Interactions of Calmodulin with Two Peptides Derived from the C-terminal Cytoplasmic Domain of the Cav1.2 Ca2+ Channel Provide Evidence for a Molecular Switch Involved in Ca2+-induced Inactivation*

Jérôme Mouton, Anne Feltz, and Yves MauletDagger

From the Laboratoire de Neurobiologie Cellulaire, CNRS FRE 2180, 5 rue Blaise Pascal, 67084 Strasbourg, France

Received for publication, January 26, 2001, and in revised form, April 4, 2001

    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

When opened by depolarization, L-type calcium channels are rapidly inactivated by the elevation of Ca2+ 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 Ca2+-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 Cav1.2 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 Kd of the CB interaction with calmodulin to be 12 nM, i.e. below the Kd of IQ-calmodulin, thereby precluding a competitive displacement of CB by IQ in the presence of Ca2+. In place, we demonstrated that a ternary complex is formed at high Ca2+ concentration, provided that calmodulin and the peptides are initially allowed to interact at a low Ca2+ concentration. These results provide evidence that CB and IQ motifs interacting together with calmodulin constitute a minimal molecular switch leading to Ca2+-induced inactivation. In addition, we suggest that they could also be the tethering site of calmodulin.

    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Numerous Ca2+-dependent cellular functions are regulated by Ca2+ entries from the extracellular space. Therefore, much interest has focused on the regulation of the voltage-dependent Ca2+ channels. In the case of the widely distributed L-type dihydropyridine-sensitive channels, opposing inhibitory and facilitatory effects are both Ca2+-dependent. Observations of invertebrate cells (1) and identified L-type channels of mammalian neurons (2) have demonstrated that Ca2+ channel inactivation is promoted through Ca2+ entry itself, leading to the paradigm that Ca2+ ions cause Ca2+ current inactivation by binding to a site inside the cell (3). Actually, intracellular photorelease of caged Ca2+ can induce this blockade in less than 7 ms (4). From a functional point of view, this type of blockade helps to maintain the internal Ca2+ concentration within physiological limits. Facilitation in contrast is not systematically observed. A stimulatory effect of Ca2+ ions is only observed as a result of repetitive depolarizations (see Ref. 5, and references therein) or when a steady, moderately elevated internal Ca2+concentration is maintained before channel opening (6). In most cases, it is masked by inhibition. Facilitation characteristically develops within 30-60 s, suggesting a long multifactorial pathway. Therefore, these two opposing regulatory processes were at first thought to be mechanistically unrelated.

Potential sites controlling the Ca2+-induced inactivation/facilitation have been identified in the proximal third of the C-terminal cytoplasmic domain of Cav1.2. An EF hand-like motif located near the beginning of the 660-amino acid C terminus was shown to be essential for preserving the Ca2+-induced inactivation of the channel (7, 8), but not operational in the direct binding of Ca2+ (8, 9). A region of 80 residues located at a distance of 50 residues on the C-side of the EF hand, potentially involved in alternate splicing substitutions, was shown to be essential in preserving the Ca2+ -induced inactivation of the commonly studied alpha 1C77 splice variant of Cav1.2 (10, 11). In an extensive analysis involving deletions and point mutations in this region, Zühlke et al. described two short stretches operating in the inactivation process (12): a dipeptide NE present 60 residues on the C-side of the EF hand, and an octapeptide occurring 35 residues further downstream that resembles an IQ consensus sequence for Ca2+-independent calmodulin (CaM)1 binding (13). This sequence is now commonly referred as the IQ motif. Evidence that CaM binds to the IQ segment has been provided recently (14-16). This interaction is Ca2+-dependent with a 1:1 stoichiometry and occurs at Ca2+ concentrations above 100 nM. However, competition experiments with mutant CaMs defective in Ca2+ binding suggest that it is constitutively tethered to the channel (16). The actual domain of Cav1.2 responsible for constitutive binding of CaM is still unknown. Recently the IQ motif and CaM were shown to be involved in both facilitation and inactivation of the channel (17). An additional short sequence covering the critical NE dipeptide also binds CaM in a strictly Ca2+-dependent manner (18). The peptide, named CB by the authors, binds with a 1:1 stoichiometry. At 200 µM Ca2+, IQ was shown to compete efficiently with CB for CaM. Furthermore, these authors showed that injection of the CB peptide into cardiac myocytes promotes facilitation of the Ca2+ current, providing another clue to the CB involvement in the Ca2+-dependent inactivation process. More recently, Romanin et al. (19) showed that peptides containing the CB motif can bind to CaM at Ca2+ concentrations as low as 50 nM and that a short stretch on the N-side of CB directly binds Ca2+ with an affinity in the range of 100 nM. Incidentally, the CB peptide was first pointed out by Slavik et al. (20) for its ability to inhibit both binding of [3H]ryanodine and activity of the purified type-1 ryanodine receptor channel incorporated in planar lipid bilayers, suggesting that its function is not restricted to the Ca2+-dependent inactivation of L-type channels.

