Ca2+-Activated Cl? Channels of the ClCa Family Express in the Cilia of a Subset of Rat Olfactory Sensory Neurons

The Ca²⁺-activated Cl⁻ channel is considered a key constituent of odor transduction. Odorant binding to a specific receptor in the cilia of olfactory sensory neurons (OSNs) triggers a cAMP cascade that mediates the opening of a cationic cyclic nucleotide-gated channel (CNG), allowing Ca²⁺ influx. Ca²⁺ ions activate Cl⁻ channels, generating a significant Cl⁻ efflux, with a large contribution to the receptor potential. The Anoctamin 2 channel (ANO2) is a major constituent of the Cl⁻ conductance, but its knock-out has no impairment of behavior and only slightly reduces field potential odorant responses of the olfactory epithelium. Likely, an additional Ca²⁺-activated Cl⁻ channel of unknown molecular identity is also involved. In addition to ANO2, we detected two members of the ClCa family of Ca²⁺-activated Cl⁻ channels in the rat olfactory epithelium, ClCa4l and ClCa2. These channels, also expressed in the central nervous system, may correspond to odorant transduction channels. Whole Sprague Dawley olfactory epithelium nested RT-PCR and single OSNs established that the mRNAs of both channels are expressed in OSNs. Real time RT-PCR and full length sequencing of amplified ClCa expressed in rat olfactory epithelium indicated that ClCa4l is the most abundant. Immunoblotting with an antibody recognizing both channels revealed immunoreactivity in the ciliary membrane. Immunochemistry of olfactory epithelium and OSNs confirmed their ciliary presence in a subset of olfactory sensory neurons. The evidence suggests that ClCa4l and ClCa2 might play a role in odorant transduction in rat olfactory cilia.     

Ca2+-dependent Inactivation of CaV1.2 Channels Prevents Gd3+ Block: Does Ca2+ Block the Pore of Inactivated Channels?

Lanthanide gadolinium (Gd(3+)) blocks Ca(V)1.2 channels at the selectivity filter. Here we investigated whether Gd(3+) block interferes with Ca(2+)-dependent inactivation, which requires Ca(2+) entry through the same site. Using brief pulses to 200 mV that relieve Gd(3+) block but not inactivation, we monitored how the proportions of open and open-blocked channels change during inactivation. We found that blocked channels inactivate much less. This is expected for Gd(3+) block of the Ca(2+) influx that enhances inactivation. However, we also found that the extent of Gd(3+) block did not change when inactivation was reduced by abolition of Ca(2+)/calmodulin interaction, showing that Gd(3+) does not block the inactivated channel. Thus, Gd(3+) block and inactivation are mutually exclusive, suggesting action at a common site. These observations suggest that inactivation causes a change at the selectivity filter that either hides the Gd(3+) site or reduces its affinity, or that Ca(2+) occupies the binding site at the selectivity filter in inactivated channels. The latter possibility is supported by previous findings that the EEQE mutation of the selectivity EEEE locus is void of Ca(2+)-dependent inactivation (Zong Z.Q., J.Y. Zhou, and T. Tanabe. 1994. Biochem. Biophys. Res. Commun. 201:1117-11123), and that Ca(2+)-inactivated channels conduct Na(+) when Ca(2+) is removed from the extracellular medium (Babich O., D. Isaev, and R. Shirokov. 2005. J. Physiol. 565:709-717). Based on these results, we propose that inactivation increases affinity of the selectivity filter for Ca(2+) so that Ca(2+) ion blocks the pore. A minimal model, in which the inactivation "gate" is an increase in affinity of the selectivity filter for permeating ions, successfully simulates the characteristic U-shaped voltage dependence of inactivation in Ca(2+).     

Characterization of the Driving Force as a Modulator of Gating in Cardiac ATP-sensitive K+ Channels — Evidence for Specific Elementary Properties

