Calmodulin Is an Auxiliary Subunit of KCNQ2/3 Potassium Channels

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The Journal of Neuroscience, September 15, 2002, 22(18):7991-8001

Calmodulin Is an Auxiliary Subunit of KCNQ2/3 Potassium Channels
Hua Wen and Irwin B. Levitan
Department of Neuroscience, University of Pennsylvania School of Medicine, Philadelphia, Pennsylvania 19104

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Calmodulin (CaM) was identified as a KCNQ2 and KCNQ3 potassium channel-binding protein, using a yeast two-hybrid screen. CaMis tethered constitutively to the channel, in the absence or presenceof Ca²⁺, in transfected cells and also coimmunoprecipitates with KCNQ2/3from mouse brain. The structural elements critical for CaM bindingto KCNQ2 lie in two conserved motifs in the proximal half of thechannel C-terminal domain. Truncations and point mutations inthese two motifs disrupt the interaction. The first CaM-bindingmotif has a sequence that conforms partially to the consensusIQ motif, but both wild-type CaM and a Ca²⁺-insensitive CaM mutant bind to KCNQ2. The voltage-dependent activationof the KCNQ2/3 channel also shows no Ca²⁺ sensitivity, nor is it affected by overexpression of the Ca²⁺-insensitive CaM mutant. On the other hand, KCNQ2 mutants deficientin CaM binding are unable to generate detectable currents whencoexpressed with KCNQ3 in CHO cells, although they are expressedand targeted to the cell membrane and retain the ability to assemblewith KCNQ3. A fusion protein containing both of the KCNQ2 CaM-bindingmotifs competes with the full-length KCNQ2 channel for CaM bindingand decreases KCNQ2/3 current density in CHO cells. The correlationof CaM binding with channel function suggests that CaM is an auxiliarysubunit of the KCNQ2/3channel.

Key words: calmodulin; KCNQ channels; M current; IQ motif; channel modulation; auxiliary subunit; Ca²⁺-independent interaction

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

KCNQ2 and KCNQ3 are two members of the KCNQ potassium channel family that are expressed exclusively in the nervous system.In addition to forming functional homomeric channels, KCNQ2 andKCNQ3 subunits coassemble to form a heteromeric channel that underliesthe neuronal M current (Wang et al., 1998). Consistent with theproposal that the M current plays a critical role in controllingneuronal excitability, mutations in KCNQ2 and KCNQ3 genes havebeen linked to an autosomal dominant human epilepsy (Biervertet al., 1998; Charlier et al., 1998; Singh et al., 1998). TheM current is modulated richly by a variety of receptor systemsvia poorly understood intracellular signaling mechanisms (Brownand Adams, 1980; Marrion, 1997; Selyanko et al., 2000), and KCNQ2/3channel activity also is strongly suppressed by muscarinic agonistsin both neurons and heterologous cells (Selyanko et al., 2000;Shapiro et al., 2000).

The recent cloning of five mammalian KCNQ genes establishes a voltage-dependent potassium (Kv) channel family evolutionarilydistinct from other Kv channels. Most notably, KCNQ channels possessa C-terminal domain after the end of the sixth transmembrane domain,which is much longer than those of most other Kv channels (Kubischet al., 1999; Lerche et al., 2000; Schroeder et al., 2000). Althoughthe function of the C-terminal domain currently is unknown, itappears to be indispensable for channel function because severalloss-of-function KCNQ2 mutations identified in epileptic patientsinvolve truncations or alterations in this region of the channel(Biervert et al., 1998; Singh et al., 1998; Lerche et al., 1999).KCNQ2 splice variants missing an intact C-terminal tail also failto give rise to measurable current when expressed in heterologoussystems (Nakamura et al., 1998; Smith et al., 2001). One possibilityis that the long C-terminal tail domain provides the sites whereother signaling proteins interact with the channel and modulatechannel activity, as has been shown for KCNQ1. This cardiac channelinteracts with an adaptor protein via a C-terminal domain leucinezipper motif, thus recruiting protein kinase A (PKA) and proteinphosphatase 1 into a signaling complex that is required for $beta$ -adrenergicreceptor modulation of the channel (Marx et al., 2002). KCNQ2and KCNQ3 may interact with cytoskeleton, because they are foundin brain in a Triton X-100 insoluble protein complex along withtubulin and a PKA subunit (Cooper et al., 2000). There is alsoevidence that a single membrane-spanning protein, KCNE2, associateswith these two channels (Tinel et al., 2000).

The universal cellular calcium sensor calmodulin (CaM) is a small protein with four EF-hand-type Ca²⁺-binding sites. Evidence that ion channels are among the numeroustarget proteins regulated by CaM binding has been accumulatingin recent years. In a number of Ca²⁺-permeant channels CaM was suggested to mediate negative feedbackprocesses that regulate Ca²⁺ entry into the cell (Levitan, 1999; Saimi and Kung, 2002). CaMwas shown to be tethered constitutively to two types of calcium-activatedpotassium channels [small (SK) and intermediate (IK) conductance]and to confer calcium dependence to these channels (Xia et al.,1998; Fanger et al., 1999). For a voltage-dependent potassiumchannel, human ether à go-go (EAG), CaM was found to bind thechannel in a Ca²⁺-dependent manner and inhibit its activity (Schonherr et al.,2000).

In this study we describe and characterize the interaction of CaM with KCNQ2/3 and identify two conserved CaM-binding sitesin the C-terminal domain of the channel protein. Via mutagenesisand competition experiments we show that the Ca²⁺-sensing function of CaM is not necessary for it to bind to thechannel. Instead, the Ca²⁺-independent interaction itself seems to be essential for channelfunction.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Yeast two-hybrid screen and interaction assay. A yeast two-hybrid screen was performed according to a standard protocol (Schopperleet al., 1998). The coding sequence of the last 550 amino acidsof the mouse KCNQ2 channel and that of the last 512 amino acidsof the mouse KCNQ3 channel were cloned into the bait vector, pEG202.The baits were screened against a mouse brain cDNA library subclonedinto the prey vector, pJG45 (Matchmaker cDNA library, Clontech,Palo Alto, CA). Approximately 3,400,000 yeast cotransformantswere screened for KCNQ2-interacting clones and ~1,000,000 forKCNQ3 interactors. True positive clones were selected on plateslacking leucine, tryptophan, histidine, and uracil and were assayedfor $beta$ -galactosidase activity on plates containing X-gal. Libraryplasmids of the interactor clones were isolated from yeast cells,and the sequences of their library inserts were determined byDNAsequencing.

