Calmodulin Activity Research Articles

Spine neck geometry determines spino-dendritic cross-talk in the presence of mobile endogenous calcium binding proteins

Dendritic spines are thought to compartmentalize second messengers like Ca2+. The notion of isolated spine signaling, however, was challenged by the recent finding that under certain conditions mobile endogenous Ca(2+)-binding proteins may break the spine limit and lead to activation of Ca(2+)-dependent dendritic signaling cascades. Since the size of spines is variable, the spine neck may be an important regulator of this spino-dendritic crosstalk. We tested this hypothesis by using an experimentally defined, kinetic computer model in which spines of Purkinje neurons were coupled to their parent dendrite by necks of variable geometry. We show that Ca2+ signaling and calmodulin activation in spines with long necks is essentially isolated from the dendrite, while stubby spines show a strong coupling with their dendrite, mediated particularly by calbindin D28k. We conclude that the spine neck geometry, in close interplay with mobile Ca(2+)-binding proteins, regulates the spino-dendritic crosstalk.

Functional Properties Of The CaV1.2 Calcium Channel Activated By Calmodulin In The Absence Of α2δ Subunits

Voltage-activated Cav1.2 calcium channels require association of the pore-forming α1C subunit with accessory Cavβ and α2δ subunits. Binding of a single calmodulin (CaM) to α1C supports Ca2+-dependent inactivation (CDI). The human Cav1.2 channel is silent in the absence of Cavβ and/or α2δ. Recently, we found that coexpression of exogenous CaM (CaMex) supports plasma-membrane targeting, gating facilitation and CDI of the channel in the absence of Cavβ. Here we discovered that CaMex and its Ca2+-insensitive mutant (CaM1234) activate the α1C/Cavβ channel in the absence of α2δ. Coexpression of CaMex with α1C and β2d in calcium-channel-free COS1 cells recovered gating of the channel and supported CDI. Voltage-dependence of activation was shifted by ≈ +40 mV to depolarization potentials. The calcium current reached maximum at +40 mV (20 mM Ca2+) and exhibited ≈3 times slower activation and 5 times slower inactivation kinetics compared to the wild-type channel. Furthermore, both CaMex and CaM1234 accelerated recovery from inactivation and induced facilitation of the calcium current by strong depolarization prepulse, the properties absent from the human vascular/neuronal Cav1.2 channel. The data suggest a previously unknown action of CaM that in the presence of Cavβ translates into activation of the α2δ-deficient calcium channel and alteration of its properties.

A New Conformation in Sarcoplasmic Reticulum Calcium Pump and Plasma Membrane Ca2+ Pumps Revealed by a Photoactivatable Phospholipidic Probe

The purpose of this work was to obtain structural information about conformational changes in the membrane region of the sarcoplasmic reticulum (SERCA) and plasma membrane (PMCA) Ca(2+) pumps. We have assessed changes in the overall exposure of these proteins to surrounding lipids by quantifying the extent of protein labeling by a photoactivatable phosphatidylcholine analog 1-palmitoyl-2-[9-[2'-[(125)I]iodo-4'-(trifluoromethyldiazirinyl)-benzyloxycarbonyl]-nonaoyl]-sn-glycero-3-phosphocholine ([(125)I]TID-PC/16) under different conditions. We determined the following. 1) Incorporation of [(125)I]TID-PC/16 to SERCA decreases 25% when labeling is performed in the presence of Ca(2+). This decrease in labeling matches qualitatively the decrease in transmembrane surface exposed to the solvent calculated from crystallographic data for SERCA structures. 2) Labeling of PMCA incubated with Ca(2+) and calmodulin decreases by approximately the same amount. However, incubation with Ca(2+) alone increases labeling by more than 50%. Addition of C28, a peptide that prevents activation of PMCA by calmodulin, yields similar results. C28 has also been shown to inhibit ATPase SERCA activity. Interestingly, incubation of SERCA with C28 also increases [(125)I]TID-PC/16 incorporation to the protein. These results suggest that in both proteins there are two different E(1) conformations as follows: one that is auto-inhibited and is in contact with a higher amount of lipids (Ca(2+) + C28 for SERCA and Ca(2+) alone for PMCA), and one in which the enzyme is fully active (Ca(2+) for SERCA and Ca(2+)-calmodulin for PMCA) and that exhibits a more compact transmembrane arrangement. These results are the first evidence that there is an autoinhibited conformation in these P-type ATPases, which involves both the cytoplasmic regions and the transmembrane segments.