Single cardiac ATP-sensitive K⁺ channels and, comparatively, two other members of the inwardly rectifying K⁺ channel family, cardiac K⁺ _(ir) and K⁺ _(ACh) channels, were studied in the inside-out recording mode in order to analyze influence and significance of the electrochemical K⁺ gradient for open-state kinetics of these K⁺ channels. The conductive state of K⁺ _(ATP) channels was defined as a function of the electrochemical K⁺ gradient in that increased driving force correlates with shortened open-channel lifetime. Flux coupling of gating can be largely excluded as the underlying mechanism for two reasons: (i) τ_open proved identical in 23 pS, 56 pS and 80 pS channels; (ii) K⁺ _(ATP) channel protonation by an external pH shift from 9.5 to 5.5 reduced conductance without a concomitant detectable change of τ_open. Since gating continued to operate at E _K , i.e., in the absence of K⁺ permeation through the pore, K⁺ driving force cannot be causally involved in gating. Rather the driving force acts to modulate the gating process similar to Rb⁺ whose interference with an externally located binding site stabilizes the open state. In K⁺ _(ir) and K⁺ _(ACh) channels, the open state is essentially independent on driving force meaning that their gating apparatus does not sense the electrochemical K⁺ gradient. Thus, K⁺ _(ATP) channels differ in an important functional aspect which may be tentatively explained by a structural peculiarity of their gating apparatus. Received: 24 March 1997/Revised: 24 April 1998     

Impaired Gating of an L-Type Ca2+ Channel Carrying a Mutation Linked to?Malignant Hyperthermia

Recently, we characterized the functional properties of a mutant skeletal muscle L-type Ca²⁺ channel (Ca_V1.1 R174W) linked to the pharmacogenetic disorder malignant hyperthermia. Although the R174W mutation neutralizes the innermost basic amino acid in the voltage-sensing S4 helix of the first conserved membrane repeat of Ca_V1.1, the ability of the mutant channel to engage excitation-contraction coupling was largely unaffected by the introduction of the bulky tryptophan residue. In stark contrast, the mutation ablated the ability of Ca_V1.1 to produce L-type current under our standard recording conditions. In this study, we have investigated the mechanism of channel dysfunction more extensively. We found that Ca_V1.1 R174W will open and conduct Ca²⁺ in response to strong or prolonged depolarizations in the presence of the 1,4-dihydropyridine receptor agonist ±Bay K 8644. From these results, we have concluded that the R174W mutation impedes entry into both mode 1(low P_o) and mode 2 (high P_o) gating states and that these gating impairments can be partially overcome by maneuvers that promote entry into mode 2.     

Regulation of Guinea Pig Detrusor Smooth Muscle Excitability by 17β-Estradiol: The Role of the Large Conductance Voltage- and Ca2+-Activated K+ Channels

Estrogen replacement therapies have been suggested to be beneficial in alleviating symptoms of overactive bladder. However, the precise regulatory mechanisms of estrogen in urinary bladder smooth muscle (UBSM) at the cellular level remain unknown. Large conductance voltage- and Ca²⁺-activated K⁺ (BK) channels, which are key regulators of UBSM function, are suggested to be non-genomic targets of estrogens. This study provides an electrophysiological investigation into the role of UBSM BK channels as direct targets for 17β-estradiol, the principle estrogen in human circulation. Single BK channel recordings on inside-out excised membrane patches and perforated whole cell patch-clamp were applied in combination with the BK channel selective inhibitor paxilline to elucidate the mechanism of regulation of BK channel activity by 17β-estradiol in freshly-isolated guinea pig UBSM cells. 17β-Estradiol (100 nM) significantly increased the amplitude of depolarization-induced whole cell steady-state BK currents and the frequency of spontaneous transient BK currents in freshly-isolated UBSM cells. The increase in whole cell BK currents by 17β-estradiol was eliminated upon blocking BK channels with paxilline. 17β-Estradiol (100 nM) significantly increased (~3-fold) the single BK channel open probability, indicating direct 17β-estradiol-BK channel interactions. 17β-Estradiol (100 nM) caused a significant hyperpolarization of the membrane potential of UBSM cells, and this hyperpolarization was reversed by blocking the BK channels with paxilline. 17β-Estradiol (100 nM) had no effects on L-type voltage-gated Ca²⁺ channel currents recorded under perforated patch-clamp conditions. This study reveals a new regulatory mechanism in the urinary bladder whereby BK channels are directly activated by 17β-estradiol to reduce UBSM cell excitability.     