For the interaction assay the indicated KCNQ2 C-terminal-fragment coding sequences were subcloned into the bait vector, pEG202,as fusions with the LexA DNA-binding domain. CaM was fused tothe B42 transcription activation domain in the prey vector pJG45.Positive interactions were identified as blue colonies grown onthe selection plates (medium lacking leucine, tryptophan, histidine,and uracil) containing X-gal on the third day ofplating.

DNA constructs and mutagenesis. Mouse KCNQ2 was amplified by PCR from a mouse brain cDNA library (Marathon-ready cDNA library,Clontech) by using the following primers designed according tothe sequence of rat KCNQ2 (GenBank accession number AF087453):5'-CGCCGCCGGCACCATGGTGCAAAAGTCGCG-3' and 5'-CTTCCTAGGCCCTGCCCAAGCCACATCTCCAAAGGG-3'.The PCR product was TA-cloned into the mammalian expression vectorpCDNA3.1/V5/His-TOPO (Invitrogen, San Diego, CA) to tag the channelwith a V5 epitope at the C terminus. The complete coding sequenceof mouse KCNQ2 has been deposited to GenBank (accession numberAF490773). A mouse KCNQ3 fragment including the C-terminalsequence was PCR-amplified from the same library with the followingprimers: 5'-GGCGCGCGGATCATGGCATTGGAGTTCCCG-3' and 5'-AGTGGGCTTGTTGGAAGGGGTCCATATGGAATC-3'.The C-terminal sequence, which is 99.4% identical to that of therat KCNQ3 (GenBank accession number AF091247) on the aminoacid level, then was subcloned into pEG202 for the two-hybridscreen. Full-length rat KCNQ3 cDNA was the kind gift of Dr. DavidMcKinnon (State University of New York at Stony Brook, Stony Brook,NY) (Wang et al., 1998). It also was tagged with a V5 epitopein pCDNA3.1/V5/His-TOPO. For KCNQ2/3 channel recordings, the mouseKCNQ2 and rat KCNQ3 cDNAs were cloned into pIRES2-EGFP, a bicistronicvector that allows for coexpression of both subunits in the samecell (Clontech). This was done by inserting KCNQ2 cDNA into themulticloning site of the vector and replacing enhanced green fluorescentprotein (EGFP) cDNA in the original vector with KCNQ3 cDNA. CaMcDNA (the kind gift of Dr. John Lowenstein, Brandeis University,Waltham, MA) was subcloned into the two-hybrid prey vector pJG45and a modified version of the mammalian expression vector pCDNA3to give it a hemagglutinin (HA) epitope tag at the N terminus.For the expression of GST fusion proteins in mammalian cells,the indicated KCNQ2 sequences were cloned into the pEBG-1 vector(kindly provided by Dr. Joseph Avruch, Harvard Medical School,Boston,MA).

Site-directed mutagenesis was done via the Quik-Change system (Stratagene, La Jolla, CA) according to the manufacturer's instructions.The final cDNAs were sequenced through the entire coding regionto ensure that there were no additional mutations introduced byPCR except at the desired sites (DNA sequencing facility, Universityof Pennsylvania, Philadelphia,PA).

Antibody preparation, coimmunoprecipitation, and Western blotting. The anti-mouse KCNQ2 antibody was generated by immunizingrabbits with a GST fusion protein containing the C-terminal 42amino acids of the cloned channel. Specific anti-mKCNQ2 antibodywas affinity-purified by Sepharose beads coupled with a maltose-bindingprotein (New England Biolabs, Beverly, MA) fusion containing thesame mKCNQ2 C-terminal sequence. This antibody recognizes KCNQ3protein as well. Other antibodies were purchased from UpstateBiotechnology (Lake Placid, NY; anti-CaM), Santa Cruz Biotechnology(Santa Cruz, CA; anti-GST, anti- $beta$ -tubulin), and Invitrogen (anti-V5,anti-Myc).

Coimmunoprecipitation and Western blotting were done as described previously (Wang et al., 1999). tsA201 cells were maintainedin DMEM supplemented with 10% fetal bovine serum (FBS). At 48hr after transfection with a calcium phosphate protocol, the cellswere lysed in a buffer containing 1% CHAPS and (in mM) 20 Tris-HCl,pH 7.5, 10 EDTA, 120 NaCl, 50 KCl, 50 NaF, 2 DTT, and proteaseinhibitors (1 mM PMSF plus 1 µg/ml each aprotinin, leupeptin,and pepstatin A). Cleared lysates were incubated for 2 hr at 4°Cwith the appropriate antibodies, and the immunocomplexes wereprecipitated with protein A/G-agarose beads (Santa CruzBiotechnology).

Proteins in the cell lysates or immunoprecipitates were separated on polyacrylamide gels and transferred to nitrocellulosemembranes. The blots were blocked with 5% nonfat milk in TBST(10 mM Tris-HCl, pH 7.5, 150 mM NaCl, 0.1% Tween 20) and thenincubated with the appropriate primary antibodies in blockingbuffer at 4°C overnight. After three washes with TBST the blotswere incubated with horseradish peroxidase-conjugated anti-mouseor anti-rabbit IgG (Amersham Biosciences, Arlington Heights, IL)for 1 hr at room temperature. Proteins were visualized with anenhanced chemiluminescence detection system (AmershamBiosciences).

Membrane preparation from tissues and affinity purification of KCNQ channels. For crude membrane preparation the strippedmouse brains and mouse pancreas (Pel-Freez Biologicals, Rogers,AK) were ground to fine powder while being kept frozen in liquidnitrogen. The powders were homogenized further by using a glasshomogenizer with five strokes in a buffer containing (in mM) 2.5KCl, 250 sucrose, and 25 HEPES, pH 7.4, with complete proteaseinhibitors and 2 mM DTT. The homogenates were centrifuged at 1000× g for 10 min, and the supernatants were centrifuged again for1 hr at 150,000 × g. The pellets were the crude membraneextracts.

Immunoaffinity purification of KCNQ2/3 channels from tissue extracts was done after a protocol by Cooper and colleagues (Cooperet al., 2000). Briefly, the membrane fractions were resuspendedin a lysis buffer containing 1% Triton X-100 plus (in mM) 20 Tris-HCl,pH 7.5, 10 EDTA, 120 NaCl, 50 KCl, and 50 NaF with 2 DTT and completeprotease inhibitors. The protein concentrations of the lysateswere adjusted to 2-3 mg/ml (DC protein assay, Bio-Rad, Hercules,CA). Polyclonal KCNQ2/3 antibody, which was coupled covalentlyto Sepharose beads, was added to the lysates and incubated at4°C overnight. Then the beads were recovered and washed five timesby using 200 bead volumes of lysis buffer. Proteins bound to thebeads were eluted with sample loadingbuffer.

