Ca2+-sensitive inactivation and facilitation of L-type Ca2+ channels both depend on specific amino acid residues in a consensus calmodulin-binding motif in the(alpha)1C subunit

Ca2+ currents in cardiac myocytes: Old story, new insights

Calcium is a ubiquitous second messenger which plays key roles in numerous physiological functions. In cardiac myocytes, Ca2+ crosses the plasma membrane via specialized voltage-gated Ca2+ channels which have two main functions: (i) carrying depolarizing current by allowing positively charged Ca2+ ions to move into the cell; (ii) triggering Ca2+ release from the sarcoplasmic reticulum. Recently, it has been suggested than Ca2+ channels also participate in excitation-transcription coupling. The purpose of this review is to discuss the physiological roles of Ca2+ currents in cardiac myocytes. Next, we describe local regulation of Ca2+ channels by cyclic nucleotides. We also provide an overview of recent studies investigating the structure-function relationship of Ca2+ channels in cardiac myocytes using heterologous system expression and transgenic mice, with descriptions of the recently discovered Ca2+ channels alpha(1D) and alpha(1E). We finally discuss the potential involvement of Ca2+ currents in cardiac pathologies, such as diseases with autoimmune components, and cardiac remodeling.

Sites on Calmodulin That Interact with the C-terminal Tail of Cav1.2 Channel

Two fragments of the C-terminal tail of the alpha(1) subunit (CT1, amino acids 1538-1692 and CT2, amino acids 1596-1692) of human cardiac L-type calcium channel (Ca(V)1.2) have been expressed, refolded, and purified. A single Ca(2+)-calmodulin binds to each fragment, and this interaction with Ca(2+)-calmodulin is required for proper folding of the fragment. Ca(2+)-calmodulin, bound to these fragments, is in a more extended conformation than calmodulin bound to a synthetic peptide representing the IQ motif, suggesting that either the conformation of the IQ sequence is different in the context of the longer fragment, or other sequences within CT2 contribute to the binding of calmodulin. NMR amide chemical shift perturbation mapping shows the backbone conformation of calmodulin is nearly identical when bound to CT1 and CT2, suggesting that amino acids 1538-1595 do not contribute to or alter calmodulin binding to amino acids 1596-1692 of Ca(V)1.2. The interaction with CT2 produces the greatest changes in the backbone amides of hydrophobic residues in the N-lobe and hydrophilic residues in the C-lobe of calmodulin and has a greater effect on residues located in Ca(2+) binding loops I and II in the N-lobe relative to loops III and IV in the C-lobe. In conclusion, Ca(2+)-calmodulin assumes a novel conformation when part of a complex with the C-terminal tail of the Ca(V)1.2 alpha(1) subunit that is not duplicated by synthetic peptides corresponding to the putative binding motifs.

Calmodulin reverses rundown of L-type Ca(2+) channels in guinea pig ventricular myocytes

Calmodulin (CaM) is implicated in regulation of Ca(2+) channels as a Ca(2+) sensor. The effect of CaM on rundown of L-type Ca(2+) channels in inside-out patch form was investigated in guinea pig ventricular myocytes. Ca(2+) channel activity disappeared within 1-3 min and did not reappear when the patch was excised and exposed to an artificial intracellular solution. However, application of CaM (0.03, 0.3, 3 microM) + 3 mM ATP to the intracellular solution within 1 min after patch excision resulted in dose-dependent activation of channel activity. Channel activity averaged 11.2%, 94.7%, and 292.9%, respectively, of that in cell-attached mode. Channel activity in inside-out patch mode was induced by CaM + ATP at nanomolar Ca(2+) concentrations ([Ca(2+)]); however, increase to micromolar [Ca(2+)] rapidly inactivated the channel activity induced, revealing that the effect of CaM on the channel was Ca(2+) dependent. At the 2nd, 4th, 6th, 8th, and 10th minutes after patch excision, CaM (0.75 microM) + ATP induced Ca(2+) channel activity to 150%, 100%, 96.9%, 29.3%, and 16.6%, respectively, revealing a time-dependent action of CaM on the channel. CaM added with adenosine 5'-(beta,gamma-imido)triphosphate (AMP-PNP) also induced channel activity, although with much lower potency and shorter duration. Protein kinase inhibitors KN-62, CaM-dependent protein kinase (CaMK)II 281-309, autocamtide-related CaMKII inhibitor peptide, and K252a (each 1-10 microM) did not block the effect of CaM, indicating that the effect of CaM on the Ca(2+) channel was phosphorylation independent. Neither CaM nor ATP alone induced Ca(2+) channel activity, showing a cooperative effect of CaM and ATP on the Ca(2+) channel. These results suggest that CaM is a crucial regulatory factor of Ca(2+) channel basal activity.

Modulation of the voltage sensor of L-type Ca2+ channels by intracellular Ca2+

Both intracellular calcium and transmembrane voltage cause inactivation, or spontaneous closure, of L-type (CaV1.2) calcium channels. Here we show that long-lasting elevations of intracellular calcium to the concentrations that are expected to be near an open channel (>/=100 microM) completely and reversibly blocked calcium current through L-type channels. Although charge movements associated with the opening (ON) motion of the channel's voltage sensor were not altered by high calcium, the closing (OFF) transition was impeded. In two-pulse experiments, the blockade of calcium current and the reduction of gating charge movements available for the second pulse developed in parallel during calcium load. The effect depended steeply on voltage and occurred only after a third of the total gating charge had moved. Based on that, we conclude that the calcium binding site is located either in the channel's central cavity behind the voltage-dependent gate, or it is formed de novo during depolarization through voltage-dependent rearrangements just preceding the opening of the gate. The reduction of the OFF charge was due to the negative shift in the voltage dependence of charge movement, as previously observed for voltage-dependent inactivation. Elevation of intracellular calcium concentration from approximately 0.1 to 100-300 microM sped up the conversion of the gating charge into the negatively distributed mode 10-100-fold. Since the "IQ-AA" mutant with disabled calcium/calmodulin regulation of inactivation was affected by intracellular calcium similarly to the wild-type, calcium/calmodulin binding to the "IQ" motif apparently is not involved in the observed changes of voltage-dependent gating. Although calcium influx through the wild-type open channels does not cause a detectable negative shift in the voltage dependence of their charge movement, the shift was readily observable in the Delta1733 carboxyl terminus deletion mutant, which produces fewer nonconducting channels. We propose that the opening movement of the voltage sensor exposes a novel calcium binding site that mediates inactivation.

Neurotransmitter modulation of extracellular H+ fluxes from isolated retinal horizontal cells of the skate

Self-referencing H(+)-selective microelectrodes were used to measure extracellular H(+) fluxes from horizontal cells isolated from the skate retina. A standing H(+) flux was detected from quiescent cells, indicating a higher concentration of free hydrogen ions near the extracellular surface of the cell as compared to the surrounding solution. The standing H(+) flux was reduced by removal of extracellular sodium or application of 5-(N-ethyl-N-isopropyl) amiloride (EIPA), suggesting activity of a Na(+)-H(+) exchanger. Glutamate decreased H(+) flux, lowering the concentration of free hydrogen ions around the cell. AMPA/kainate receptor agonists mimicked the response, and the AMPA/kainate receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) eliminated the effects of glutamate and kainate. Metabotropic glutamate agonists were without effect. Glutamate-induced alterations in H(+) flux required extracellular calcium, and were abolished when cells were bathed in an alkaline Ringer solution. Increasing intracellular calcium by photolysis of the caged calcium compound NP-EGTA also altered extracellular H(+) flux. Immunocytochemical localization of the plasmalemma Ca(2+)-H(+)-ATPase (PMCA pump) revealed intense labelling within the outer plexiform layer and on isolated horizontal cells. Our results suggest that glutamate modulation of H(+) flux arises from calcium entry into cells with subsequent activation of the plasmalemma Ca(2+)-H(+)-ATPase. These neurotransmitter-induced changes in extracellular pH have the potential to play a modulatory role in synaptic processing in the outer retina. However, our findings argue against the hypothesis that hydrogen ions released by horizontal cells normally act as the inhibitory feedback neurotransmitter onto photoreceptor synaptic terminals to create the surround portion of the centre-surround receptive fields of retinal neurones.