Differential Effect of High Extracellular Ca2+ on K+ and Cl− Conductances in Murine Osteoclasts

Effects of the extracellular Ca²⁺ concentration ([Ca²⁺] _o ) on whole cell membrane currents were examined in mouse osteoclastic cells generated from bone marrow/stromal cell coculture. The major resting conductance in the presence of 1 mm Ca²⁺ was mediated by a Ba²⁺-sensitive, inwardly rectifying K⁺ (IR_K) current. A rise in [Ca²⁺] _o (5–40 mm) inhibited the IR_K current and activated an 4,4′-diisothiocyano-2,2′-stilbenedisulfonate (DIDS)-sensitive, outwardly rectifying Cl⁻ (OR_Cl) current. The activation of the OR_Cl current developed slowly and needed higher [Ca²⁺] _o than that required to inhibit the IR_K current. The inhibition of the IR_K current consisted of two components, initial and subsequent late phases. The initial inhibition was not affected by intracellular application of guanosine 5′-O-(3-thiotriphosphate) (GTPγS) or guanosine 5′-O-(2-thiodiphosphate) (GDPβS). The late inhibition, however, was enhanced by GTPγS and attenuated by GDPβS, suggesting that GTP-binding proteins mediate this inhibition. The activation of the OR_Cl current was suppressed by pretreatment with pertussis toxin, but not potentiated by GTPγS. An increase in intracellular Ca²⁺ level neither reduced the IR_K current nor activated the OR_Cl current. Staurosporine, an inhibitor for protein kinase C, did not modulate the [Ca²⁺] _o -induced changes in the IR_K and OR_Cl conductances. These results suggest that high [Ca²⁺] _o had a dual action on the membrane conductance of osteoclasts, an inhibition of an IR_K conductance and an activation of an OR_Cl conductance. The two conductances modulated by [Ca²⁺] _o may be involved in different phases of bone resorption because they differed in Ca²⁺ sensitivity, temporal patterns of changes and regulatory mechanisms. Received: 28 May 1996/Revised: 28 January 1997     

Are B-type Ca2+ Channels of Cardiac Myocytes Akin to the Passive Ion Channel in the Plasma Membrane Ca2+ Pump?

The present study demonstrates that B-type Ca²⁺ channels observed in rat ventricular myocytes markedly reacted to agents known to affect the ion-motive plasma membrane Ca²⁺-ATPase (PMCA) pump. Chlorpromazine (CPZ)-activated B-type Ca²⁺ channels were completely blocked by internal application of PMCA pump inhibitors, namely La³⁺ (100 μm), eosin (10 μm) and AIF₃ (100 μm). Calmodulin (50 U/ml), the main endogenous positive regulator of PMCA, was unable to activate but significantly reduced CPZ-activated B-type channel activity. In the same manner, ATP (1 and 4 mm), the main energizing substrate of PMCA, was able to reversibly and significantly reduce this activity in a dose-dependent manner. Interestingly, anti-PMCA antibody 5F10, but not anti-Na/K ATPase antibody (used as a negative control) induced a marked Ba²⁺-conducting channel activity that shared the same characteristics with that of CPZ-activated B-type channels. 5F10-Activated channels were mostly selective towards Ba²⁺, mainly had three observed conductance levels (23, 47 and 85 pS), were observed with a frequency of about 1 out of 5 membrane patches and were completely blocked by 10 μm eosin. These results suggest that B-type Ca²⁺ channels are some form of the PMCA pump. Received: 24 July 2000/Revised: 5 October 2000     

Chloroquine Stimulates Cl? Secretion by Ca2+ Activated Cl? Channels in Rat Ileum

Chloroquine (CQ), a bitter tasting drug widely used in treatment of malaria, is associated gastrointestinal side effects including nausea or diarrhea. In the present study, we investigated the effect of CQ on electrolyte transport in rat ileum using the Ussing chamber technique. The results showed that CQ evoked an increase in short circuit current (I_SC) in rat ileum at lower concentration (≤5×10⁻⁴ M ) but induced a decrease at higher concentrations (≥10⁻³ M). These responses were not affected by tetrodotoxin (TTX). Other bitter compounds, such as denatoniumbenzoate and quinine, exhibited similar effects. CQ-evoked increase in I_SC was partly reduced by amiloride(10⁻⁴ M), a blocker of epithelial Na⁺ channels. Furosemide (10⁻⁴ M), an inhibitor of Na⁺-K⁺ -2Cl⁻ co-transporter, also inhibited the increased I_SC response to CQ, whereas another Cl⁻ channel inhibitor, CFTR(inh)-172(10⁻⁵M), had no effect. Intriguingly, CQ-evoked increases were almost completely abolished by niflumic acid (10⁻⁴M), a relatively specific Ca²⁺-activated Cl⁻ channel (CaCC) inhibitor. Furthermore, other CaCC inhibitors, such as DIDS and NPPB, also exhibited similar effects. CQ-induced increases in I_SC were also abolished by thapsigargin(10⁻⁶M), a Ca²⁺ pump inhibitor and in the absence of either Cl⁻ or Ca²⁺ from bathing solutions. Further studies demonstrated that T2R and CaCC-TMEM16A were colocalized in small intestinal epithelial cells and the T2R agonist CQ evoked an increase of intracelluar Ca²⁺ in small intestinal epithelial cells. Taken together, these results demonstrate that CQ induces Cl⁻ secretion in rat ileum through CaCC at low concentrations, suggesting a novel explanation for CQ-associated gastrointestinal side-effects during the treatment of malaria.     