Cell surface biotinylation. tsA 201 cells were washed three times with PBS at 2 d after transfection and then were incubatedwith 2 ml of 0.5 mg/ml Sulfo-NHS-LC-Biotin (Pierce, Rockford,IL) in PBS, pH 8.0, at room temperature for 30 min with gentleagitation. This reagent is cell membrane-impermeable because ofits charged sulfate group, and it does not label an overexpressedintracellular protein, 14-3-3, used as a negative control forthis assay in our laboratory. After the labeling reaction thereagent was removed by washing the cells three times with PBS.Cells were harvested and lysed in the lysis buffer as describedpreviously. Then 20 µl of ImmunoPure immobilized streptavidinbeads (Pierce) was added to each cell lysate to isolate the biotinylatedproteins. Channels in total cell lysates and streptavidin precipitateswere analyzed by Western blotting with the anti-V5 antibody. Toconfirm that the biotinylation reagent did not leak into the celland label intracellular proteins, we stripped and reprobed thesame blots with an anti- $beta$ -tubulin antibody (Joiner et al., 2001).

Emission fluorescence spectroscopy. Tryptophan fluorescence of the IQ-2 peptide (see Fig. 7A), alone or with increasing amountsof CaM, was measured with the PerkinElmer LS50B luminescence spectrometer(PerkinElmer Life Sciences, Emeryville, CA). The excitation wavelengthwas 295 nm, and emission spectra were recorded from 300 to 400nm. Both excitation and emission bandwidths were 5 nm. The concentrationof IQ-2 peptide was 1.6 µM in 30 mM Tris-HCl, pH 7.5, and 50 mMNaCl, with a 1 mM concentration of either CaCl₂ or EGTA. For thetitration experiments a small volume of concentrated CaM was addedto the buffer containing the IQ peptide. The final fluorescencedata were obtained by subtracting the buffer fluorescence fromthose of the peptide and peptide plus CaM and correcting for changesin the sample volume caused by the CaM additions. The bindingwas described as: IQ + CaM $left-right-arrow$ IQ·CaM.

The dissociation constant K_D for this reaction is:

(1)

where [IQ]₀ is the initial concentration of the peptide, [CaM]₀ is the initial concentration of CaM, and [IQ·CaM] is theconcentration of the IQ·CaM complex, respectively. Because theobserved fluorescence is attributed to a single tryptophan residuein the IQ-2 peptide, the fluorescence intensity F is:

(2)

where F_IQ and F_IQ·CaM are the quantum efficiencies of IQ-2 and IQ·CaM. Experimental fluorescence intensity data givenas a function of [CaM] were fit by combining equations 1 and 2,using a nonlinear least squares program (Origin, Microcal, Northampton,MA) to give the estimated value for K_D, F_IQ, and F_IQ·CaM.

Electrophysiological recordings. Chinese hamster ovary (CHO) cells were maintained in Ham's F-12 medium with 10% FBS and transfectedwith Lipofectamine Plus (Invitrogen, San Diego, CA) accordingto the manufacturer's instructions. To identify transfected cells,we cotransfected the cells with channel constructs and EGFP; onlycells with bright green fluorescence were used forrecordings.

At 1-3 d after transfection the KCNQ2/3 currents were recorded in the whole-cell configuration with an Axopatch 200A amplifier(Axon Instruments, Union City, CA). Pipette electrodes were pulledfrom borosilicate glass and had resistances of 2-4 M $Omega$ . The bathsolution consisted of (in mM): 105 NaCl, 30 KCl, 2 MgCl₂, 1.8CaCl₂, 10 HEPES, pH 7.2. The electrode solution consisted of (inmM): 10 NaCl, 130 KCl, 0.5 MgCl₂, 5 EGTA, 10 HEPES, pH 7.2. Forinternal solutions containing 100 nM and 10 µM free Ca²⁺, appropriate amounts of CaCl₂ were added to the internal solutionaccording to calculations from Equal software (Biosoft, Cambridge,UK). Cells were held at $-$ 80 mV and depolarized to +80 mV in 10mV steps for 1 sec. Data were acquired and analyzed with pClamp7 software (Axon Instruments). To construct the activation curves,we fit relative tail currents (I_rel) to the Boltzmann equation:

(3)

where V_0.5 is the half-maximum activation voltage and k is the slope factor. All results are shown as mean ± SEM; statisticalsignificance was assessed by one-way ANOVA(Origin).

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Two-hybrid screen that uses KCNQ2 and KCNQ3 C termini as bait

The cloned mouse KCNQ2 channel has a long C-terminal domain after the putative S6 transmembrane segment. This domain shareslittle homology with its counterparts in other Kv channels andcontains no obvious structural motifs. To search for proteinsinteracting with KCNQ channels, we conducted a yeast two-hybridscreen by using the last 550 amino acids of the KCNQ2 channelas bait. We screened ~3.4 × 10⁶ yeast cotransformants and identified multiple positive interactorclones. All of these clones contain overlapping cDNA inserts oftwo mouse genes, M27844 and M19381, encoding the same proteinCaM. All of the cDNA inserts contain the complete coding sequencefor CaM but differ in the length of their 5'- and 3'-untranslatedregions. In an independent screen with the entire C-terminal domainof the mouse KCNQ3 channel as bait, CaM also was identified asa positiveinteractor.

CaM associates with KCNQ channels both in transfected cells and in mouse brain

To confirm the results from the two-hybrid screen, we expressed full-length KCNQ channels and CaM in the tsA 201 mammaliancell line and tested the interaction by coimmunoprecipitationexperiments. Overexpressed CaM, tagged with a HA epitope, is detectedin KCNQ2 channel immunoprecipitates when both proteins are transfectedtogether (Fig. 1A, bottom panel, lane 2), but not when CaM istransfected with the vector (Fig. 1A, bottom panel, lane 1). EndogenousCaM is also present in the channel immunoprecipitates, as shownby an 18 kDa band on the blot that is recognized by a specificmonoclonal antibody against CaM, even when no exogenous CaM isintroduced into the cells (data not shown). In the reciprocalexperiment KCNQ2 is found in the CaM immunoprecipitates (datanot shown). Using the same strategy, we also are able to confirmthe interaction of CaM and the KCNQ3 channel in transfected cells(Fig. 1A, bottom panel, lane 3). We fail to detect any interactionby coimmunoprecipitation when we mix together two lysates fromcells transfected with KCNQ2 or CaM individually, suggesting thatthe interaction between KCNQ2 and CaM might occur early in thebiogenesis pathway.