Functional properties of the Cav1.2 calcium channel activated by calmodulin in the absence of α2δ subunits

Voltage-activated Cav1.2 calcium channels require association of the pore-forming α1C subunit with accessory Cavβ and α2δ subunits. Binding of a single calmodulin (CaM) to α1C supports Ca2+-dependent inactivation (CDI). The human Cav1.2 channel is silent in the absence of Cavβ and/or α2δ. Recently, we found that coexpression of exogenous CaM (CaMex) supports plasma membrane targeting, gating facilitation and CDI of the channel in the absence of Cavβ. Here we discovered that CaMex and its Ca2+-insensitive mutant (CaM1234) rendered active α1C/Cavβ channel in the absence of α2δ. Coexpression of CaMex with α1C and β2d in calcium-channel-free COS-1 cells recovered gating of the channel and supported CDI. Voltage-dependence of activation was shifted by ≈ +40 mV to depolarization potentials. The calcium current reached maximum at +40 mV (20 mM Ca2+) and exhibited approximately 3 times slower activation and 5 times slower inactivation kinetics compared to the wild-type channel. Furthermore, both CaMex and CaM1234 accelerated recovery from inactivation and induced facilitation of the calcium current by strong depolarization prepulse, the properties absent from the human vascular/neuronal Cav1.2 channel. The data suggest a previously unknown action of CaM that in the presence of Cavβ translates into activation of the α2δ-deficient calcium channel and alteration of its properties.

Calmodulin and guanylyl cyclase inhibitors block the in vivo expression of gLTP in sympathetic ganglia from chronically stressed rats

Previous work from this laboratory indicated that superior cervical ganglia from rats exposed to chronic psychosocial stress expressed ganglionic long-term potentiation (gLTP) in vivo. In the present study, we report additional pharmacological evidence indicating involvement of calmodulin and guanylyl cyclase in gLTP, and supporting the in vivo gLTP expression in ganglia from chronically stressed rats. Pretreatment with the calmodulin inhibitors W-7 (5 μM) or calmidazolium (5 μM) or with guanylyl cyclase inhibitor LY-83583 (5 μM) completely blocked HFS (20 Hz/20 s)-induced gLTP in superior cervical ganglia isolated from normal rats. Along with that, inhibition of apparent basal ganglionic transmission by W-7 (5 μM), calmidazolium (5 μM) or LY-83583 (5 μM) is observed in ganglia isolated from chronically stressed rats, but not in those from control rats, indicating in vivo expression of gLTP in ganglia isolated from stressed rats. The present results confirm the involvement of both calmodulin and GC activities in gLTP, and indicate that ganglia from stressed rats may have expressed gLTP in vivo, which is known to precipitate hypertension in these animals.