Niflumic Acid Affects Store-Operated Ca2+-Permeable (SOC) and Ca2+-Dependent K+ and Cl− Ion Channels and Induces Apoptosis in K562 Cells

Non-steroidal anti-inflammatory drugs (NSAIDs) are known to induce apoptosis in a variety of cancer cells. However, the precise mechanisms by which NSAIDs facilitate apoptosis in tumor cells are not clear. In the present study, we show that niflumic acid (NA), a member of the fenamates group of NSAIDs and Cl^? and Ca²⁺-activated Cl^? (CAC) channels blocker, induced apoptosis (by ~8 %, 24 h treatment) and potentiated (by 8–10 %) apoptotic effect of endoplasmic reticulum Ca²⁺ mobilizer thapsigargin (Tg) in human erythroleukemic K562 cell line. The whole-cell patch clamp and Fluo-3 flow cytometric experiments confirmed an inhibitory effect of NA (100 and 300 µM) on store-operated (SOC) channels. We also found that NA-blocked CAC channels were activated by acute application of Tg (2 µM) in K562 cells. NA blockage of CAC channels was accompanied by activation of Ca²⁺-activated K⁺ (SK4) channels. The observed effects of NA were not connected with COX-2 inhibition since 100-nM NA (IC₅₀ for COX-2 inhibition) did not induce either apoptosis or affect the channels activity. We conclude that inhibition of SOC channels plays a major role in NA-induced apoptosis. Increased apoptotic levels in Tg-treated K562 cells in the presence of NA may be due to the blockage of CAC and stimulation of SK4 channels in addition to SOC channels inhibition.     

Is a Ca2+ -ATPase involved in Ca2+ regulation during capacitation and the acrosome reaction of guinea-pig spermatozoa?

The Ca2+-ATPase antagonists quercetin and ethacrynic acid accelerated the onset of the acrosome reaction in guinea-pig spermatozoa incubated in the continuous presence of Ca2+, whereas furosemide had no effect, and sodium orthovanadate only affected sperm motility. When spermatozoa were preincubated in a 'Ca2+-free' medium, quercetin and ethacrynic acid shortened capacitation time: spermatozoa incubated for 1 h in 100-200 microM-ethacrynic acid showed 60-80% acrosome reactions when Ca2+ was added. Such spermatozoa were able to fertilize zona-free hamster eggs. Our results therefore point to the possible involvement of a Ca2+-ATPase in the regulation of intracellular Ca2+ in spermatozoa. Cysteine and dithiothreitol, both disulphide reducing agents, prevented the effects of quercetin and ethacrynic acid, suggesting that sulphydryl groups may be important for the expression of Ca2+-ATPase activity. Lysophosphatidylserine (LS) also prevented the stimulatory effect of ethacrynic acid, an effect similar to that shown by LS on lysophosphatidylcholine (LC). It is argued that both LS and LC could exert their action through an effect on the Ca2+-ATPase.     

In Situ OH Generation from O2 ? and H2O2 Plays a Critical Role in Plasma-Induced Cell Death

Reactive oxygen and nitrogen species produced by cold atmospheric plasma (CAP) are considered to be the most important species for biomedical applications, including cancer treatment. However, it is not known which species exert the greatest biological effects, and the nature of their interactions with tumor cells remains ill-defined. These questions were addressed in the present study by exposing human mesenchymal stromal and LP-1 cells to reactive oxygen and nitrogen species produced by CAP and evaluating cell viability. Superoxide anion (O₂ ⁻) and hydrogen peroxide (H₂O₂) were the two major species present in plasma, but their respective concentrations were not sufficient to cause cell death when used in isolation; however, in the presence of iron, both species enhanced the cell death-inducing effects of plasma. We propose that iron containing proteins in cells catalyze O₂ ⁻ and H₂O₂ into the highly reactive OH radical that can induce cell death. The results demonstrate how reactive species are transferred to liquid and converted into the OH radical to mediate cytotoxicity and provide mechanistic insight into the molecular mechanisms underlying tumor cell death by plasma treatment.     