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Figure 1. CaM coimmunoprecipitates with KCNQ2 and KCNQ3 channels. A, tsA 201 cells were transfected with HA-tagged CaM together with one of following constructs: vector (lane 1), V5-tagged KCNQ2 (lane 2), or V5-tagged KCNQ3 (lane 3). Cell lysates were probed for the expression of CaM with the anti-HA antibody (top panel). Channel immunoprecipitates were probed with the anti-V5 antibody to confirm the precipitation of channels (middle panel) and were probed with the anti-HA antibody to detect CaM pulled down with the channels (bottom panel). CaM is present in a KCNQ channel immunoprecipitate, but not in that from vector-transfected cells. B, CaM copurifies with KCNQ2 and KCNQ3 channels from mouse brain. KCNQ2 and KCNQ3 channels were immunopurified from the crude membrane fraction of mouse brain (lane 1), but not pancreas (lane 2), with anti-KCNQ2/3 antibody-coupled Sepharose beads (top panel). CaM is detected in the channel immunoprecipitates from brain, but not pancreas, when probed with a specific monoclonal antibody against CaM (bottom panel).

To look for the existence of such a KCNQ2/3-CaM complex in the native neuronal environment, we asked whether CaM copurifieswith the channel when KCNQ2/3 is immunoprecipitated from mousebrain lysates. Consistent with a previous report, most KCNQ channelsare found in a 1% Triton X-100 insoluble subcellular fraction(Cooper et al., 2000). When the channels are pulled down fromthis fraction with a polyclonal antibody that recognizes bothKCNQ2 and KCNQ3 subunits, a 95 kDa protein band that is presentin the brain membrane prep (data not shown) is now enriched inthe immunoprecipitates (Fig. 1B, top panel, lane 1). This bandis indeed KCNQ protein because it is absent in the membrane prepand immunoprecipitates prepared from a control tissue, mouse pancreas(Fig. 1B, top panel, lane 2), which has been shown to lack KCNQ2/3mRNA (Biervert et al., 1998; Schroeder et al., 1998). CaM immunoreactivityis detected in the channel immunoprecipitates from brain, butnot pancreas (Fig. 1B, bottom panel). Therefore, the interactionof KCNQ channels and CaM occurs not only in heterologous cellsbut also in mousebrain.

CaM is tethered constitutively to KCNQ channels

The yeast two-hybrid system was shown to detect only Ca²⁺-independent interactions between CaM and the SK2 channel (Keen etal., 1999), suggesting that the CaM-KCNQ interaction in yeastis also Ca²⁺-independent. We have two additional lines of evidence that suggestCaM is tethered to KCNQ channel tails constitutively. First, coimmunoprecipitationof CaM and KCNQ2 persists even when the cells are lysed with abuffer containing a 1 mM (data not shown) or 10 mM (Fig. 2, bottompanel, lane 1) concentration of the Ca²⁺ chelator EGTA. Second, we made a Ca²⁺-insensitive CaM (Putkey et al., 1989; Geiser et al., 1991) byreplacing the first aspartate residue in each of its four EF-handCa²⁺-binding motifs with an alanine and tested its ability to coimmunoprecipitatewith KCNQ2. The mutant, CaM₁₂₃₄, is indeed unable to bind Ca²⁺, because it loses the Ca²⁺-dependent mobility shift characteristic of wild-type CaM on aprotein gel (Fig. 2, top panel) (Geiser et al., 1991; Xia et al.,1998). This mutant still coimmunoprecipitates robustly with theKCNQ2 channel, although to a somewhat reduced extent when comparedwith wild-type CaM (Fig. 2, bottom panel). Clearly, CaM bindsto KCNQ2 independent of its Ca²⁺-binding ability.

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Figure 2. Both Ca²⁺-CaM and apo-CaM coimmunoprecipitate with KCNQ2. tsA 201 cells were transfected with V5-tagged KCNQ2 together with one of two HA-tagged CaM constructs: wild type (lanes 1, 2) or Ca²⁺-insensitive mutant (CaM₁₂₃₄; lanes 3, 4). Cell lysates were probed for the expression of CaMs with the anti-HA antibody (top panel). KCNQ2 was precipitated with a polyclonal antibody against KCNQ2/3 in the presence of either 10 mM EGTA (lanes 1, 3) or 1 mM Ca²⁺ (lanes 2, 4), as indicated on the top of the blots. Channel immunoprecipitates were eluted with sample loading buffer containing 2 mM EGTA (for precipitates prepared in the presence of 10 mM EGTA) or 5 mM Ca²⁺ (for precipitates prepared in the presence of 1 mM Ca²⁺) and were used for Western blot. Blots were probed for the channel by using anti-V5 antibody (middle panel) and for CaMs by using anti-HA antibody (bottom panel). A doublet usually shows up in the channel blot (middle panel) with longer exposure. Both bands represent overexpressed KCNQ2 protein because they are absent in vector-transfected cells. CaM is detected in all immunoprecipitates. Ca²⁺-loaded CaM (lane 2) shows greater mobility than the apo-CaM (CaM₁₂₃₄ and wild-type CaM in the presence of EGTA) on the blots.

Voltage-dependent activation of the KCNQ2/3 channel shows no Ca²⁺ sensitivity

Recent years have seen the rediscovery of CaM as a key regulator of ion channel function by virtue of its constitutive tetheringto the channels and its well established function of Ca²⁺ sensing (Saimi and Kung, 2002). In those examples the tetheredCaM mediates some Ca²⁺-sensitive property of the channel, because the Ca²⁺-insensitive CaM mutants can act as dominant negatives for theseeffects (Xia et al., 1998; Peterson et al., 1999; Zuhlke et al.,1999). There has long been controversy about whether the nativeM current is modulated by intracellular Ca²⁺, and the heteromeric KCNQ2/3 channel has not been reported toshow Ca²⁺ dependence. We tested the voltage-dependent activation of KCNQ2/3channels expressed in CHO cells, using whole-cell patch recordingwith a range of Ca²⁺ concentrations in the pipette. No significant difference wasdetected in the half-maximal activation voltage and slope factorfor activation with 0 (5 mM EGTA), 100 nM, or 10 µM free intracellularCa²⁺ (Table 1). One possible explanation for the lack of effect isthat there is insufficient endogenous CaM to interact with theoverexpressed channel. This seems not to be the case, becausecoexpressing either wild-type CaM or CaM₁₂₃₄ together with thechannel has no effects on the voltage sensitivity of KCNQ2/3 (Table1), although our biochemical data demonstrate that both of thembind to the channel tail (Fig. 2). The kinetics for activationand deactivation also remains the same under all conditions (datanot shown).