Intraprotein electron transfer in inducible nitric oxide synthase holoenzyme

Intraprotein electron transfer (IET) from flavin mononucleotide (FMN) to heme is essential in NO synthesis by NO synthase (NOS). Our previous laser flash photolysis studies provided a direct determination of the kinetics of the FMN-heme IET in a truncated two-domain construct (oxyFMN) of murine inducible NOS (iNOS), in which only the oxygenase and FMN domains along with the calmodulin (CaM) binding site are present (Feng et al. J. Am. Chem. Soc. 128, 3808-3811, 2006). Here we report the kinetics of the IET in a human iNOS oxyFMN construct, a human iNOS holoenzyme, and a murine iNOS holoenzyme, using CO photolysis in comparative studies on partially reduced NOS and a NOS oxygenase construct that lacks the FMN domain. The IET rate constants for the human and murine iNOS holoenzymes are 34 +/- 5 and 35 +/- 3 s(-1), respectively, thereby providing a direct measurement of this IET between the catalytically significant redox couples of FMN and heme in the iNOS holoenzyme. These values are approximately an order of magnitude smaller than that in the corresponding iNOS oxyFMN construct, suggesting that in the holoenzyme the rate-limiting step in the IET is the conversion of the shielded electron-accepting (input) state to a new electron-donating (output) state. The fact that there is no rapid IET component in the kinetic traces obtained with the iNOS holoenzyme implies that the enzyme remains mainly in the input state. The IET rate constant value for the iNOS holoenzyme is similar to that obtained for a CaM-bound neuronal NOS holoenzyme, suggesting that CaM activation effectively removes the inhibitory effect of the unique autoregulatory insert in neuronal NOS.

Role of the N- and C-Lobes of Calmodulin in the Activation of Ca2+/Calmodulin-Dependent Protein Kinase II

Understanding the principles of calmodulin (CaM) activation of target enzymes will help delineate how this seemingly simple molecule can play such a complex role in transducing Ca (2+)-signals to a variety of downstream pathways. In the work reported here, we use biochemical and biophysical tools and a panel of CaM constructs to examine the lobe specific interactions between CaM and CaMKII necessary for the activation and autophosphorylation of the enzyme. Interestingly, the N-terminal lobe of CaM by itself was able to partially activate and allow autophosphorylation of CaMKII while the C-terminal lobe was inactive. When used together, CaMN and CaMC produced maximal CaMKII activation and autophosphorylation. Moreover, CaMNN and CaMCC (chimeras of the two N- or C-terminal lobes) both activated the kinase but with greater K act than for wtCaM. Isothermal titration calorimetry experiments showed the same rank order of affinities of wtCaM > CaMNN > CaMCC as those determined in the activity assay and that the CaM to CaMKII subunit binding ratio was 1:1. Together, our results lead to a proposed sequential mechanism to describe the activation pathway of CaMKII led by binding of the N-lobe followed by the C-lobe. This mechanism contrasts the typical sequential binding mode of CaM with other CaM-dependent enzymes, where the C-lobe of CaM binds first. The consequence of such lobe specific binding mechanisms is discussed in relation to the differential rates of Ca (2+)-binding to each lobe of CaM during intracellular Ca (2+) oscillations.

Innate immunity signaling: cytosolic Ca2+ elevation is linked to downstream nitric oxide generation through the action of calmodulin or a calmodulin-like protein.

Ca(2+) rise and nitric oxide (NO) generation are essential early steps in plant innate immunity and initiate the hypersensitive response (HR) to avirulent pathogens. Previous work from this laboratory has demonstrated that a loss-of-function mutation of an Arabidopsis (Arabidopsis thaliana) plasma membrane Ca(2+)-permeable inwardly conducting ion channel impairs HR and that this phenotype could be rescued by the application of a NO donor. At present, the mechanism linking cytosolic Ca(2+) rise to NO generation during pathogen response signaling in plants is still unclear. Animal nitric oxide synthase (NOS) activation is Ca(2+)/calmodulin (CaM) dependent. Here, we present biochemical and genetic evidence consistent with a similar regulatory mechanism in plants: a pathogen-induced Ca(2+) signal leads to CaM and/or a CaM-like protein (CML) activation of NOS. In wild-type Arabidopsis plants, the use of a CaM antagonist prevents NO generation and the HR. Application of a CaM antagonist does not prevent pathogen-induced cytosolic Ca(2+) elevation, excluding the possibility of CaM acting upstream from Ca(2+). The CaM antagonist and Ca(2+) chelation abolish NO generation in wild-type Arabidopsis leaf protein extracts as well, suggesting that plant NOS activity is Ca(2+)/CaM dependent in vitro. The CaM-like protein CML24 has been previously associated with NO-related phenotypes in Arabidopsis. Here, we find that innate immune response phenotypes (HR and [avirulent] pathogen-induced NO elevation in leaves) are inhibited in loss-of-function cml24-4 mutant plants. Pathogen-associated molecular pattern-mediated NO generation in cells of cml24-4 mutants is impaired as well. Our work suggests that the initial pathogen recognition signal of Ca(2+) influx into the cytosol activates CaM and/or a CML, which then acts to induce downstream NO synthesis as intermediary steps in a pathogen perception signaling cascade, leading to innate immune responses, including the HR.