At present, these observations suggest that CB, but not IQ, should bind to CaM at Ca2+ concentrations corresponding to the resting state of the cell. However, both motifs would be able to bind at Ca2+ levels corresponding to local concentrations reached during the opening of the channel, although in a mutually exclusive fashion. This raises the question of the function of one of these motifs. If one considers the CaM interaction with the domain containing these two peptides as a Ca2+-triggered molecular switch, it is obvious that structural or functional elements still need to be assessed in order to provide a molecular description of its mechanism.

In the present report we show that CB and IQ are the only sequences of the C-terminal tail of Cav1.2 capable of interacting with CaM. We evaluated the affinity of CB for CaM and determined the threshold Ca2+ concentration for CaM interaction with CB and IQ alone and together. We demonstrate that CaM can form a ternary complex with IQ and CB at Ca2+ concentrations reached during the opening of the channel, provided the three partners have been allowed to interact first at low Ca2+ concentrations corresponding to the resting level of the cell. The present results suggest that the interaction of CaM with the IQ and CB motifs is sufficient for the formation of both a constitutive tethering and a minimal molecular switch leading to the Ca2+-dependent inactivation of L-type Ca2+ channels.

    EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Reagents-- Highly purified bovine brain calmodulin was either purchased from Calbiochem (La Jolla, CA) or was a generous gift from Dr. C. Lugnier (CNRS, Strasbourg, France). Streptavidin-coated sensor chips were purchased from Biacore AB (Uppsala, Sweden). N-terminally biotinylated CB and IQ peptides were synthesized and purified in the institute facility.

Fusion Protein Constructs-- The pF2 fusion construct was obtained in two steps. First, a sequence from a partial clone of rat Cav1.2 (sequence identical to GenBankTM accession no. M67515) was amplified by PCR with primers ACT.S (GAGGATCCATGGACAACTTTGACTACC) and ACT.AS (GTGATTCGGTGTCCGCTTGG), subcloned into the EcoRV site of pBluescript SK- for sequencing. Then, a BamHI/StuI fragment of 698 base pairs from this plasmid was subcloned in frame into BamHI/SmaI-digested pQE30 (Quiagen). This generated a 718-base pair product encoding a His6 fusion protein of the proximal C-terminal region of Cav1.2 (GenBankTM accession no. M67515, map position 4696-5370). The pF3 fusion construct was obtained by subcloning a StuI/SacI fragment of 972 base pairs from a partial clone of rat Cav1.2 (GenBankTM accession no. M67515, map position: 5371-6342) into the BamHI-blunted/SacI sites of pQE30. The pF4 fusion construct was realized in two steps: first, subcloning of the SacI/ApaI fragment from the C-terminal CaV1.2 partial clone in pBluescript SK-; and second, cloning of the SacI/KpnI digestion product in frame into pQE30 (GenBankTM accession no. M67515, map position 6343-6692). pF2Delta Delta was prepared from pF2 by three PCR amplifications with Pfx polymerase. First, two separate amplifications were made using the following couple of primers, C1/C2 (TGAGCGGATAACAATTTCACACAG)/(CTCTAGATCTGGCTTGCTCTAGGTTCCC)) and C3/C4 ((GAGGAGATCTGGTCGGCAAGCCCTC)/(TCCAGATGGAGTTCTGAGGTC)). The C1/C2 and C3/C4 PCR products were digested by BglII, ligated with phosphorylated primers C5 (GATCCGACCAGGTGGTGCCCCCTGCAGGTGATGACGAG) and C6 (GATCGAACTTGCCCACTGTGACCTCGTCATCACCT), respectively, and then repaired by Klenow polymerase. The two resulting fragments were mixed, amplified with primers C1/C4, digested with BamHI and HindIII, and cloned into the same sites of pQE30. Sequences of all constructs were checked, and fusion proteins were prepared in denaturing conditions according to the standard protocols of the QiaExpressionist kit (Qiagen). SDS-polyacrylamide gel electrophoresis and Coomassie Blue staining were used to check the apparent electrophoretic mobility and purity of the fusion proteins.