Ca2+-binding protein-1 facilitates and forms a postsynaptic complex with Cav1.2 (L-type) Ca2+ channels

Ca2+-binding protein-1 (CaBP1) is a Ca2+-binding protein that is closely related to calmodulin (CaM) and localized in somatodendritic regions of principal neurons throughout the brain, but how CaBP1 participates in postsynaptic Ca2+ signaling is not known. Here, we describe a novel role for CaBP1 in the regulation of Ca2+ influx through Ca(v)1.2 (L-type) Ca2+ channels. CaBP1 interacts directly with the alpha1 subunit of Ca(v)1.2 at sites that also bind CaM. CaBP1 binding to one of these sites, the IQ domain, is Ca2+ dependent and competitive with CaM binding. The physiological significance of this interaction is supported by the association of Ca(v)1.2 and CaBP1 in postsynaptic density fractions purified from rat brain. Moreover, in double-label immunofluorescence experiments, CaBP1 and Ca(v)1.2 colocalize in numerous cell bodies and dendrites of neurons, particularly in pyramidal cells in the CA3 region of the hippocampus and in the dorsal cortex. In electrophysiological recordings of cells transfected with Ca(v)1.2, CaBP1 greatly prolonged Ca2+ currents, prevented Ca2+-dependent inactivation, and caused Ca2+-dependent facilitation of currents evoked by step depolarizations and repetitive stimuli. These effects contrast with those of CaM, which promoted strong Ca2+-dependent inactivation of Ca(v)1.2 with these same voltage protocols. Our findings reveal how Ca2+-binding proteins, such as CaM and CaBP1, differentially adjust Ca2+ influx through Ca(v)1.2 channels, which may specify diverse modes of Ca2+ signaling in neurons.

Calmodulin permanently associates with rat olfactory CNG channels under native conditions

An important mechanism by which vertebrate olfactory sensory neurons rapidly adapt to odorants is feedback modulation of the Ca(2+)-permeable cyclic nucleotide-gated (CNG) transduction channels. Extensive heterologous studies of homomeric CNGA2 channels have led to a molecular model of channel modulation based on the binding of calcium-calmodulin to a site on the cytoplasmic amino terminus of CNGA2. Native rat olfactory CNG channels, however, are heteromeric complexes of three homologous but distinct subunits. Notably, in heteromeric channels, we found no role for CNGA2 in feedback modulation. Instead, an IQ-type calmodulin-binding site on CNGB1b and a similar but previously unidentified site on CNGA4 are necessary and sufficient. These sites seem to confer binding of Ca(2+)-free calmodulin (apocalmodulin), which is then poised to trigger inhibition of native channels in the presence of Ca(2+).

Calcium channel function regulated by the SH3-GK module in beta subunits

beta subunits of voltage-gated calcium channels (VGCCs) regulate channel trafficking and function, thereby shaping the intensity and duration of intracellular changes in calcium. beta subunits share limited sequence homology with the Src homology 3-guanylate kinase (SH3-GK) module of membrane-associated guanylate kinases (MAGUKs). Here, we show biochemical similarities between beta subunits and MAGUKs, revealing important aspects of beta subunit structure and function. Similar to MAGUKs, an SH3-GK interaction within beta subunits can occur both intramolecularly and intermolecularly. Mutations that disrupt the SH3-GK interaction in beta subunits alter channel inactivation and can inhibit binding between the alpha(1) and beta subunits. Coexpression of beta subunits with complementary mutations in their SH3 and GK domains rescues these deficits through intermolecular beta subunit assembly. In MAGUKs, the SH3-GK module controls protein scaffolding. In beta subunits, this module regulates the inactivation of VGCCs and provides an additional mechanism for tuning calcium responsiveness.

Identification of the components controlling inactivation of voltage-gated Ca2+ channels

Ca(2+)-dependent inactivation (CDI) of L-type voltage-gated Ca(2+) channels limits Ca(2+) entry into neurons, thereby regulating numerous cellular events. Here we present the isolation and purification of the Ca(2+)-sensor complex, consisting of calmodulin (CaM) and part of the channel's pore-forming alpha(1C) subunit, and demonstrate the Ca(2+)-dependent conformational shift that underlies inactivation. Dominant-negative CaM mutants that prevent CDI block the sensor's Ca(2+)-dependent conformational change. We show how Ile1654 in the CaM binding IQ motif of alpha(1C) forms the link between the Ca(2+) sensor and the downstream inactivation machinery, using the alpha(1C) EF hand motif as a signal transducer to activate the putative pore-occluder, the alpha(1C) I-II intracellular linker.

Intracellular Ca(2+) regulates responsiveness of cardiac L-type Ca(2+) current to protein kinase A: role of calmodulin

The goal of this study was to determine whether the protein kinase A (PKA) responsiveness of the cardiac L-type Ca(2+) current (ICa) is affected during transient increases in intracellular Ca(2+) concentration. Ventricular myocytes were isolated from 3- to 4-day-old neonatal rats and cultured on aligned collagen thin gels. When measured in 1 or 2 mM Ca(2+) external solution, the aligned myocytes displayed a large ICa that was weakly regulated (20% increase) during stimulation of PKA by 2 microM forskolin. In contrast, application of forskolin caused a 100% increase in ICa when the external Ca(2+) concentration was reduced to 0.5 mM or replaced with Ba(2+). This Ca(2+)-dependent inhibition was also observed when the cells were treated with 1 microM isoproterenol, 100 microM 3-isobutyl-1-methylxanthine, or 500 microM 8-bromo-cAMP. The responsiveness of ICa to PKA was restored during intracellular dialysis with a calmodulin (CaM) inhibitory peptide but not during treatment with inhibitors of protein kinase C, Ca(2+)/CaM-dependent protein kinase, or calcineurin. Adenoviral-mediated expression of a CaM molecule with mutations in all four Ca(2+)-binding sites also increased the PKA sensitivity of ICa. Finally, adult mouse ventricular myocytes displayed a greater response to forskolin and cAMP in external Ba(2+). Thus Ca(2+) entering the myocyte through the voltage-gated Ca(2+) channel regulates the PKA responsiveness of ICa.

Molecular determinants of Ca(2+)/calmodulin-dependent regulation of Ca(v)2.1 channels

Ca2+-dependent facilitation and inactivation (CDF and CDI) of Cav2.1 channels modulate presynaptic P/Q-type Ca2+ currents and contribute to activity-dependent synaptic plasticity. This dual feedback regulation by Ca2+ involves calmodulin (CaM) binding to the alpha1 subunit (alpha12.1). The molecular determinants for Ca2+-dependent modulation of Cav2.1 channels reside in CaM and in two CaM-binding sites in the C-terminal domain of alpha12.1, the CaM-binding domain (CBD) and the IQ-like domain. In transfected tsA-201 cells, CDF and CDI were both reduced by deletion of CBD. In contrast, alanine substitution of the first two residues of the IQ-like domain (IM-AA) completely prevented CDF but had little effect on CDI, and glutamate substitutions (IM-EE) greatly accelerated voltage-dependent inactivation but did not prevent CDI. Mutational analyses of the Ca2+ binding sites of CaM showed that both the N- and C-terminal lobes of CaM were required for full development of facilitation, but only the N-terminal lobe was essential for CDI. In biochemical assays, CaM12 and CaM34 were unable to bind CBD, whereas CaM34 but not CaM12 retained Ca2+-dependent binding to the IQ-like domain. These findings support a model in which Ca2+ binding to the C-terminal EF-hands of preassociated CaM initiates CDF via interaction with the IQ-like domain. Further Ca2+ binding to the N-terminal EF-hands promotes secondary CaM interactions with CBD, which enhance facilitation and cause a conformational change that initiates CDI. This multifaceted mechanism allows positive regulation of Cav2.1 in response to local Ca2+ increases (CDF) and negative regulation during more global Ca2+ increases (CDI).

A mechanism for the direct regulation of T-type calcium channels by Ca2+/calmodulin-dependent kinase II

Low-voltage-activated (LVA) Ca2+ channels are widely distributed throughout the CNS and are important determinants of neuronal excitability, initiating dendritic and somatic Ca2+ spikes that trigger and shape the pattern of action potential firing. Here, we define a molecular mechanism underlying the dynamic regulation of alpha1H channels (Cav3.2), by Ca2+/CaM-dependent protein kinase II (CaMKII). We show that channel regulation is selective for the LVA alpha1H Ca2+ channel subtype, depends on determinants in the alpha1H II-III intracellular loop, and requires the phosphorylation of a serine residue absent from unregulated alpha1G (Cav3.1) channels. These studies identify the alpha1H channel as a new substrate for CaMKII and provide the first molecular mechanism for the direct regulation of T-type Ca2+ channels by a protein kinase. Our data suggest a novel mechanism for modulating the integrative properties of neurons.