An allosteric model of calmodulin explains differential activation of PP2B and CaMKII

Calmodulin plays a vital role in mediating bidirectional synaptic plasticity by activating either calcium/calmodulin-dependent protein kinase II (CaMKII) or protein phosphatase 2B (PP2B) at different calcium concentrations. We propose an allosteric model for calmodulin activation, in which binding to calcium facilitates the transition between a low-affinity [tense (T)] and a high-affinity [relaxed (R)] state. The four calcium-binding sites are assumed to be nonidentical. The model is consistent with previously reported experimental data for calcium binding to calmodulin. It also accounts for known properties of calmodulin that have been difficult to model so far, including the activity of nonsaturated forms of calmodulin (we predict the existence of open conformations in the absence of calcium), an increase in calcium affinity once calmodulin is bound to a target, and the differential activation of CaMKII and PP2B depending on calcium concentration.

Mechanism of Ca2+-influx and Ca2+/calmodulin-dependent protein kinase IV activity during in utero hypoxia in cerebral cortical neuronal nuclei of the guinea pig fetus at term

Previously we showed that following hypoxia there is an increase in nuclear Ca(2+)-influx and Ca(2+)/calmodulin-dependent protein kinase IV activity (CaMK IV) in the cerebral cortex of term guinea pig fetus. The present study tests the hypothesis that clonidine administration will prevent hypoxia-induced increased neuronal nuclear Ca(2+)-influx and increased CaMK IV activity, by blocking high-affinity Ca(2+)-ATPase. Studies were conducted in 18 pregnant guinea pigs at term, normoxia (Nx, n=6), hypoxia (Hx, n=6) and clonidine with Hx (Hx+Clo, n=6). The pregnant guinea pig was exposed to a decreased FiO(2) of 0.07 for 60 min. Clonidine, an imidazoline inhibitor of high-affinity Ca(2+)-ATPase, was administered 12.5 microg/kg IP 30 min prior to hypoxia. Hypoxia was determined biochemically by ATP and phosphocreatine (PCr) levels. Nuclei were isolated and ATP-dependent (45)Ca(2+)-influx was determined. CaMK IV activity was determined by (33)P-incorporation into syntide 2 for 2 min at 37 degrees C in a medium containing 50mM HEPES (pH 7.5), 2mM DTT, 40muM syntide 2, 0.2mM (33)P-ATP, 10mM magnesium acetate, 5 microM PKI 5-24, 2 microM PKC 19-36 inhibitor peptides, 1 microM microcystine LR, 200 microM sodium orthovanadate and either 1mM EGTA (for CaMK IV-independent activity) or 0.8mM CaCl(2) and 1mM calmodulin (for total activity). ATP (mumoles/gbrain) values were significantly different in the Nx (4.62+/-0.2), Hx (1.65+/-0.2, p<0.05 vs. Nx), and Hx+Clo (1.92+/-0.6, p<0.05 vs. Nx). PCr (mumoles/g brain) values in the Nx (3.9+/-0.1), Hx (1.10+/-0.3, p<0.05 vs. Nx), and Hx+Clo (1.14+/-0.3, p<0.05 vs. Nx). There was a significant difference between nuclear Ca(2+)-influx (pmoles/mg protein/min) in Nx (3.98+/-0.4), Hx (10.38+/-0.7, p<0.05 vs. Nx), and Hx+Clo (7.35+/-0.9, p<0.05 vs. Nx, p<0.05 vs. Hx), and CaM KIV (pmoles/mg protein/min) in Nx (1314.00+/-195.4), Hx (2315.14+/-148.5, p<0.05 vs. Nx), and Hx+Clo (1686.75+/-154.3, p<0.05 vs. Nx, p<0.05 vs. Hx). We conclude that the mechanism of hypoxia-induced increased nuclear Ca(2+)-influx is mediated by high-affinity Ca(2+)-ATPase and that CaMK IV activity is nuclear Ca(2+)-influx-dependent. We speculate that hypoxia-induced alteration of high-affinity Ca(2+)-ATPase is a key step that triggers nuclear Ca(2+)-influx, leading to CREB protein-mediated increased expression of apoptotic proteins and hypoxic neuronal death.