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Table 1. Steady-state activation of the KCNQ2/3 channel under different recording conditions

Two binding sites are required for the constitutive tethering of CaM to KCNQ2

We adopted a truncation analysis strategy to identify binding domains for CaM in the KCNQ2 C-terminal tail. The original two-hybridbait, consisting of amino acids 321-870, was shortened progressivelyfrom either its N or C terminus, and the resultant truncationmutants were tested against CaM in a two-hybrid interaction assay.Deletion of over one-half of the tail from the C-terminal end(amino acids 568-870) leaves the interaction intact (Fig. 3).However, further truncation at position 535 completely abolishesthe interaction, indicating that amino acids 536-567, which wecall site 2, are important for the channel to bind to CaM (Fig.3). In contrast, the N terminus of the tail tolerates little truncation.Removal of just 38 residues (amino acids 321-358) from the positiveinteractor, Q2C $Delta$ 31, takes away its ability to bind CaM (Fig. 3).This region, named site 1, begins immediately after the S6 transmembranedomain and includes an IQ-2 peptide sequence (see Fig. 7A). Thetruncation analysis shows that the two CaM-binding motifs, site1 and site 2, are both necessary for KCNQ-CaM interaction, andremoval of either one will disrupt the association. Furthermore,the fragment containing both sites, Q2C $Delta$ 31, also interacts withthe Ca²⁺-insensitive CaM mutant CaM₁₂₃₄ in the two-hybrid system (datanot shown), suggesting that it is the minimum sequence mediatingthe Ca²⁺-independent constitutive interaction of CaM and KCNQ2.

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Figure 3. Truncation analysis reveals two sites in the KCNQ2 C-terminal domain that are necessary for CaM-KCNQ2 interaction. KCNQ2 C-terminal fragments (shown as boxes with amino acid numbers) were tested against CaM in the two-hybrid system for LacZ reporter gene expression (positive interactions are indicated by plus signs). Further truncation from either end of Q2C $Delta$ 31 (amino acids 321-567) abolished the interaction. The locations of the two putative CaM-binding sites, site 1 (amino acids 321-358; hatched boxes) and site 2 (amino acids 536-567; filled boxes), are indicated in each fragment.

To confirm further the necessity and sufficiency of these two sites in mediating the interaction, we constructed a GST fusionprotein containing these sites, GST-Q2C $Delta$ 31 (Fig. 4A), and testedits ability to bind CaM by coimmunoprecipitation. Two other fusionproteins were constructed also (Fig. 4A): one is missing site2 and the other is identical to GST-Q2C $Delta$ 31 except for a pointmutation (R345E) in site 1 that disrupts the interaction (seebelow). Not surprisingly, GST-Q2C $Delta$ 31 is the only protein amongthe three that coimmunoprecipitates with CaM (Fig. 4B, bottompanel).

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Figure 4. A GST fusion protein containing both binding sites coimmunoprecipitates with CaM. A, Schematic view of the fusion protein constructs. GST is shown as an oval. KCNQ2 C-terminal fragments are presented as lines with amino acid numbers. The locations of site 1 (hatched boxes) and site 2 (filled boxes) are indicated. The position of a mutation introduced in site 1, R345E, is indicated by an arrow. B, tsA 201 cells were transfected with HA-tagged CaM together with GST (lane 1), GST-Q2C $Delta$ 31 (lane 2), GST-Q2C $Delta$ 31(R345E) (lane 3), and GST-Q2C $Delta$ 4 (lane 4). Cell lysates were probed for the expression of CaM by using an anti-HA antibody (top panel). GST immunoprecipitates were probed for GST with anti-GST (middle panel) and for CaM with anti-HA (bottom panel). The fusion protein containing both sites, GST-Q2C $Delta$ 31, coimmunoprecipitates with CaM, whereas the one lacking site 2, GST-Q2C $Delta$ 4, does not. A single amino acid mutation (R345E) in site 1 also disrupts the interaction.

Mutations in site 1 and site 2 disrupt the association of CaM with KCNQ2

The interaction between KCNQ2 and CaM can be disrupted by point mutations in both site 1 and site 2. When a single positivelycharged residue in site 1 is changed to a negatively charged one(R345E), CaM no longer can be detected in the immunoprecipitatesof the mutant channel (Fig. 5A, bottom panel, lane 2). Point mutationof another conserved residue in site 1, I340E, also eliminatethe CaM-binding ability of the channel (data not shown). Additionally,binding is abolished when the charges of two conserved basic residuesin site 2 are reversed (K553E/R554E) (Fig. 5A, bottom panel, lane3).

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Figure 5. Properties of two KCNQ2 channels with mutations in CaM-binding sites. A, R345E and K553E/R554E KCNQ2 do not coimmunoprecipitate with CaM. HA-tagged CaM was coexpressed with one of the following V5-tagged KCNQ2 constructs in tsA 201 cells: wild type (lane 1), R345E (lane 2), or K553E/R554E (lane 3). Cell lysates were probed for the expression of CaM with anti-HA (top panel). KCNQ2 channel immunoprecipitates were probed for the channel with anti-V5 (middle panel) and for CaM with anti-HA (bottom panel). CaM is detected in immunoprecipitates of wild-type, but not mutant, channels. B, R345E and K553E/R554E KCNQ2 are expressed on the cell surface. tsA 201 cells were transfected with V5-tagged KCNQ2 channels. Cell surface proteins were biotinylated by a membrane-impermeable reagent and isolated by streptavidin beads. Channel immunoreactivity in the lysates (first panel) and in the streptavidin precipitates (third panel) was detected with the anti-V5 antibody. The proportions of mutant channels (lanes 2, 3) targeted to the surface are comparable with those of the wild-type KCNQ2 (lane 1). The biotinylation reagent did not label an intracellular protein, $beta$ -tubulin (second and fourth panels), confirming its specificity for cell surface proteins. C, R345E and K553E/R554E KCNQ2 still coimmunoprecipitate with KCNQ3. C-Myc-tagged KCNQ3 channel was transfected together with one of the V5-tagged KCNQ2 channels into tsA 201 cells. The KCNQ3 channel was pulled down with anti-Myc antibody, and the lysates (top panel) and immunoprecipitates (bottom panel) were probed for KCNQ2 with anti-V5. Both wild-type (lane 1) and mutant KCNQ2 channels (lanes 2, 3) immunoprecipitate with KCNQ3. Note that in B and C the top band of the KCNQ2 doublet in the cell lysates is enriched in the streptavidin or anti-KCNQ3 precipitates.