Calmodulin binds to the C terminus of sodium channels Nav1.4 and Nav1.6 and differentially modulates their functional properties

Modulation of voltage-gated sodium channels (VGSC) can have a major impact on cell excitability. Analysis of calmodulin (CaM) binding to GST-fusion proteins containing the C-terminal domains of Nav1.1-Nav1.9 indicates that some of the tetrodotoxin-sensitive VGSC isoforms, including NaV1.4 and NaV1.6, are able to bind CaM in a calcium-independent manner. Here we demonstrate that association with CaM is important for functional expression of NaV1.4 and NaV1.6 VGSCs. Disrupting the interaction between CaM and the C terminus of NaV1.4 and NaV1.6 channels reduced current amplitude by 99 and 62%, respectively. Overexpression of CaM increased the current generated by Nav1.4 and Nav1.6 C-terminal mutant constructs that exhibited intermediate current densities and intermediate binding affinities for CaM, demonstrating that this effect on current density was directly dependent on the ability of the C terminus to bind CaM. In addition to the effects on current density, calmodulin also was able to modulate the inactivation kinetics of Nav1.6, but not Nav1.4, currents in a calcium-dependent manner. Our data demonstrate that CaM can regulate the properties of VGSCs via calcium-dependent and calcium-independent mechanisms and suggest that modulation of neuronal sodium channels may play a role in calcium-dependent neuronal plasticity.

Unified mechanisms of Ca2+ regulation across the Ca2+ channel family

L-type (CaV1.2) and P/Q-type (CaV2.1) calcium channels possess lobe-specific CaM regulation, where Ca2+ binding to one or the other lobe of CaM triggers regulation, even with inverted polarity of modulation between channels. Other major members of the CaV1-2 channel family, R-type (CaV2.3) and N-type (CaV2.2), have appeared to lack such CaM regulation. We report here that R- and N-type channels undergo Ca(2+)-dependent inactivation, which is mediated by the CaM N-terminal lobe and present only with mild Ca2+ buffering (0.5 mM EGTA) characteristic of many neurons. These features, together with the CaM regulatory profiles of L- and P/Q-type channels, are consistent with a simplifying principle for CaM signal detection in CaV1-2 channels-independent of channel context, the N- and C-terminal lobes of CaM appear invariably specialized for decoding local versus global Ca2+ activity, respectively.

Apocalmodulin and Ca2+ calmodulin-binding sites on the CaV1.2 channel

The cardiac L-type voltage-dependent calcium channel is responsible for initiating excitation-contraction coupling. Three sequences (amino acids 1609-1628, 1627-1652, and 1665-1685, designated A, C, and IQ, respectively) of its alpha(1) subunit contribute to calmodulin (CaM) binding and Ca(2+)-dependent inactivation. Peptides matching the A, C, and IQ sequences all bind Ca(2+)CaM. Longer peptides representing A plus C (A-C) or C plus IQ (C-IQ) bind only a single molecule of Ca(2+)CaM. Apocalmodulin (ApoCaM) binds with low affinity to the IQ peptide and with higher affinity to the C-IQ peptide. Binding to the IQ and C peptides increases the Ca(2+) affinity of the C-lobe of CaM, but only the IQ peptide alters the Ca(2+) affinity of the N-lobe. Conversion of the isoleucine and glutamine residues of the IQ motif to alanines in the channel destroys inactivation (Zühlke et al., 2000). The double mutation in the peptide reduces the interaction with apoCaM. A mutant CaM unable to bind Ca(2+) at sites 3 and 4 (which abolishes the ability of CaM to inactivate the channel) binds to the IQ, but not to the C or A peptide. Our data are consistent with a model in which apoCaM binding to the region around the IQ motif is necessary for the rapid binding of Ca(2+) to the C-lobe of CaM. Upon Ca(2+) binding, this lobe is likely to engage the A-C region.

Calmodulin kinase modulates Ca2+ release in mouse skeletal muscle

Activation of the contractile machinery in skeletal muscle is initiated by the action-potential-induced release of Ca2+ from the sarcoplasmic reticulum (SR). Several proteins involved in SR Ca2+ release are affected by calmodulin kinase II (CaMKII)-induced phosphorylation in vitro, but the effect in the intact cell remains uncertain and is the focus of the present study. CaMKII inhibitory peptide or inactive control peptide was injected into single isolated fast-twitch fibres of mouse flexor digitorum brevis muscles, and the effect on free myoplasmic [Ca2+] ([Ca2+]i) and force during different patterns of stimulation was measured. Injection of the inactive control peptide had no effect on any of the parameters measured. Conversely, injection of CaMKII inhibitory peptide decreased tetanic [Ca2+]i by ~25 %, but had no significant effect on the rate of SR Ca2+ uptake or the force-[Ca2+]i relationship. Repeated tetanic stimulation resulted in increased tetanic [Ca2+]i, and this increase was smaller after CaMKII inhibition. In conclusion, CaMKII-induced phosphorylation facilitates SR Ca2+ release in the basal state and during repeated contractions, providing a positive feedback between [Ca2+]i and SR Ca2+ release.

C terminus L-type Ca2+ channel calmodulin-binding domains are 'auto-agonist' ligands in rabbit ventricular myocytes

L-type Ca2+ channel C terminus calmodulin (CaM)-binding domains are molecular determinants for Ca(2+)-CaM-dependent increases in L-type Ca2+ current (ICa), and a CaM-binding IQ domain mimetic peptide (IQmp) increases L-type Ca2+ channel current by promoting a gating mode with prolonged openings (mode 2), suggesting the intriguing possibility that CaM-binding domains are 'auto-agonist' signalling molecules. In order to test the breadth of this concept, we studied the effect of a second C terminus CaM-binding domain (CB) mp (CBmp), in conjunction with IQmp, on single L-type Ca2+ channel currents in excised cell membrane patches from rabbit ventricular myocytes. Here we show that both CBmp and IQmp are agonist ligands that non-additively increase L-type Ca2+ channel opening probability (Po) by inducing mode 2 gating. CBmp and IQmp agonist effects were lost under conditions favouring calcification of CaM (Ca(2+)-CaM, 150 nM free Ca2+ and 10-20 microM CaM), but persisted in the presence of CaM (0-20 microM) under conditions adverse to Ca(2+)-CaM (20 mM BAPTA), indicating that CaM-binding domains increase L-type Ca2+ channel Po by a low Ca(2+)-CaM activity mechanism. Increasing Ca(2+)-CaM in the bath (cytosol) reduced the efficacy of CBmp and IQmp signals with Ba2+ as charge carrier, suggesting that CaM binding motifs target a site outside of the pore region. We measured the combined effects of CBmp and Ca(2+)-CaM-dependent protein kinase II (CaMKII) on L-type Ca2+ channels by using an engineered Ca(2+)-CaM-independent form of CaMKII that remains active under low Ca(2+)-CaM conditions, permissive for CBmp signalling. CBmp and CaMKII increased L-type Ca2+ channel Po in a non-additive manner, suggesting that low and high Ca(2+)-CaM-dependent L-type Ca2+ channel facilitation pathways converge upon a common signalling mechanism.

Ca2+-sensitive regulation of E-type Ca2+ channel activity depends on an arginine-rich region in the cytosolic II-III loop

Ca2+-dependent regulation of L-type and P/Q-type Ca2+ channel activity is an important mechanism to control Ca2+ entry into excitable cells. Here we addressed the question whether the activity of E-type Ca2+ channels can also be controlled by Ca2+. Switching from Ba2+ to Ca2+ as charge carrier increased within 50 s, the density of currents observed in HEK-293 cells expressing a human Cav2.3d subunit and slowed down the inactivation kinetics. Furthermore, with Ca2+ as permeant ion, recovery from inactivation was accelerated, compared to the recovery process recorded under conditions where the accumulation of [Ca2+]i was prevented. In a Ba2+ containing bath solution the Ca2+-dependent changes of E-type channel activity could be induced by dialysing the cells with 1 micro m free [Ca2+]i suggesting that an elevation of [Ca2+]i is responsible for these effects. Deleting 19 amino acids in the intracellular II-III linker (exon 19) as part of an arginine-rich region, severely impairs the Ca2+ responsiveness of the expressed channels. Interestingly, deletion of an adjacent homologue arginine-rich region activates channel activity but now independently from [Ca2+]i. As a positive feedback-regulation of channel activity this novel activation mechanism might determine specific biological functions of E-type Ca2+ channels.