Early-phase occurrence of K+ and Cl? efflux in addition to Ca2+ mobilization is a prerequisite to apoptosis in HeLa cells

Sustained rise in cytosolic Ca(2+) and cell shrinkage mainly caused by K(+) and Cl(-) efflux are known to be prerequisites to apoptotic cell death. Here, we investigated how the efflux of K(+) and Cl(-) as well as the rise in cytosolic Ca(2+) occur prior to caspase activation and are coupled to each other in apoptotic human epithelial HeLa cells. Caspase-3 activation and DNA laddering induced by staurosporine were abolished by blockers of K(+) and Cl(-) channels or cytosolic Ca(2+) chelation. Staurosporine induced decreases in the intracellular free K(+) and Cl(-) concentrations ([K(+)](i) and [Cl(-)](i)) in an early stage prior to caspase-3 activation. Staurosporine also induced a long-lasting rise in the cytosolic free Ca(2+) concentration. The early-phase decreases in [K(+)](i) and [Cl(-)](i) were completely prevented by a blocker of K(+) or Cl(-) channel, but were not affected by cytosolic Ca(2+) chelation. By contrast, the Ca(2+) response was abolished by a blocker of K(+) or Cl(-) channel. Strong hypertonic stress promptly induced a cytosolic Ca(2+) increase lasting >50 min together with sustained shrinkage and thereafter caspase-3 activation after 4 h. The hypertonic stress induced slight increases in [K(+)](i) and [Cl(-)](i) in the first 50 min, but these increases were much less than the effect of shrinkage-induced condensation, indicating that K(+) and Cl(-) efflux took place. Hypertonicity induced caspase-3 activation that was prevented not only by cytosolic Ca(2+) chelation but also by K(+) and Cl(-) channel blockers. Thus, it is concluded that not only Ca(2+) mobilization but early-phase efflux of K(+) and Cl(-) are required for caspase activation, and Ca(2+) mobilization is a downstream and resultant event of cell shrinkage in both staurosporine- and hypertonicity-induced apoptosis.     

C-Terminal Modulatory Domain Controls Coupling of Voltage-Sensing to?Pore Opening in Cav1.3 L-type Ca2+ Channels

Activity of voltage-gated Ca_v1.3 L-type Ca²⁺ channels is required for proper hearing as well as sinoatrial node and brain function. This critically depends on their negative activation voltage range, which is further fine-tuned by alternative splicing. Shorter variants miss a C-terminal regulatory domain (CTM), which allows them to activate at even more negative potentials than C-terminally long-splice variants. It is at present unclear whether this is due to an increased voltage sensitivity of the Ca_v1.3 voltage-sensing domain, or an enhanced coupling of voltage-sensor conformational changes to the subsequent opening of the activation gate. We studied the voltage-dependence of voltage-sensor charge movement (Q_ON-V) and of current activation (I_Ca-V) of the long (Ca_v1.3_L) and a short Ca_v1.3 splice variant (Ca_v1.3_42A) expressed in tsA-201 cells using whole cell patch-clamp. Charge movement (Q_ON) of Ca_v1.3_L displayed a much steeper voltage-dependence and a more negative half-maximal activation voltage than Ca_v1.2 and Ca_v3.1. However, a significantly higher fraction of the total charge had to move for activation of Ca_v1.3 half-maximal conductance (Ca_v1.3: 68%; Ca_v1.2: 52%; Ca_v3.1: 22%). This indicated a weaker coupling of Ca_v1.3 voltage-sensor charge movement to pore opening. However, the coupling efficiency was strengthened in the absence of the CTM in Ca_v1.3_42A, thereby shifting I_Ca-V by 7.2 mV to potentials that were more negative without changing Q_ON-V. We independently show that the presence of intracellular organic cations (such as n-methyl-D-glucamine) induces a pronounced negative shift of Q_ON-V and a more negative activation of I_Ca-V of all three channels. These findings illustrate that the voltage sensors of Ca_v1.3 channels respond more sensitively to depolarization than those of Ca_v1.2 or Ca_v3.1. Weak coupling of voltage sensing to pore opening is enhanced in the absence of the CTM, allowing short Ca_v1.3_42A splice variants to activate at lower voltages without affecting Q_ON-V.     

On the Gating Mechanisms of the Light-dependent Conductance in Pecten Hyperpolarizing Photoreceptors: Does Light Remove Inactivation in Voltage-dependent K Channels?