Calmodulin Activation by Calcium Transients in the Postsynaptic Density of Dendritic Spines

The entry of calcium into dendritic spines can trigger a sequence of biochemical reactions that begins with the activation of calmodulin (CaM) and ends with long-term changes to synaptic strengths. The degree of activation of CaM can depend on highly local elevations in the concentration of calcium and the duration of transient increases in calcium concentration. Accurate measurement of these local changes in calcium is difficult because the spaces are so small and the numbers of molecules are so low. We have therefore developed a Monte Carlo model of intracellular calcium dynamics within the spine that included calcium binding proteins, calcium transporters and ion channels activated by voltage and glutamate binding. The model reproduced optical recordings using calcium indicator dyes and showed that without the dye the free intracellular calcium concentration transient was much higher than predicted from the fluorescent signal. Excitatory postsynaptic potentials induced large, long-lasting calcium gradients across the postsynaptic density, which activated CaM. When glutamate was released at the synapse 10 ms before an action potential occurred, simulating activity patterns that strengthen hippocampal synapses, the calcium gradient and activation of CaM in the postsynaptic density were much greater than when the order was reversed, a condition that decreases synaptic strengths, suggesting a possible mechanism underlying the induction of long-term changes in synaptic strength. The spatial and temporal mechanisms for selectivity in CaM activation demonstrated here could be used in other signaling pathways.

Plant form and function

Plant form and function

A nitric oxide/Ca2+/calmodulin/ERK1/2 mitogen‐activated protein kinase pathway is involved in the mitogenic effect of IL‐1β in human astrocytoma cells

Evidence is accumulating to support a role for interleukin-1beta (IL-1beta) in astrocyte proliferation. However, the mechanism by which this cytokine modulates this process is not fully elucidated. In this study we used human astrocytoma U-373MG cells to investigate the role of nitric oxide (NO), intracellular Ca(2+) concentration ([Ca(2+)](i)), and extracellular signal-regulated protein kinase (ERK) in the signalling pathway mediating IL-1beta-induced astrocyte proliferation. Low IL-1beta concentrations induced dose-dependent ERK activation which paralleled upregulation of cell division, whereas higher concentrations gradually reversed both these responses by promoting apoptosis. Pretreatment with the nonspecific NOS inhibitor, N-omega-nitro-l-arginine methyl ester (L-NAME) or the selective iNOS inhibitor, N-[[3-(aminomethyl)phenyl]methyl]-ethanimidamide dihydrochloride (1400W), antagonized ERK activation and cell proliferation induced by IL-1beta. Inhibition of cGMP formation by the guanylate cyclase inhibitor, 1H-[1,2,4]oxadiazolo[4,3-a]quinoxalin-1-one (ODQ), partially inhibited ERK activation and cell division. Functionally blocking Ca(2+) release from endoplasmic reticulum with ryanodine or 2-aminoethoxydiphenylborane (2-APB), inhibiting calmodulin (CaM) activity with N-(6-aminohexyl)-5-chloro-1-naphthalenesulphonamide hydrochloride (W7) or MAPK kinase activity with 1,4-diamino-2,3-dicyano-1,4-bis[2-aminophenylthiol]butadiene (U0126) downregulated IL-1beta-induced ERK activation as well as cell proliferation. The cytokine induced a transient and time-dependent increase in intracellular NO levels which preceded elevation in [Ca(2+)](i). These data identified the NO/Ca(2+)/CaM/ERK signalling pathway as a novel mechanism mediating the mitogenic effect of IL-1beta in human astrocytes. As astrocyte proliferation is a hallmark of reactive astrogliosis, our results reveal a new potential target for therapeutic intervention in neuroinflammatory disorders.