A calmodulin/inositol 1,4,5-trisphosphate (IP3) receptor-binding region targets TRPC3 to the plasma membrane in a calmodulin/IP3 receptor-independent process

Conformational coupling with the inositol 1,4,5-trisphosphate (IP3) receptor has been suggested as a possible mechanism of activation of TRPC3 channels and a region in the C terminus of TRPC3 has been shown to interact with the IP3 receptor as well as calmodulin (calmodulin/IP3 receptor-binding (CIRB) region). Here we show that internal deletion of 20 amino acids corresponding to the highly conserved CIRB region results in the loss of diacylglycerol and agonist-mediated channel activation in HEK293 cells. By using confocal microscopy to examine the cellular localization of Topaz fluorescent protein fusion constructs, we demonstrate that this loss in activity is caused by faulty targeting of CIRB-deleted mutants to intracellular compartments. Wild type TRPC3 and mutants lacking a C-terminal predicted coiled coil region downstream of CIRB were targeted to the plasma membrane correctly in HEK293 cells and exhibited TRPC3-mediated calcium entry in response to agonist activation. Mutation of conserved YQ and MKR motifs to alanine within the CIRB region in TRPC3-Topaz, which would be expected to interfere with IP3 receptor and/or calmodulin binding, had no effect on channel function or targeting. Additionally, TRPC3 targets to the plasma membrane of DT40 cells lacking all three IP3 receptors and forms functional ion channels. These findings indicate that the previously identified CIRB region of TRPC3 is involved in its targeting to the plasma membrane by a mechanism that does not involve interaction with IP3 receptors.

FRET two-hybrid mapping reveals function and location of L-type Ca2+ channel CaM preassociation

L-type Ca(2+) channels possess a Ca(2+)-dependent inactivation (CDI) mechanism, affording feedback in diverse neurobiological settings and serving as prototype for unconventional calmodulin (CaM) regulation emerging in many Ca(2+) channels. Crucial to such regulation is the preassociation of Ca(2+)-free CaM (apoCaM) to channels, facilitating rapid triggering of CDI as Ca(2+)/CaM shifts to a channel IQ site (IQ). Progress has been hindered by controversy over the preassociation site, as identified by in vitro assays. Most critical has been the failure to resolve a functional signature of preassociation. Here, we deploy novel FRET assays in live cells to identify a 73 aa channel segment, containing IQ, as the critical preassociation pocket. IQ mutations disrupting preassociation revealed accelerated voltage-dependent inactivation (VDI) as the functional hallmark of channels lacking preassociated CaM. Hence, the alpha(1C) IQ segment is multifunctional-serving as ligand for preassociation and as Ca(2+)/CaM effector site for CDI.

Ligand-activated signal transduction in the 2-cell embryo

Platelet-activating factor (PAF) is an autocrine trophic/survival factor for the preimplantation embryo. PAF induced an increase in intracellular calcium concentration ([Ca2+]i) in the 2-cell embryo that had an absolute requirement for external calcium. L-type calcium channel blockers (diltiazem, verapamil, and nimodipine) significantly inhibited PAF-induced Ca2+ transients, but inhibitors of P/Q type (omega-agatoxin; omega-conotoxin MVIIC), N-type (omega-conotoxin GVIA), T-type (pimozide), and store-operated channels (SKF 96365 and econazole) did not block the transient. mRNA and protein for the alpha1-C subunit of L-type channels was expressed in the 2-cell embryo. The L-type calcium channel agonist (+/-) BAY K 8644 induced [Ca2+]i transients and, PAF and BAY K 8644 each caused mutual heterologous desensitization of each other's responses. Depolarization of the embryo (75 mM KCl) induced a [Ca2+]i transient that was inhibited by diltiazem and verapamil. Whole-cell patch-clamp measurements detected a voltage-gated channel (blocked by diltiazem, verapamil, and nifedipine) that was desensitized by prior responses of embryos to exogenous or embryo-derived PAF. Replacement of media Ca2+ with Mn2+ allowed Mn2+ influx to be observed directly; activation of a diltiazem-sensitive influx channel was an early response to PAF. The activation of a voltage-gated L-type calcium channel in the 2-cell embryo is required for normal signal transduction to an embryonic trophic factor.

Calcium dynamics are altered in cortical neurons lacking the calmodulin-binding protein RC3

RC3 is a neuronal calmodulin-binding protein and protein kinase C substrate that is thought to play an important regulatory role in synaptic transmission and neuronal plasticity. Two molecules known to regulate synaptic transmission and neuronal plasticity are Ca(2+) and calmodulin, and proposed mechanisms of RC3 action involve both molecules. However, physiological evidence for a role of RC3 in neuronal Ca(2+) dynamics is limited. In the current study we utilized cultured cortical neurons obtained from RC3 knockout (RC3-/-) and wildtype mice (RC3+/+) and fura-2-based microscopic Ca(2+) imaging to investigate a role for RC3 in neuronal Ca(2+) dynamics. Immunocytochemical characterization showed that the RC3-/- cultures lack RC3 immunoreactivity, whereas cultures prepared from wildtype mice showed RC3 immunoreactivity at all ages studied. RC3+/+ and RC3-/- cultures were indistinguishable with respect to neuron density, neuronal morphology, the formation of extensive neuritic networks and the presence of glial fibrillary acidic protein (GFAP)-positive astrocytes and gamma-aminobutyric acid (GABA)ergic neurons. However, the absence of RC3 in the RC3-/- neurons was found to alter neuronal Ca(2+) dynamics including baseline Ca(2+) levels measured under normal physiological conditions or after blockade of synaptic transmission, spontaneous intracellular Ca(2+) oscillations generated by network synaptic activity, and Ca(2+) responses elicited by exogenous application of N-methyl-D-aspartate (NMDA) or class I metabotropic glutamate receptor agonists. Thus, significant changes in Ca(2+) dynamics occur in cortical neurons when RC3 is absent and these changes do not involve changes in gross neuronal morphology or neuronal maturation. These data provide direct physiological evidence for a regulatory role of RC3 in neuronal Ca(2+) dynamics.

Interactions with PDZ proteins are required for L-type calcium channels to activate cAMP response element-binding protein-dependent gene expression

After brief periods of heightened stimulation, calcium entry through L-type calcium channels leads to activation of the transcription factor cAMP response element-binding protein (CREB) and CRE-dependent transcription. Many of the details surrounding the mechanism by which L-type calcium channels are privileged in signaling to CREB, to the exclusion of other calcium entry pathways, has remained unclear. We hypothesized that the PDZ interaction sequence contained within the last four amino acids of the calcium channel alpha1C (Ca(V)1.2) subunit [Val-Ser-Asn-Leu (VSNL)] is critical for L-type calcium channels (LTCs) to interact with the signaling machinery that triggers activity-dependent gene expression. To disrupt this interaction, hippocampal CA3-CA1 pyramidal neurons were transfected with DNA encoding for enhanced green fluorescent protein tethered to VSNL (EGFP-VSNL). EGFP-VSNL significantly attenuated L-type calcium channel-induced CREB phosphorylation and CRE-dependent transcription, although somatic calcium concentrations after stimulation remained unchanged. The effect of EGFP-VSNL was specific to the actions of L-type calcium channels, because CREB signaling after NMDA receptor stimulation remained intact. The importance of the PDZ interaction sequence was verified using dihydropyridine (DHP)-insensitive alpha1C subunits. Neurons transfected with alpha1C lacking the terminal five amino acids (DHP-LTCnoPDZ) exhibited attenuated CREB responses in comparison with cells expressing the full-length subunit (DHP-LTC). Collectively, these data suggest that localized calcium responses, regulated by interactions with PDZ domain proteins, are necessary for L-type calcium channels to effectively activate CREB and CRE-mediated gene expression.