The hyperpolarizing receptor potential of ciliary photoreceptors of scallop and other mollusks is mediated by a cGMP-activated K conductance; these cells also express a transient potassium current triggered by depolarization. During steady illumination, the outward currents elicited by voltage steps lose their decay kinetics. One interesting conjecture that has been proposed is that the currents triggered by light and by depolarization are mediated by the same population of channels, and that illumination evokes the receptor potential by removing their steady-state inactivation. Exploiting the information that has become available on the phototransduction cascade of ciliary photoreceptors, we demonstrated that the same downstream signaling elements are implicated in the modulation of voltage-elicited currents: direct chemical stimulation both at the level of the G protein and of the final messenger that controls the light-dependent channels (cGMP) also attenuate the falling phase of the voltage-activated current. Application of a protein kinase G antagonist was ineffective, suggesting that a cGMP-initiated phosphorylation step is not implicated. To ascertain the commonality of ionic pathways we used pharmacological blockers. Although millimolar 4-aminopyridine (4-AP) suppressed both currents, at micromolar concentrations only the photocurrent was blocked. Conversely, barium completely and reversibly antagonized the transient voltage-activated current with no detectable effect on the light-evoked current. These results rule out that the same ionic pores mediate both currents; the mechanism of light modulation of the depolarization-evoked K current was elucidated as a time-dependent increase in the light-sensitive conductance that is superimposed on the inactivating K current.     

Is ryanodine receptor a calcium or magnesium channel? Roles of K+ and Mg2+ during Ca2+ release

The ryanodine receptor (RyR) is a poorly selective channel that mediates Ca(2+) release from intracellular Ca(2+) stores. How RyR's selectivity between the physiological cations K(+), Mg(2+), and Ca(2+) affects single-channel Ca(2+) current amplitude is examined using a recent model of RyR permeation. It is found that K(+) provides the vast majority of the countercurrent (through RyR itself) that is needed to prevent the sarcoplasmic reticulum (SR) membrane potential from changing and stopping Ca(2+) release. Moreover, intra-pore competition between Ca(2+) and Mg(2+) defines single RyR Ca(2+) current amplitude. Since both [Mg(2+)] and [Ca(2+)](SR) can change during pathophysiological conditions, the RyR unitary Ca(2+) current amplitude during Ca(2+) release may change significantly due to this Ca(2+)/Mg(2+) competition. Compared to the classic action of Mg(2+) on RyR open probability, these Ca(2+) current amplitude changes have as large or larger effects on overall RyR Ca(2+) mobilization. A new aspect of RyR divalent versus monovalent selectivity is also identified where this kind of selectivity decreases as divalent concentration increases.     

Calretinin Regulates Ca2+-dependent Inactivation and Facilitation of Cav2.1 Ca2+ Channels through a Direct Interaction with the α12.1 Subunit

Voltage-gated Ca_v2.1 Ca²⁺ channels undergo dual modulation by Ca²⁺, Ca²⁺-dependent inactivation (CDI), and Ca²⁺-dependent facilitation (CDF), which can influence synaptic plasticity in the nervous system. Although the molecular determinants controlling CDI and CDF have been the focus of intense research, little is known about the factors regulating these processes in neurons. Here, we show that calretinin (CR), a Ca²⁺-binding protein highly expressed in subpopulations of neurons in the brain, inhibits CDI and enhances CDF by binding directly to α₁2.1. Screening of a phage display library with CR as bait revealed a highly basic CR-binding domain (CRB) present in multiple copies in the cytoplasmic linker between domains II and III of α₁2.1. In pulldown assays, CR binding to fusion proteins containing these CRBs was largely Ca²⁺-dependent. α₁2.1 coimmunoprecipitated with CR antibodies from transfected cells and mouse cerebellum, which confirmed the existence of CR-Ca_v2.1 complexes in vitro and in vivo. In HEK293T cells, CR significantly decreased Ca_v2.1 CDI and increased CDF. CR binding to α₁2.1 was required for these effects, because they were not observed upon substitution of the II-III linker of α₁2.1 with that from the Ca_v1.2 α₁ subunit (α₁1.2), which lacks the CRBs. In addition, coexpression of a protein containing the CRBs blocked the modulatory action of CR, most likely by competing with CR for interactions with α₁2.1. Our findings highlight an unexpected role for CR in directly modulating effectors such as Ca_v2.1, which may have major consequences for Ca²⁺ signaling and neuronal excitability.