the cholera toxin to excess ganglioside G_M1. We conclude that cholera toxin has many of the properties required for promoting transmembranes Ca²⁺ movement in membrane vesicles and appears to be an effective Ca²⁺ ionophore in isolated mammalian cells.