Inactivation of ICa-L is the major determinant of use-dependent facilitation in rat cardiomyocytes

Two models have been proposed to explain facilitation of the L-type calcium current (ICa-L). A positive feedback model proposes that calcium released during a conditioning pulse (I1) facilitates the subsequent pulse (I2) via calmodulin/calmodulin kinase II (CaMKII) mechanisms. The negative feedback model proposes that the calcium release of each pulse feeds back on itself via calcium-dependent inactivation. The relative physiological roles were evaluated in rat ventricular myocytes. Paired pulses (450 ms interpulse interval) elicited facilitation (I2 of 872 +/- 145 versus I1 of 777 +/- 132 pA, P < 0.01). Inactivation time (T0.37) was prolonged for I2 versus I1 (22 +/- 2 and 16 +/- 2 ms, P > 0.01). Evidence for the negative feedback mechanism includes: (a) ryanodine (0.3 mM ) eliminated facilitation, surprisingly by increasing the amplitude of I1 more than that of I2 (1039 +/- 216 and 977 +/- 186 pA) and eliminated the difference in T0.37 between I2 and I1 (33.1 +/- 4.5 versus 32.5 +/- 4.6 ms); (b) an outward I2, which does not trigger sarcoplasmic reticulum (SR) Ca2+ release, eliminated facilitation even when it was conditioned by an inward I1; (c) facilitation decayed as the I1-I2 interval lengthened (time constant (tau) = 16.9 +/- 1.4 s); (d) thapsigargin (0.1 microM ) slowed this decay (tau = 43.8 +/- 11.7 s) whereas isoproterenol accelerated it (tau = 5.6 +/- 1.4 s, P < 0.01) and T0.37 paralleled this decay; and (e) the magnitude of ICa-L was negatively correlated with the sodium-calcium exchange current (INa/Ca) elicited by the SR-Ca2+ release. In conclusion, Ca2+-dependent inactivation of ICa-L is the major mechanism underlying facilitation.

Mechanisms causing plateau potentials in spinal motoneurones

Plateau potentials are generated by a voltage sensitive persistent inward current. In spinal motoneurones this current is predominantly mediated by influx of Ca2+ through L-type Ca2+ channels of the Ca(v)1.3 subtype. Depolarisation-induced facilitation of L-type Ca2+ channels is thought to be the mechanism for delayed activation (wind-up and warm-up) of the plateau potential and for the hysteresis in firing frequency and I-V relation during triangular depolarisation. L-type Ca2+ channels and plateau potentials in spinal motoneurones are facilitated by activation of metabotropic receptors for glutamate, acetylcholine, noradrenaline and serotonin and down regulated by activation of GABA(B) receptors. The facilitation has been shown to depend on activated calmodulin.

Down-regulation of voltage-gated Ca2+ channels by neuronal calcium sensor-1 is beta subunit-specific

Neuronal Ca(2+) sensor protein-1 (NCS-1) is a member of the Ca(2+) binding protein family, with three functional Ca(2+) binding EF-hands and an N-terminal myristoylation site. NCS-1 is expressed in brain and heart during embryonic and postnatal development. In neurons, NCS-1 facilitates neurotransmitter release, but both inhibition and facilitation of the Ca(2+) current amplitude have been reported. In heart, NCS-1 co-immunoprecipitates with K(+) channels and modulates their activity, but the potential effects of NCS-1 on cardiac Ca(2+) channels have not been investigated. To directly assess the effect of NCS-1 on the various types of Ca(2+) channels we have co-expressed NCS-1 in Xenopus oocytes, with Ca(V)1.2, Ca(V)2.1, and Ca(V)2.2 Ca(2+) channels, using various subunit combinations. The major effect of NCS-1 was to decrease Ca(2+) current amplitude, recorded with the three different types of alpha(1) subunit. When expressed with Ca(V)2.1, the depression of Ca(2+) current amplitude induced by NCS-1 was dependent upon the identity of the beta subunit expressed, with no block recorded without beta subunit or with the beta(3) subunit. Current-voltage and inactivation curves were also slightly modified and displayed a different specificity toward the beta subunits. Taken together, these data suggest that NCS-1 is able to modulate cardiac and neuronal voltage-gated Ca(2+) channels in a beta subunit specific manner.

Differential transcriptional expression of Ca2+ BP superfamilies in murine gastrointestinal smooth muscles

Calmodulin (Cal) plays important roles for contractile activity in smooth muscles. Recently, two distinct Ca(2+)-binding protein superfamilies with sequence similarities to Cal have been identified in neuronal cells: neuronal Ca(2+)-binding proteins (NCBPs) and Cal-like Ca(2+)-binding proteins (CaBPs). Some NCBPs and CaBPs play significant roles for Ca(2+)-dependent cellular signaling in the nervous system. In gastrointestinal smooth muscles (GISMs), Cal functions as the regulator of contractile behavior and electrical rhythmicity. However, the molecular identification of NCBPs and CaBPs has not been elucidated in GISMs. Here, we have identified NCBPs and CaBPs expressed in GISMs and determined the expression levels of their transcripts by quantitative RT-PCR. Of 12 NCBPs, the transcripts for neuronal Ca(2+) sensor 1, neural visinin-like proteins 1, 2, and 3, and K(+) channel-interacting proteins 1 and 3 were detected in proximal colon, gastric fundus, gastric antrum, and jejunum. On the other hand, of seven CaBPs including alternatively spliced variants, only CaBP1L transcripts were detected in GISMs.

Spinal plasticity mediated by postsynaptic L-type Ca2+ channels

In the spinal cord, motoneurons and specific subgroups of interneurons express L-type Ca(2+) channels. As elsewhere, these dihydropyridine-sensitive channels mediate a slowly activating inward current in response to depolarisation and show little or no inactivation. The slow kinetics for activation and deactivation provide voltage-sensitive properties in a time range from hundreds of milliseconds to tens of seconds and lead to plateau potentials, bistability and wind-up in neurons in both sensory and motor networks. This slow dynamics is in part due to facilitation of L-type Ca(2+) channels by depolarisation. The voltage sensitivity of L-type Ca(2+) channels is also regulated by a range of metabotropic transmitter receptors. Up-regulation is mediated by receptors for glutamate, acetylcholine, noradrenaline and serotonin in motoneurons and by receptors for glutamate and substance P in plateau-generating dorsal horn interneurons. In both cell types, L-type Ca(2+) channels are down-regulated by activation of GABA(B) receptors. In this way, metabotropic regulation in cells expressing L-type Ca(2+) channels provides mechanisms for flexible adjustment of excitability and of the contribution of plateau currents to the intrinsic properties. This type of regulation also steers the magnitude and compartmental distribution of Ca(2+) influx during depolarisation, thus providing a signal for local synaptic plasticity.

Mechanisms underlying the frequency dependence of contraction and [Ca(2+)](i) transients in mouse ventricular myocytes

In most mammalian species force of contraction of cardiac muscle increases with increasing rate of stimulation, i.e. a positive force-frequency relationship. In single mouse ventricular cells, both positive and negative relationships have been described and little is known about the underlying mechanisms. We studied enzymatically isolated single ventricular mouse myocytes, at 30 degrees C. During field stimulation, amplitude of unloaded cell shortening increased with increasing frequency of stimulation (0.04 +/- 0.01 Delta L/L(0) at 1 Hz to 0.07 +/- 0.01 Delta L/L(0) at 4 Hz, n = 12, P < 0.05). During whole cell voltage clamp with 50 microM [K5-fluo-3](pip), both peak and baseline [Ca(2+)](i) increased at higher stimulation frequencies, but the net Delta[Ca(2+)](i) increased only modestly from 1.59 +/- 0.08 Delta F/F(0) at 1 Hz, to 1.71 +/- 0.11 Delta F/F(0) at 4 Hz (n = 17, P < 0.05). When a 1 s pause was interposed during stimulation at 2 and 4 Hz, [Ca(2+)](i) transients were significantly larger (at 4 Hz, peak F/F(0) increased by 78 +/- 2 %, n = 5). SR Ca(2+) content assessed during caffeine application, significantly increased from 91 +/- 24 micromol l(-1) at 1 Hz to 173 +/- 20 micromol l(-1) at 4 Hz (n = 5, P < 0.05). Peak I(Ca,L) decreased at higher frequencies (by 28 +/- 6 % at 2 Hz, and 45 +/- 8 % at 4 Hz), due to slow recovery from inactivation. This loss of I(Ca,L) resulted in reduced fractional release. Thus, in mouse ventricular myocytes the [Ca(2+)](i)-frequency response depends on a balance between the increase in SR content and the loss of trigger I(Ca,L). Small changes in this balance may contribute to variability in frequency-dependent behaviour. In addition, there may be a regulation of the contractile response downstream of [Ca(2+)](i).