The Secondary Structure of Calcineurin Regulatory Region and Conformational Change Induced by Calcium/Calmodulin Binding

The protein serine/threonine phosphatase calcineurin (CN) is activated by calmodulin (CaM) in response to intracellular calcium mobilization. A widely accepted model for CN activation involves displacement of the CN autoinhibitory peptide (CN(467-486)) from the active site upon binding of CaM. However, CN activation requires calcium binding both to the low affinity sites of CNB and to CaM, and previous studies did not dissect the individual contributions of CNB and CaM to displacement of the autoinhibitory peptide from the active site. In this work we have produced separate CN fragments corresponding to the CNA regulatory region (CNRR(381-521), residues 381-521), the CNA catalytic domain truncated at residue 341, and the CNA-CNB heterodimer with CNA truncated at residue 380 immediately after the CNB binding helix. We show that the separately expressed regulatory region retains its ability to inhibit CN phosphatase activity of the truncated CN341 and CN380 and that the inhibition can be reversed by calcium/CaM binding. Tryptophan fluorescence quenching measurements further indicate that the isolated regulatory region inhibits CN activity by occluding the catalytic site and that CaM binding exposes the catalytic site. The results provide new support for a model in which calcium binding to CNB enables CaM binding to the CNA regulatory region, and CaM binding then instructs an activating conformational change of the regulatory region that does not depend further on CNB. Moreover, the secondary structural content of the CNRR(381-521) was tentatively addressed by Fourier transform infrared spectroscopy. The results indicate that the secondary structure of CNRR(381-521) fragment is predominantly random coil, but with significant amount of beta-strand and alpha-helix structures.

Influence of CPZ and DMSO on the mechanism regulation of the plasma membrane Ca2+ ATPase of human erythrocyte

The calcium pumping ATPase of the erythrocyte plasma membrane (hPMCA4b) is the principal active system that expulse intracellular calcium into extracellular space in eukaryotic cells. PMCA is regulated by calmodulin (CaM), incrementing its ATP affinity. The use of molecules like chlorpromazine (CPZ) and dimethylsulfoxide (DMSO), inhibitors to hPMCA4b activity (non specific), were used in this study as a molecular tools that could help to understand the regulating mechanism of biochemical activation by CaM activation and their relationship with them. These molecules inhibit the PMCA activity, affecting its calcium homeostasis. CPZ is a phenotiazine that interfere with CaM functionality and it is commonly used in the treatment of mental disease. Erythrocytes membranes were used as the model biological system in order to assess the PMCA due to the absence of other calcium ATPases.PMCA activities in absence and presence of CaM and activated by trypsin exhibited inhibition by DMSO and CPZ. The ATPase activated with CaM in presence of CPZ does not interfere with the mechanism of regulation because there is no protection against the effect inhibitory of CPZ compared with the native PMCA. DMSO interacts with the regulation mechanism in the PMCA activated with CaM since there is the same profile of protection against the inhibition in comparison with the native enzyme. The recovery values of the activity in presence of CPZ and DMSO indicated the possible dilution of CPZ by the solvent.Supported by the grants of Fondos Mixtos CONACYT‐Edo. De Chihuahua and PROMEP‐CAEC.