To summarize, our biochemical data demonstrate that CaM is tethered to the KCNQ2/3 channel in a Ca²⁺-independent manner via two binding motifs, site 1 and site 2,which are located in the proximal portion of the C-terminal domainof the channel. We then asked what the functional consequenceof this constitutive interactionis.

Correlation between CaM binding and channel function

During our patch-clamp recordings we noticed that two KCNQ2 mutants deficient in CaM binding, R345E and K553E/R554E, do notgive rise to detectable currents when coexpressed with KCNQ3 inCHO cells. These mutants are expressed at a somewhat reduced levelcompared with the wild-type channel (Fig. 5A, middle panel, B,C,top panels), but this difference in expression cannot accountfor the complete loss of channel activity. We tested two otherpossibilities that could explain a nonfunctional channel. We firstasked whether mutant channels could make it to the cell membranesurface. We labeled the total membrane proteins with a membrane-impermeablebiotinylation reagent and isolated membrane proteins with streptavidinbeads. The ratio of channels on the membrane to those in the totallysates is not significantly different in wild-type and the twomutant channels (Fig. 5B), indicating that the membrane targetingof the mutants is not altered. We then tested whether the mutantscan still coassemble with KCNQ3. When KCNQ3 is immunoprecipitatedfrom the cotransfected cells, the mutant KCNQ2 proteins are alsopresent in the precipitates, and quantification shows no markeddifference from wild type (Fig. 5C). Thus the lack of channelactivity cannot be explained by their inability to form heteromers.Despite the fact that some small quantitative differences do existin the expression of wild-type and mutant channels, the correlationbetween the ability of a channel to bind CaM and its functioncan be extended to several other KCNQ2 mutants bearing mutationsin one of the binding domains (Table 2). In all cases the mutantsare more or less normal in terms of their surface expression andtheir heteromerization with KCNQ3. All those that can bind CaMgive easily detectable currents when coexpressed with KCNQ3, whereasthose that cannot bind produce no current. Hence we hypothesizethat CaM binding is necessary for a functional KCNQ2/3 channel.


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Table 2. Properties of KCNQ2 mutant channels

A fusion protein that decreases CaM binding to KCNQ2 reduces channel activity

It is nearly impossible to find a CaM-free system to test this hypothesis, because removal of such an important molecule fromany cell is generally lethal. We therefore sought a molecule thatwould reduce the degree of CaM binding to the KCNQ2/3 channel.Because less functional CaM-KCNQ would be available in the cellin the presence of this competitor, our hypothesis predicts itwould decrease channel activity. GST-Q2C $Delta$ 31 could be such a candidatemolecule, because it contains both CaM-binding motifs and associateswith CaM in transfected cells (Fig. 4). GST-Q2C $Delta$ 31 indeed is capableof competing with the full-length KCNQ2 channel for binding toendogenous CaM, as shown by less CaM in KCNQ2 immunoprecipitateswhen GST-Q2C $Delta$ 31 is cotransfected into the cells (Fig. 6A, toppanel, lane 1). Consistent with our hypothesis, when GST-Q2C $Delta$ 31is coexpressed with the KCNQ2/3 channel in CHO cells, it significantlyreduces the current density (Fig. 6B,C) compared with two otherfusion proteins that do not compete for CaM binding (Fig. 6A).These data support the hypothesis that the constitutive tetheringof CaM to the KCNQ2/3 channel is essential for the channel function.

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Figure 6. A two-site fusion protein decreases CaM binding to KCNQ2 and reduces channel activity. A, GST-Q2C $Delta$ 31 competes with the full-length KCNQ2 channel for binding to endogenous CaM. tsA 201 cells were transfected with V5-tagged KCNQ2 together with one of the GST fusion constructs in a 1:1.5 molar ratio: GST-Q2C $Delta$ 31 (lane 1), GST-Q2C $Delta$ 31(R345E) (lane 2), or GST-Q2C $Delta$ 4 (lane 3). KCNQ2 immunoprecipitates were probed for the channel with an anti-V5 antibody (bottom panel) and endogenous CaM with a monoclonal anti-CaM antibody (top panel). In cells that were transfected with GST-Q2C $Delta$ 31 (lane 1), there is considerably less CaM in the KCNQ2 channel immunoprecipitates compared with cells in which the two other fusion proteins were transfected (lanes 2, 3). Similar results were obtained when the fusion proteins were cotransfected with both KCNQ2 and KCNQ3 subunits (data not shown). Note that these GST fusion proteins are expressed at comparable levels in tsA 201 cells (Fig. 4B, middle panel). B, Representative recording traces from three CHO cells cotransfected with IR-Q2Q3 and one of the GST fusion protein constructs in a 1:1.5 molar ratio. The membrane capacitances were comparable in these three cells. C, GST-Q2C $Delta$ 31 reduces the current density of the KCNQ2/3 channel in CHO cells. Whole-cell tail currents after a hyperpolarizing step from + 20 to $-$ 80 mV were recorded 2-3 d after transfection and normalized to membrane capacitance to give the current density in that cell. GST-Q2C $Delta$ 31 significantly reduces KCNQ2/3 current density; *p < 0.05.

A role for Ca²⁺?

Many studies have shown that CaM binds to a relatively small stretch of sequences on its target proteins, such as Baa (basicamphiphilic $alpha$ ) helices and IQ motifs (Rhoads and Frieldberg, 1997).A careful inspection of the C-terminal amino acid sequence ofKCNQ2 reveals that amino acids 335-354 within site 1 resemblean IQ motif (Fig. 7A), which is loosely defined as IQxxxRGxxxR.Although it was proposed originally as a consensus sequence mediatingCa²⁺-independent binding, more and more IQ motifs have been foundto bind CaM in a Ca²⁺-dependent manner, with varying Ca²⁺ sensitivities (Jurado et al., 1999). We thus used a 20-amino-acidsynthetic peptide, IQ-2, corresponding in sequence to a portionof site 1 in KCNQ2 (Fig. 7A), in a gel mobility shift assay. Inthe presence of Ca²⁺ the preincubation of CaM and IQ-2 shifts the CaM band to a higherposition on a SDS-PAGE gel, and this mobility shift does not happenin the absence of Ca²⁺ (data not shown), suggesting the formation of an IQ-Ca²⁺·CaM complex.