Fast and slow inactivation kinetics of the Ca2+ channels ECaC1 and ECaC2 (TRPV5 and TRPV6). Role of the intracellular loop located between transmembrane segments 2 and 3

The Ca(2+) channels ECaC1 and ECaC2 (TRPV5 and TRPV6) share several functional properties including permeation profile and Ca(2+)-dependent inactivation. However, the kinetics of ECaC2 currents notably differ from ECaC1 currents. The initial inactivation is much faster in ECaC2 than in ECaC1, and the kinetic differences between Ca(2+) and Ba(2+) currents are more pronounced for ECaC2 than ECaC1. Here, we identify the structural determinants for these functional differences. Chimeric proteins were expressed heterologously in HEK 293 cells and studied by patch clamp analysis. Both channels retained their phenotype after exchanging the complete N termini, the C termini, or even both N and C termini, i.e. ECaC1 with the ECaC2 N or C terminus still showed the ECaC1 phenotype and vice versa. The substitution of the intracellular loop between the transmembrane domains 2 and 3 of ECaC2 with that of ECaC1 induced a delay of inactivation. Three amino acid residues (Leu-409, Val-411 and Thr-412) present in this loop determine the fast inactivation behavior. When this intracellular loop between the transmembrane domains 2 and 3 of ECaC1 was exchanged with the TM2-TM3 loop of ECaC2, the ECaC1 kinetics were analogous to ECaC2. In conclusion, the TM2-TM3 loop is a critical determinant of the inactivation in ECaC1 and ECaC2.

Calcium, calmodulin, and calcium-calmodulin kinase II: heartbeat to heartbeat and beyond

Calcium (Ca) is the key regulator of cardiac contraction during excitation-contraction (E-C) coupling. However, differences exist between the amount of Ca being transported into the myocytes upon electrical stimulation as compared to Ca released from the sarcoplasmic reticulum (SR). Moreover, alterations in E-C coupling occur in cardiac hypertrophy and heart failure. In addition to the direct effects of Ca on the myofilaments, Ca plays a pivotal role in activation of a number of Ca-dependent proteins or second messengers, which can modulate E-C coupling. Of these proteins, calmodulin (CaM) and Ca-CaM-dependent kinase II (CaMKII) are of special interest in the heart because of their role of modulating Ca influx, SR Ca release, and SR Ca uptake during E-C coupling. Indeed, CaM and CaMKII may be associated with some ion channels and Ca transporters and both can modulate acute cellular Ca handling. In addition to the changes in Ca, CaM and CaMKII signals from beat-to-beat, changes may occur on a longer time scale. These may occur over seconds to minutes involving phosphorylation/dephosphorylation reactions, and even a longer time frame in altering gene transcription (excitation-transcription (E-T) coupling) in hypertrophic signaling and heart failure. Here we review the classical role of Ca in E-C coupling and extend this view to the role of the Ca-dependent proteins CaM and CaMKII in modulating E-C coupling and their contribution to E-T coupling.

Localization and function of a calmodulin-apocalmodulin-binding domain in the N-terminal part of the type 1 inositol 1,4,5-trisphosphate receptor

Calmodulin (CaM) is a ubiquitous protein that plays a critical role in regulating cellular functions by altering the activity of a large number of proteins, including the d-myo-inositol 1,4,5-trisphosphate (IP3) receptor (IP3R). CaM inhibits IP3 binding in both the presence and absence of Ca2+ and IP3-induced Ca2+ release in the presence of Ca2+. We have now mapped and characterized a Ca2+-independent CaM-binding site in the N-terminal part of the type 1 IP3R (IP3R1). This site could be responsible for the inhibitory effects of CaM on IP3 binding. We therefore expressed the N-terminal 581 amino acids of IP3R1 as a His-tagged recombinant protein, containing the functional IP3-binding pocket. We showed that CaM, both in the presence and absence of Ca2+, inhibited IP3 binding to this recombinant protein with an IC50 of approx. 2 microM. Deletion of the N-terminal 225 amino acids completely abolished the effects of both Ca2+ and CaM on IP3 binding. We mapped the Ca2+-independent CaM-binding site to a recombinant glutathione S-transferase fusion protein containing the first 159 amino acids of IP3R1 and then made different synthetic peptides overlapping this region. We demonstrated that two synthetic peptides matching amino acids 49-81 and 106-128 bound CaM independently of Ca2+ and could reverse the inhibition of IP3 binding caused by CaM. This suggests that these sequences are components of a discontinuous Ca2+-independent CaM-binding domain, which is probably involved in the inhibition of IP3 binding by CaM.

The cannabinoid agonist DALN positively modulates L-type voltage-dependent calcium-channels in N18TG2 neuroblastoma cells

The present study demonstrates a novel stimulatory effect of a cannabinoid agonist on calcium channels. DALN (1 nM) potentiated 45Ca(2+)-uptake by N18TG2 neuroblastoma cells, an effect that was abolished by the specific CB1 receptor antagonist SR141716A. The stimulation of 45Ca(2+)-uptake by DALN was resistant to pertussis toxin (PTX), suggesting that Gi/Go GTP-binding proteins did not mediate this effect. Furthermore, PTX unmasked a stimulatory effect of a high concentration of DALN (1 microM), which by itself failed to stimulate calcium uptake in naive cells. The stimulatory effect of DALN on calcium entry to the cells was blocked by nicardipine but not by omega-conotoxin GVIA, indicating the entry of calcium through L-type voltage-dependent calcium channels. Blocking cAMP-dependent protein kinase (PKA) by H-89 completely eliminated the elevation in calcium uptake, while blocking protein kinase C (PKC) by chelerythrine and calphostine-C only partially attenuated the stimulation. Blocking calmodulin by W-7 revealed a similar partial inhibition of the stimulatory effect of DALN. Hence, we suggest a cannabinoid-specific, PTX-insensitive, stimulatory effect on L-type voltage-dependent calcium channels, which is mediated by PKA and modulated by PKC and calmodulin.

Functional Roles of Ca(v)1.3 (alpha(1D)) calcium channel in sinoatrial nodes: insight gained using gene-targeted null mutant mice

We directly examined the role of the Ca(v)1.3 (alpha(1D)) Ca(2+) channel in the sinoatrial (SA) node by using Ca(v)1.3 Ca(2+) channel-deficient mice. A previous report has shown that the null mutant (Ca(v)1.3(-/-)) mice have sinus bradycardia with a prolonged PR interval. In the present study, we show that spontaneous action potentials recorded from the SA nodes show a significant decrease in the beating frequency and rate of diastolic depolarization in Ca(v)1.3(-/-) mice compared with their heterozygous (Ca(v)1.3(+/-)) or wild-type (WT, Ca(v)1.3(+/+)) littermates, suggesting that the deficit is intrinsic to the SA node. Whole-cell L-type Ca(2+) currents (I(Ca,L)s) recorded in single isolated SA node cells from Ca(v)1.3(-/-) mice show a significant depolarization shift in the activation threshold. The voltage-dependent activation of Ca(v)1.2 (alpha(1C)) versus Ca(v)1.3 Ca(2+) channel subunits was directly compared by using a heterologous expression system without beta coexpression. Similar to the I(Ca,L) recorded in the SA node of Ca(v)1.3(-/-) mutant mice, the Ca(v)1.2 Ca(2+) channel shows a depolarization shift in the voltage-dependent activation compared with that in the Ca(v)1.3 Ca(2+) channel. In summary, using gene-targeted deletion of the Ca(v)1.3 Ca(2+) channel, we were able to establish a role for Ca(v)1.3 Ca(2+) channels in the generation of the spontaneous action potential in SA node cells.

Calmodulin as an ion channel subunit

A surprising variety of ion channels found in a wide range of species from Homo to Paramecium use calmodulin (CaM) as their constitutive or dissociable Ca(2+)-sensing subunits. The list includes voltage-gated Ca(2+) channels, various Ca(2+)- or ligand-gated channels, Trp family channels, and even the Ca(2+)-induced Ca(2+) release channels from organelles. Our understanding of CaM chemistry and its relation to enzymes has been instructive in channel research, yet the intense study of CaM regulation of ion channels has also revealed unexpected CaM chemistry. The findings on CaM channel interactions have indicated the existence of secondary interaction sites in addition to the primary CaM-binding peptides and the functional differences between the N- and C-lobes of CaM. The study of CaM in channel biology will figure into our understanding on how this uniform, universal, vital, and ubiquitous Ca(2+) decoder coordinates the myriad local and global cell physiological transients.