Intramolecular Fluorescence Resonance Energy Transfer between Fused Autofluorescent Proteins Reveals Rearrangements of the N- and C-terminal Segments of the Plasma Membrane Ca2+ Pump Involved in the Activation

The blue and green fluorescent proteins (BFP and GFP) have been fused at the N- and C-terminal ends, respectively, of the plasma membrane Ca(2+) pump (PMCA) isoform 4xb (hPMCA4xb). The fusion protein was successfully expressed in yeast and purified by calmodulin affinity chromatography. Despite the presence of the fused autofluorescent proteins BFP-PMCA-GFP performed similarly to the wild-type enzyme with respect to Ca(2+)-ATPase activity and sensitivity to calmodulin activation. In the autoinhibited state BFP-PMCA-GFP exhibited a significant intramolecular fluorescence resonance energy transfer (FRET) consistent with the location of the fluorophores at an average distance of 45A. The FRET intensity in BFP-PMCA-GFP decreased when the enzyme was activated either by Ca(2+)-calmodulin, partial proteolysis, or acidic lipids. Moreover, FRET decreased and became insensitive to calmodulin when hPMCA4xb was activated by mutation D170N in BFP-PMCA(D170N)-GFP. The results suggest that the ends of the PMCA are in close proximity in the autoinhibited conformation, and they separate or reorient when the PMCA achieves its final activated conformation.

Potential role of NADPH-oxidase in early steps of lead-induced oxidative burst in Vicia faba roots

The mechanism of oxidative burst induced by lead in Vicia faba excised roots was investigated by luminol-dependent chemiluminescence. Results showed that lead triggered a rapid and dose-dependent increase in chemiluminescence production. In this study, specific inhibitors of putative reactive oxygen species (ROS) sources were used to determine the mechanism of lead-induced ROS generation. This generation was sensitive to dephenylene iodonium (DPI), quinacrine and imidazole, some inhibitors of the NADPH-oxidase and not inhibited by other putative ROS sources inhibitors. Data reported in this work clearly demonstrated the pivotal role of NADPH-oxidase-like enzyme in early steps of lead-induced oxidative burst. To investigate the respective implication of calmodulin and protein kinase (PK) in lead-induced NADPH-oxidase activation, excised roots were treated with the calmodulin inhibitor W7 or with the PK inhibitor staurosporine. The chemiluminescence generation inhibition by these inhibitors illustrated the role of PK in lead-induced NADPH-oxidase activation and revealed a calmodulin-dependent step. Using the calcium entry blocker La(3+) or different concentrations of calcium in the extra-cellular medium, our data highlighted the implication of Ca(2+) channel in lead-induced oxidative burst.

Intracellular calcium regulation of connexin43

The mechanism by which intracellular Ca(2+) concentration ([Ca(2+)](i)) regulates the permeability of gap junctions composed of connexin43 (Cx43) was investigated in HeLa cells stably transfected with this connexin. Extracellular addition of Ca(2+) in the presence of the Ca(2+) ionophore ionomycin produced a sustained elevation in [Ca(2+)](i) that resulted in an inhibition of the cell-to-cell transfer of the fluorescent dye Alexa fluor 594 (IC(50) of 360 nM Ca(2+)). The Ca(2+) dependency of this inhibition of Cx43 gap junctional permeability is very similar to that described in sheep lens epithelial cell cultures that express the three sheep lens connexins (Cx43, Cx44, and Cx49). The intracellular Ca(2+)-mediated decrease in cell-to-cell dye transfer was prevented by an inhibitor of calmodulin action but not by inhibitors of Ca(2+)/calmodulin-dependent protein kinase II or protein kinase C. In experiments that used HeLa cells transfected with a Cx43 COOH-terminus truncation mutant (Cx43(Delta257)), cell-to-cell coupling was similarly decreased by an elevation of [Ca(2+)](i) (IC(50) of 310 nM Ca(2+)) and similarly prevented by the addition of an inhibitor of calmodulin. These data indicate that physiological concentrations of [Ca(2+)](i) regulate the permeability of Cx43 in a calmodulin-dependent manner that does not require the major portion of the COOH terminus of Cx43.