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Figure 7. Fluorescence emission assay of the Ca²⁺-dependent interaction between an IQ-2 peptide and CaM. A, Alignment of the KCNQ2 IQ-2 sequence (bottom) with the canonical IQ motif (top), where X is any amino acid. Residues that are identical in the two sequences are highlighted in bold. B, Representative fluorescence emission spectra of 1.6 µM IQ-2 peptide alone in the presence of 1 mM Ca²⁺ or 1 mM EGTA (curve 1), 1.6 µM IQ-2 peptide with 3.33 µM CaM in the presence of 1 mM Ca²⁺ (curve 2), or 1 mM EGTA (curve 3). In the presence of 1 mM Ca²⁺ the addition of CaM blue-shifts the maximum emission wavelength and increases the fluorescence intensity (presented in arbitrary units, a.u.). C, Fluorescence titration of the IQ-2 peptide with CaM in the presence of 1 mM Ca²⁺. Fluorescence data from three independent experiments (mean ± SEM) are plotted against the CaM concentration. The line is the fit to a simple binding model: IQ-2 + CaM $left-right-arrow$ IQ-2·CaM. The dissociation constant, K_D, is estimated at 48 nM. The quantum efficiencies of IQ-2 and IQ·CaM, F_IQ, and F_IQ·_CaM are estimated to be 69.72 µM¹ and 154.65 µM¹, respectively.

Because the IQ-2 peptide contains a single tryptophan residue (W344) whereas CaM has none, the intrinsic fluorescence of thepeptide can be followed as a sensitive measure for any perturbationof the microenvironment around W344 because of the conformationalchanges caused by the CaM-peptide interaction (Keen et al., 1999).Adding CaM to peptide in the absence of Ca²⁺ (Fig. 7B, curve 3) does not change the emission spectrum of thepeptide, which peaks at 355 nm (Fig. 7B, curve 1). In the presenceof Ca²⁺ the CaM addition blue-shifts the emission maximum to 338 nm andincreases fluorescence intensity by a factor of 1.6 after thereaction reaches saturation (Fig. 7B, curve 2). These resultssuggest that Ca²⁺-loaded CaM binds to the IQ-2 peptide and, in doing so, introducesW344 into a more hydrophobic environment. To quantify the bindingreaction, we applied CaM titration to the peptide. Fitting theexperimental results to a simple binding model in which IQ-2 bindsto CaM with a 1:1 stoichiometry, we estimated the apparent dissociationconstant at 48 nM (Fig. 7C).

  DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The cytoplasmic domains of potassium channels greatly influence the expression, membrane targeting, subcellular localization,and gating properties of the pore-forming subunit. One commonmechanism by which they accomplish these diverse functions isto interact with other modulatory proteins (Holmes et al., 1996;Schopperle et al., 1998; Trimmer, 1998; Sheng and Kim, 1999).The recently cloned neuronal M current KCNQ2/3 channel has a C-terminaltail >500 amino acids in length, with functions that are yet tobe identified. These may be especially important, as suggestedby the observations that the tail domain is subject to extensivealternative splicing and is the site of several pathogenic mutations(Biervert et al., 1998; Nakamura et al., 1998; Singh et al., 1998;Pan et al., 2001; Smith et al., 2001). In this study we demonstratethat CaM is tethered to the KCNQ2 and KCNQ3 channels via two motifsin the proximal portion of the C-terminal domain, and the tetheringis necessary for channel function. Intriguingly, these two motifsare conserved both within the mammalian KCNQ family and acrossspecies. While this paper was under review, Yus-Nájera et al.(2002) reported the binding of CaM to mammalian KCNQ1-5. Althoughthese authors did not examine native tissue or the functionalcorrelates of the binding interaction, their conclusions aboutCaM association with the C-terminal tail domain of KCNQ agreewithours.

The biochemical interaction described here for CaM and KCNQ channels displays similarities to what is known for CaM-SK interactions.Our results show that several conserved positively charged residuesare important for the Ca²⁺-independent binding of CaM to KCNQ2. Similar results were obtainedfor the CaM binding to SK (Keen et al., 1999). More importantly,both cases feature a constitutive association and a Ca²⁺-dependent component of interaction. In SK2, amino acids 390-487in the proximal portion of the C-terminal tail were identifiedas the CaM-binding domain (CaMBD) (Xia et al., 1998). Severaldifferent assays show that CaMBD binds to CaM in the absence orpresence of Ca²⁺, whereas a subregion (amino acids 423-487) shows only Ca²⁺-dependent binding (Xia et al., 1998). We demonstrated by coimmunoprecipitationand two-hybrid assay that CaM is bound constitutively to KCNQ2and KCNQ3 channels. The minimum KCNQ2 sequence necessary for CaMbinding is a stretch of 247 amino acids (from 321 to 567) beginningimmediately after the S6 transmembrane domain. In the yeast two-hybridsystem CaM can still bind to this region even if all four of itsCa²⁺-binding sites are mutated, suggesting that it is the site whereCaM tethers to the channel independently of Ca²⁺. However, there is an IQ motif (amino acids 335-354) within thisminimum sequence that can bind CaM only in vitro in the presenceCa²⁺. CaM also has been shown to tether constitutively to some voltage-dependentcalcium channels and binds to IQ motifs in those channels in thepresence of Ca²⁺ (Peterson et al., 1999).

IQ motifs generally are predicted to be amphipathic $alpha$ -helices that bind to their targets with different levels of Ca²⁺ dependence. Our fluorescence measurement shows that an IQ-2 peptidefrom KCNQ2 binds to CaM only in the presence of Ca²⁺, but the precise Ca²⁺ dependence of this binding was not investigated further. Of course,the Ca²⁺ affinity of CaM in the CaM-peptide complex may not be the sameas that in the context of the full-length channel protein, becausethe channel has additional sequences that also contribute to CaMbinding. Therefore, it is hard to predict on the basis of ourbiochemical data whether the IQ-2 motif binds to CaM in responseto a rise in intracellular Ca²⁺ and whether the Ca²⁺-dependent interaction we see in vitro is of any significancein terms of channel function. The recent x-ray crystal structureof an SK2 CaMBD-CaM complex provides a detailed view of both Ca²⁺-dependent and -independent interactions and suggests a modelfor the mechanistic coupling between Ca²⁺ binding to CaM and channel gating (Schumacher et al., 2001).The complete understanding of how CaM is bound to KCNQ channelsmay have to await the elucidation of a similarstructure.