Stimulation of recombinant Ca(v)3.2, T-type, Ca(2+) channel currents by CaMKIIgamma(C)

Molecular cloning of low-voltage activated (LVA) T-type calcium channels has enabled the study of their regulation in heterologous expression systems. Here we investigate the regulation of Ca(v)3.2 alpha(1)-subunits (alpha1H) by calcium- and/or calmodulin-dependent protein kinase II (CaMKII). 293 cells stably expressing alpha1H were transiently transfected with CaMKIIgamma(C). Using the whole-cell recording configuration, we observed that elevation of pipette free Ca(2+) (1 microM) in the presence of CaM (2 microM) increases T-type channel activity selectively at negative potentials, evoking an 11 mV hyperpolarizing shift in the half-maximal potential (V(1/2)) for activation. The V(1/2) of channel inactivation is not altered by Ca(2+)/CaM. These effects reproduced modulation observed in adrenal zona glomerulosa cells. The potentiation by Ca(2+)/CaM was dependent on the co-expression of CaMKIIgamma(C) and required Ca(2+)/CaM-dependent kinase activity. Peptide (AIP) and lipophilic (KN-62) protein kinase inhibitors prevented the Ca(2+)/CaM-induced changes in channel gating without altering basal Ca(v)3.2 channel activity (27 nM free Ca(2+)) as did replacing pipette ATP with adenylyl imidodiphosphate (AMP-PNP), a non-hydrolysable analogue. CaMKII-dependent potentiation of channel opening resulted in significant increases in apparent steady-state open probability (P(o)) and sustained channel current at negative voltages. Under identical conditions, CaMKII activation did not regulate the activity of Ca(v)3.1 channels, the first cloned member (alpha1G) of the T-type Ca(2+) channel family. Our results provide the first evidence for the differential regulation of two members of the Ca(v)3 family by protein kinase activation and the first report reconstituting CaMKII-dependent regulation of any cloned Ca(2+) channel.

Regulation of cardiac and smooth muscle Ca(2+) channels (Ca(V)1.2a,b) by protein kinases

High voltage-activated Ca(2+) channels of the Ca(V)1.2 class (L-type) are crucial for excitation-contraction coupling in both cardiac and smooth muscle. These channels are regulated by a variety of second messenger pathways that ultimately serve to modulate the level of contractile force in the tissue. The specific focus of this review is on the most recent advances in our understanding of how cardiac Ca(V)1.2a and smooth muscle Ca(V)1.2b channels are regulated by different kinases, including cGMP-dependent protein kinase, cAMP-dependent protein kinase, and protein kinase C. This review also discusses recent evidence regarding the regulation of these channels by protein tyrosine kinase, calmodulin-dependent kinase, purified G protein subunits, and identification of possible amino acid residues of the channel responsible for kinase regulation.

Potentiation of the cardiac L-type Ca(2+) channel (alpha(1C)) by dihydropyridine agonist and strong depolarization occur via distinct mechanisms

A defining property of L-type Ca(2+) channels is their potentiation by both 1,4-dihydropyridine agonists and strong depolarization. In contrast, non-L-type channels are potentiated by neither agonist nor depolarization, suggesting that these two processes may by linked. In this study, we have tested whether the mechanisms of agonist- and depolarization-induced potentiation in the cardiac L-type channel (alpha(1C)) are linked. We found that the mutant L-type channel GFP-alpha(1C)(TQ-->YM), bearing the mutations T1066Y and Q1070M, was able to undergo depolarization-induced potentiation but not potentiation by agonist. Conversely, the chimeric channel GFP-CACC was potentiated by agonist but not by strong depolarization. These data indicate that the mechanisms of agonist- and depolarization-induced potentiation of alpha(1C) are distinct. Since neither GFP-CACC nor GFP-CCAA was potentiated significantly by depolarization, no single repeat of alpha(1C) appears to be responsible for depolarization-induced potentiation. Surprisingly, GFP-CACC displayed a low estimated open probability similar to that of the alpha(1C), but could not support depolarization-induced potentiation, demonstrating that a relatively low open probability alone is not sufficient for depolarization-induced potentiation to occur. Thus, depolarization-induced potentiation may be a global channel property requiring participation from all four homologous repeats.

The function of Ca(2+) channel subtypes in exocytotic secretion: new perspectives from synaptic and non-synaptic release

By mediating the Ca(2+) influx that triggers exocytotic fusion, Ca(2+) channels play a central role in a wide range of secretory processes. Ca(2+) channels consist of a complex of protein subunits, including an alpha(1) subunit that constitutes the voltage-dependent Ca(2+)-selective membrane pore, and a group of auxiliary subunits, including beta, gamma, and alpha(2)-delta subunits, which modulate channel properties such as inactivation and channel targeting. Subtypes of Ca(2+) channels are constituted by different combinations of alpha(1) subunits (of which 10 have been identified) and auxiliary subunits, particularly beta (of which 4 have been identified). Activity-secretion coupling is determined not only by the biophysical properties of the channels involved, but also by the relationship between channels and the exocytotic apparatus, which may differ between fast and slow types of secretion. Colocalization of Ca(2+) channels at sites of fast release may depend on biochemical interactions between channels and exocytotic proteins. The aim of this article is to review recent work on Ca(2+) channel structure and function in exocytotic secretion. We discuss Ca(2+) channel involvement in selected types of secretion, including central neurotransmission, endocrine and neuroendocrine secretion, and transmission at graded potential synapses. Several different Ca(2+) channel subtypes are involved in these types of secretion, and their function is likely to involve a variety of relationships with the exocytotic apparatus. Elucidating the relationship between Ca(2+) channel structure and function is central to our understanding of the fundamental process of exocytotic secretion.

Signaling to the nucleus by an L-type calcium channel-calmodulin complex through the MAP kinase pathway

Increases in the intracellular concentration of calcium ([Ca2+]i) activate various signaling pathways that lead to the expression of genes that are essential for dendritic development, neuronal survival, and synaptic plasticity. The mode of Ca2+ entry into a neuron plays a key role in determining which signaling pathways are activated and thus specifies the cellular response to Ca2+. Ca2+ influx through L-type voltage-activated channels (LTCs) is particularly effective at activating transcription factors such as CREB and MEF-2. We developed a functional knock-in technique to investigate the features of LTCs that specifically couple them to the signaling pathways that regulate gene expression. We found that an isoleucine-glutamine ("IQ") motif in the carboxyl terminus of the LTC that binds Ca2+-calmodulin (CaM) is critical for conveying the Ca2+ signal to the nucleus. Ca2+-CaM binding to the LTC was necessary for activation of the Ras/mitogen-activated protein kinase (MAPK) pathway, which conveys local Ca2+ signals from the mouth of the LTC to the nucleus. CaM functions as a local Ca2+ sensor at the mouth of the LTC that activates the MAPK pathway and leads to the stimulation of genes that are essential for neuronal survival and plasticity.

Calmodulin kinase and a calmodulin-binding 'IQ' domain facilitate L-type Ca2+ current in rabbit ventricular myocytes by a common mechanism

1. Ca2+-calmodulin-dependent protein kinase II (CaMK) and a calmodulin (CaM)-binding 'IQ' domain (IQ) are both implicated in Ca2+-dependent regulation of L-type Ca2+ current (I(Ca)). We used an IQ-mimetic peptide (IQmp), under conditions in which CaMK activity was controlled, to test the relationship between these CaM-activated signalling elements in the regulation of L-type Ca2+ channels (LTCCs) and I(Ca) in rabbit ventricular myocytes. 2. A specific CaMK inhibitory peptide nearly abolished I(Ca) facilitation, but the facilitation was 'rescued' by cell dialysis with IQmp. 3. IQmp significantly enhanced I(Ca) facilitation and slowed the fast component of I(Ca) inactivation, compared with an inactive control peptide. Neither effect could be elicited by a more avid CaM-binding peptide, suggesting that generalized CaM buffering did not account for the effects of IQmp. 4. I(Ca) facilitation was abolished and the fast component of inactivation eliminated by ryanodine, caffeine or thapsigargin, suggesting that the sarcoplasmic reticulum (SR) is an important source of Ca2+ for I(Ca) facilitation and inactivation. IQmp did not restore I(Ca) facilitation under these conditions. 5. Engineered Ca2+-independent CaMK and IQmp each markedly increased LTCC open probability (P(o)) in excised cell membrane patches. The LTCC P(o) increases with CaMK and IQmp were non-additive, suggesting that CaMK and IQmp are components of a shared signalling pathway. 6. Both CaMK and IQmp induced a modal gating shift in LTCCs that favoured prolonged openings, indicating that CaMK and IQmp affect LTCCs through a common biophysical mechanism. 7. These findings support the hypothesis that CaMK is required for physiological I(Ca) facilitation in cardiac myocytes. Both CaMK and IQmp were able to induce a modal gating shift in LTCCs, suggesting that each of these signalling elements is important for Ca2+-CaM-dependent LTCC facilitation in cardiac myocytes.