Ca2+‐Calmodulin is Involved in Betacyanin Accumulation Induced by Dark in C3 Halophyte Suaeda salsa

Abstract The C3 halophyte Suaeda salsa was used to investigate the roles of Ca2+, Ca2+ channels, and calmodulin (CaM) in betacyanin metabolism. Seeds of S. salsa were cultured in both the dark and light for 3 days. The fresh weight and betacyanin content were much higher in S. salsa seedlings formed in the dark than in seedlings formed in the light. The addition of Ca2+ to the half‐strength MS nutrient solution promoted betacyanin accumulation in the dark, whereas Ca2+ depletion by EGTA suppressed the dark‐induced betacyanin accumulation in shoots of S. salsa. The Ca2+ channel blocker LaCl3 also inhibited dark‐induced betacyanin accumulation. The highest activity of CaM and the maximum betacyanin content decreased by 51% and 45%, respectively, in shoots of S. salsa seedlings treated with the potent CaM antagonist chlorpromazine in the dark. Furthermore, the other CaM antagonist N‐(6‐aminohexyl)‐5‐chloro‐1‐naphthalenesulfonamide (W‐7) also inhibited the activity of CaM and dark‐dependent betacyanin accumulation, whereas its less active structural analog N‐(6‐aminohexyl)‐1‐naphthalenesulfonamide (W‐5) had little effect on the responses to dark of S. salsa seedlings. These results suggest that Ca2+, Ca2+‐regulated ion channels, and CaM play an important role in dark‐induced betacyanin accumulation in the shoots of the C3 halophyte S. salsa.

Calcium Occupancy of N-Terminal Sites within Calmodulin Induces Inhibition of the Ryanodine Receptor Calcium Release Channel

Calmodulin (CaM) regulates calcium release from intracellular stores in skeletal muscle through its association with the ryanodine receptor (RyR1) calcium release channel, where CaM association enhances channel opening at resting calcium levels and its closing at micromolar calcium levels associated with muscle contraction. A high-affinity CaM-binding sequence (RyRp) has been identified in RyR1, which corresponds to a 30-residue sequence (i.e., K3614-N3643) located within the central portion of the primary sequence. However, it is presently unclear whether the identified CaM-binding sequence in association with CaM (a) senses calcium over the physiological range of calcium concentrations associated with RyR1 regulation or alternatively, (b) plays a structural role unrelated to the calcium-dependent modulation of RyR1 function. Therefore, we have measured the calcium-dependent activation of the individual domains of CaM in association with RyRp and their relationship to the CaM-dependent regulation of RyR1. These measurements utilize an engineered CaM, permitting the site-specific incorporation of N-(1-pyrene)maleimide at either T34C (PyN-CaM) or T110C (PyC-CaM) in the N- and C-domains, respectively. Consistent with prior measurements, we observe a high-affinity association of both apo-CaM and calcium-activated CaM with RyRp. Upon association with RyRp, fluorescence changes in PyN-CaM or PyC-CaM permit the measurement of the calcium-dependent activation of these individual domains. Fluorescence changes upon calcium activation of PyC-CaM in association with RyRp are indicative of high-affinity calcium-dependent activation of the C-terminal domain of CaM at resting calcium levels; at calcium levels associated with muscle contraction, activation of the N-terminal domain occurs with concomitant increases in the fluorescence intensity of PyC-CaM that is associated with structural changes within the CaM-binding sequence of RyR1. Occupancy of calcium-binding sites in the N-domain of CaM mirrors the calcium dependence of RyR1 inhibition observed at activating calcium levels, where [Ca]1/2 = 4.3 +/- 0.4 microM, suggesting a direct regulation of RyR1 function upon the calcium-dependent activation of CaM. These results indicate that occupancy of the N-terminal domain calcium binding sites in CaM bound to the identified CaM-binding sequence K3614-N3643 induces conformational rearrangements within the complex between CaM and RyR1 responsible for the CaM-dependent modulation of the RyR1 calcium release channel.