We tested whether KCNQ2 mutants that are deficient in CaM binding fail to produce measurable currents because they are unableto reach the cell surface. Because CaM seems to be associatedwith the KCNQ2 channel early in the biosynthetic pathway, it mightbe involved in the membrane trafficking process of the channel,as has been proposed for SK channels (Joiner et al., 2001). Ourdata argue against this possibility. The R345E and K553E/R554Emutant channels completely lose their abilities to interact withCaM, but we did not detect any marked difference in their surfaceexpression compared with the wild-type channel. It is interestingin this context that a human KCNQ2 mutant that causes BFNC, KCNQ2(1600ins5bp), truncates the protein at the far end of the CaM-bindingsite 2. This mutant was shown to have no surface expression inXenopus oocytes, indicating that at least some domains responsiblefor membrane targeting are located downstream of site 2 (Schwakeet al., 2000).

KCNQ channels often function as heteromultimers in vivo. For example, the KCNQ2/3 heteromeric channel gives rise to a currentthat is 10-fold bigger than that of the homomeric channels (Wanget al., 1998; Yang et al., 1998). It seemed possible that theKCNQ2 mutant channels deficient in CaM binding lose their abilityto assemble with KCNQ3, and the small currents given by homomericchannels elude our detection. Such an argument is in conflictwith two lines of evidence. First, all of our KCNQ2 mutants stillcan coimmunoprecipitate with KCNQ3. Thus the CaM-binding abilityof the channel can be dissociated from its ability to coassemblewith KCNQ3. Second, functional interactions have been shown forKCNQ3 with all KCNQ family members except KCNQ1, but other membersseem not to mix with each other (Kubisch et al., 1999; Lercheet al., 2000; Schroeder et al., 2000). Therefore, the structuralelement that mediates the heteromeric assembly is more likelyto be unique to the KCNQ3 sequence rather than common to all KCNQs,as the conserved CaM-binding motifs are. Although we did not testwhether the CaM-binding deficient KCNQ mutants are normal in theirhomomeric assembly, mutational studies in the KCNQ1 channel haveidentified a C-terminal domain downstream of site 2 as the cytoplasmicassembly domain. Deletion of a region homologous to site 2 inKCNQ1 produces no functional channel in a heterologous expressionsystem, but this mutant appears to retain the ability to coassemblewith other subunits, because it can suppress functional expressionof wild-type channels in a dominant negative manner (Schmitt etal., 2000).

The correlation between CaM binding and channel function in our mutagenesis studies is obvious. The major defect these KCNQ2mutants exhibit is in their ability to associate with CaM, butnot in the other properties we assayed. On the other hand, wedid not detect any Ca²⁺-dependent influence on channel activity. We thus hypothesizethat CaM binding, but not its Ca²⁺-sensing ability, is necessary for a functional KCNQ2/3 channel.This hypothesis predicts that, if we reduce the level of CaM boundto KCNQ channels, we should decrease channel activity. Indeed,a fusion protein consisting of the CaM-binding domain of KCNQ2,GST-Q2C $Delta$ 31, decreases CaM binding to the channel, presumably bycompeting for endogenous CaM. When this fusion protein is coexpressedwith the KCNQ2/3 channel, the current density is reduced significantly,although KCNQ2 is still targeted to the plasma membrane (datanot shown). Furthermore, CaM-null flies exhibit a phenotype consistentwith our hypothesis. Maternal deposits of CaM allow these fliesto survive to the larval stage, but the larvae are overexcitable,as would be expected from the loss of a potassium current thatnormally opposes neuronal excitability (Heiman et al., 1996).It also is interesting that four single amino acid substitutionsin the equivalent of site 1 in KCNQ1 and two in site 2 are foundin patients with long-QT syndrome (Splawski et al., 2000). Itseems possible that channel dysfunction in these mutants alsois caused by their inabilities to bindCaM.

Our results illustrate that Ca²⁺-free apo-CaM itself is likely to have important functions. Indeed, this is not the only casein which a calcium-binding protein like CaM modulates its targetsin the absence of Ca²⁺ binding. Apo-CaM has been shown to bind and modulate severaltarget proteins, including the inositol trisphosphate receptorand ryanodine receptor 1 (Patel et al., 1997; Rodney et al., 2000).Recently, a neuronal Ca²⁺-binding protein that shares nearly 56% identity with CaM wasshown to modulate the calcium channel Ca_v2.1 in the absence ofCa²⁺ (Lee et al., 2002).

Taken together, our data are consistent with the hypothesis that the binding of CaM to KCNQ channels is necessary for channelfunction. It is conceivable that the interaction between the KCNQC-terminal domain and CaM is dynamic and regulated by intracellularsignaling pathways. For example, there are multiple PKC consensussubstrate sites within site 2, and their phosphorylation statemay affect CaM binding. It also remains a distinct possibilitythat other signaling molecules might interact with the channeltail by using sequences adjacent to or overlapping the CaM-bindingdomains, causing changes in the CaM channel interaction and hencein channel function. Competitive binding of CaM and other proteinsto a common binding domain has been shown for NMDA receptors,metabotropic glutamate receptors, and the Trp3 channel (Wyszynskiet al., 1997; El Far et al., 2001; Zhang et al., 2001). Therefore,regulating the binding of CaM to KCNQ channels may provide a novelmechanism for modulating channel activity. It will be intriguingto see whether this mechanism is used by the multiple receptortypes that are known to modulate neuronal Mcurrent.

  FOOTNOTES

Received May 8, 2002; revised June 28, 2002; accepted July 2, 2002.

This work was supported by a grant from the National Institutes of Health. We are grateful to David McKinnon for rKCNQ3 cDNA,John Lowenstein for CaM cDNA, and Ping Jin for subcloning of CaM.We thank Carol Deutsch, Yi Zhou, Angela Jaramillo, and LindseyCiali for critical comments on this manuscript and Zhe Lu, BrianSalzberg, and Levitan laboratory members for helpful suggestionsanddiscussion.

Correspondence should be addressed to Dr. Irwin Levitan, Department of Neuroscience, University of Pennsylvania School ofMedicine, 3450 Hamilton Walk, Philadelphia, PA 19104. E-mail:levitani{at}mail.med.upenn.edu.

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