Molecular basis of calmodulin tethering and Ca2+-dependent inactivation of L-type Ca2+ channels

Ca(2+)-dependent inactivation (CDI) of L-type Ca(2+) channels plays a critical role in controlling Ca(2+) entry and downstream signal transduction in excitable cells. Ca(2+)-insensitive forms of calmodulin (CaM) act as dominant negatives to prevent CDI, suggesting that CaM acts as a resident Ca(2+) sensor. However, it is not known how the Ca(2+) sensor is constitutively tethered. We have found that the tethering of Ca(2+)-insensitive CaM was localized to the C-terminal tail of alpha(1C), close to the CDI effector motif, and that it depended on nanomolar Ca(2+) concentrations, likely attained in quiescent cells. Two stretches of amino acids were found to support the tethering and to contain putative CaM-binding sequences close to or overlapping residues previously shown to affect CDI and Ca(2+)-independent inactivation. Synthetic peptides containing these sequences displayed differences in CaM-binding properties, both in affinity and Ca(2+) dependence, leading us to propose a novel mechanism for CDI. In contrast to a traditional disinhibitory scenario, we suggest that apoCaM is tethered at two sites and signals actively to slow inactivation. When the C-terminal lobe of CaM binds to the nearby CaM effector sequence (IQ motif), the braking effect is relieved, and CDI is accelerated.

Interactions of calmodulin with two peptides derived from the c-terminal cytoplasmic domain of the Ca(v)1.2 Ca2+ channel provide evidence for a molecular switch involved in Ca2+-induced inactivation

When opened by depolarization, L-type calcium channels are rapidly inactivated by the elevation of Ca(2+) concentration on the cytoplasmic side. Recent studies have shown that the interaction of calmodulin with the proximal part of the cytoplasmic C-terminal tail of the channel plays a prominent role in this modulation. Two motifs interacting with calmodulin in a Ca(2+)-dependent manner have been described: the IQ sequence and more recently the neighboring CB sequence. Here, using synthetic peptides and fusion proteins derived from the Ca(v)1.2 channel combined with biochemical techniques, we show that these two peptides are the only motifs of the cytoplasmic tail susceptible to interact with calmodulin. We determined the K(d) of the CB interaction with calmodulin to be 12 nm, i.e. below the K(d) of IQ-calmodulin, thereby precluding a competitive displacement of CB by IQ in the presence of Ca(2+). In place, we demonstrated that a ternary complex is formed at high Ca(2+) concentration, provided that calmodulin and the peptides are initially allowed to interact at a low Ca(2+) concentration. These results provide evidence that CB and IQ motifs interacting together with calmodulin constitute a minimal molecular switch leading to Ca(2+)-induced inactivation. In addition, we suggest that they could also be the tethering site of calmodulin.

Calmodulin bifurcates the local Ca2+ signal that modulates P/Q-type Ca2+ channels

Acute modulation of P/Q-type (alpha1A) calcium channels by neuronal activity-dependent changes in intracellular Ca2+ concentration may contribute to short-term synaptic plasticity, potentially enriching the neurocomputational capabilities of the brain. An unconventional mechanism for such channel modulation has been proposed in which calmodulin (CaM) may exert two opposing effects on individual channels, initially promoting ('facilitation') and then inhibiting ('inactivation') channel opening. Here we report that such dual regulation arises from surprising Ca2+-transduction capabilities of CaM. First, although facilitation and inactivation are two competing processes, both require Ca2+-CaM binding to a single 'IQ-like' domain on the carboxy tail of alpha1A; a previously identified 'CBD' CaM-binding site has no detectable role. Second, expression of a CaM mutant with impairment of all four of its Ca2+-binding sites (CaM1234) eliminates both forms of modulation. This result confirms that CaM is the Ca2+ sensor for channel regulation, and indicates that CaM may associate with the channel even before local Ca2+ concentration rises. Finally, the bifunctional capability of CaM arises from bifurcation of Ca2+ signalling by the lobes of CaM: Ca2+ binding to the amino-terminal lobe selectively initiates channel inactivation, whereas Ca2+ sensing by the carboxy-terminal lobe induces facilitation. Such lobe-specific detection provides a compact means to decode local Ca2+ signals in two ways, and to separately initiate distinct actions on a single molecular complex.

Ca2+-dependent regulation of cardiac L-type Ca2+ channels: is a unifying mechanism at hand?

Ca2+ entry (I(Ca)) through cardiac L-type Ca2+ channels (LTCC) drives critical cellular processes ranging from contraction to gene expression, and, when disordered, is implicated in arrhythmias and hypertrophy. LTCC activation occurs by cell membrane depolarization, but LTCCs are also regulated by auxiliary proteins, phosphorylation, and intracellular CA2+([Ca2+]i). LTCC regulation by [Ca2+]i is especially intriguing because increased [Ca2+]i signals dual and conflicting commands for I(Ca)inactivation and facilitation. A recent explosion of work has shed new light on the mechanisms and molecular identity of domains necessary for [Ca2+]i-dependent regulation of LTCC.

Determinants for calmodulin binding on voltage-dependent Ca2+ channels

Calmodulin, bound to the alpha(1) subunit of the cardiac L-type calcium channel, is required for calcium-dependent inactivation of this channel. Several laboratories have suggested that the site of interaction of calmodulin with the channel is an IQ-like motif in the carboxyl-terminal region of the alpha(1) subunit. Mutations in this IQ motif are linked to L-type Ca(2+) current (I(Ca)) facilitation and inactivation. IQ peptides from L, P/Q, N, and R channels all bind Ca(2+)calmodulin but not Ca(2+)-free calmodulin. Another peptide representing a carboxyl-terminal sequence found only in L-type channels (designated the CB domain) binds Ca(2+)calmodulin and enhances Ca(2+)-dependent I(Ca) facilitation in cardiac myocytes, suggesting the CB domain is functionally important. Calmodulin blocks the binding of an antibody specific for the CB sequence to the skeletal muscle L-type Ca(2+) channel, suggesting that this is a calmodulin binding site on the intact protein. The binding of the IQ and CB peptides to calmodulin appears to be competitive, signifying that the two sequences represent either independent or alternative binding sites for calmodulin rather than both sequences contributing to a single binding site.

P2Y-purinoceptor mediated inhibition of L-type Ca2+ channels in rat pancreatic beta-cells

We used the patch-clamp technique to study the effects of extracellular ATP on the activity of ion channels recorded in rat pancreatic beta-cells. In cell-attached membrane patches, action currents induced by 8.3 mM glucose were inhibited by 0.1 mM ATP, 0.1 mM ADP or 15 microM ADPbetaS but not by 0.1 mM AMP or 0.1 mM adenosine. In perforated membrane patches, action potentials were measured in current clamp, induced by 8.3 mM glucose, and were also inhibited by 0.1 mM ATP with a modest hyperpolarization to -43 mV. In whole-cell clamp experiments, ATP dose-dependently decreased the amplitudes of L-type Ca2+ channel currents (ICa) to 56.7+/-4.0% (p<0.001) of the control, but did not influence ATP-sensitive K+ channel currents observed in the presence of 0.1 mM ATP and 0.1 mM ADP in the pipette. Agonists of P2Y purinoceptors, 2-methylthio ATP (0.1 mM) or ADPbetaS (15 microM) mimicked the inhibitory effect of ATP on ICa, but PPADS (0.1 mM) and suramin (0.2 mM), antagonists of P2 purinoceptors, counteracted this effect. When we used 0.1 mM GTPgammaS in the pipette solution, ATP irreversibly reduced ICa to 58.4+/-6.6% of the control (p<0.001). In contrast, no inhibitory effect of ATP was observed when 0.2 mM GDPbetaS was used in the pipette solution. The use of either 20 mM BAPTA instead of 10 mM EGTA, or 0.1 mM compound 48/80, a blocker of phospholipase C (PLC), in the pipette solution abolished the inhibitory effect of ATP on ICa, but 1 microM staurosporine, a blocker of protein kinase C (PKC), did not. When the beta-cells were pretreated with 0.4 microM thapsigargin, an inhibitor of the endoplasmic reticulum (ER) Ca2+ pump, ATP lost the inhibitory effect on ICa. These results suggest that extracellular ATP inhibits action potentials by Ca2+-induced ICa inhibition in which an increase in cytosolic Ca2+ released from thapsigargin-sensitive store sites was brought about by a P2Y purinoceptor-coupled G-protein, PI-PLC and IP3 pathway.