Real Time Surface Plasmon Resonance Recording-- Real time surface plasmon resonance (SPR) experiments were performed on a BIAcore 2000 biosensor system (Pharmacia Biosensor AB, Uppsala, Sweden). All experiments were performed at 25 °C with a constant flow rate of 20 µl/min. Synthetic peptides were directly coupled to a streptavidin-coated dextran matrix (SA sensor chip, Pharmacia Biosensor). The density of immobilized peptides on the sensor chip surface was 0.2 ng/mm2. Immobilization was monitored using SPR spectroscopy. Calmodulin was diluted in a buffer containing 10 mM HEPES, pH 7.4, 150 mM NaCl, 1 mg/ml CM-dextran, 0.005% surfactant P20 (running buffer), and 2 mM Ca2+ or 2 mM EGTA for binding and complete desorption of calmodulin, respectively. All experiments were run in triplicate and mean values ± S.D. are given. Nonspecific binding was evaluated in the same experiment by measuring binding to a surface saturated with biotin and subtracted automatically. Absence of CaM binding on a third control peptide was also monitored in parallel (data not shown).

Gel Shift Assays-- CaM (10 µM) was incubated with different molar ratios of IQ and CB peptides in a buffer containing 50 mM Tris-HCl (pH 7.4), 150 mM NaCl, and 1 mM CaCl2 or 2 mM EGTA for 30 min at room temperature. The bound complexes were then resolved by nondenaturing polyacrylamide gel electrophoresis on a 12% polyacrylamide gel in the presence of 2 mM CaCl2 or 5 mM EGTA. Proteins were revealed by Coomassie Blue staining.

Fluorescence-- Fluorescence studies were performed on a PTI fluorescence system equipped with the FelixTM digital acquisition and analysis software (Photon Technology International, Monmouth Junction, NJ). All measurements were performed at 25 °C in 3-ml, 1-ml, or 100-µl quartz cuvettes, taking care to use the same cuvette and instrumental for each set of experiments to be compared, in interaction buffer consisting of 50 mM MOPS, 130 mM NaCl, 1 mM EGTA, pH 7.4. The amount of CaCl2 added to set the pCa was computed using the buffer program that allows corrections for ionic strength, pH, and temperature (developed in the laboratory by Dr. J.-L. Rodeau). Ca2+ and CB titration were performed by successively adding small aliquots of appropriate CaCl2 or CB stocks, keeping the total volume of added solution to less than 3% of the initial volume. In this buffer, the pH drift induced by Ca2+ titration of EGTA was checked and shown to be less than 0.07 pH units over the buffering range of the chelator (pCa 8.2-5.8). Usually entire spectra were recorded in multiplicate (n = 3-4), buffer contribution was subtracted, and spectra were averaged where indicated. Numerical files from the recording were further analyzed and plotted using the SIGMAPLOT 4.0 for Windows software.

    RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Mapping of the Sequences from the C-terminal Domain of Cav1.2 Interacting with Calmodulin-- Two short motifs have been shown to be involved in the CaM-Ca2+-dependent inactivation of Cav1.2: CB (12, 18) and IQ (12, 14, 16) (see Fig. 1A), which display Ca2+-dependent interactions with CaM (14, 16). Using a biochemical approach to check if other domains of Cav1.2 participate in the CaM binding, we constructed His6-tagged fusion proteins covering the entire intracellular C-terminal region and analyzed their interaction with CaM in gel shift assays. From their charge distribution, all fusion proteins except PF4 were expected to migrate toward the cathode in their free form. When they are bound to CaM in a 1:1 ratio, the complexes were expected to migrate toward the anode along with free CaM but with different mobilities. As shown in Fig. 1B, when mixed in equimolar ratios, PF2 and CaM formed a complex of low mobility in the presence of 1 mM Ca2+. A concomitant decrease of free CaM was observed. We were unable to saturate CaM by raising the concentration of PF2, due to its limited solubility. Neither PF3 nor PF4 seemed to bind to CaM; PF3 did not enter the gel, and PF4 mobility was not affected. In agreement, the presence of these fusion proteins did not diminish the amount of free CaM. We checked that no motif of PF2 other than CB and IQ could interact with CaM by using PF2Delta Delta with both of these segments deleted. No interaction was observed, confirming biochemically previous electrophysiological studies showing that CB and IQ are the only determinants of the C-terminal domain of Cav1.2 participating to a Ca2+-dependent interaction with CaM (11, 19). In the absence of Ca2+ (2 mM EGTA), none of the fusion proteins bound to CaM (data not shown).


View larger version (28K):
[in this window]
[in a new window]
 
Fig. 1.   Interaction of fragments from the C-terminal cytoplasmic region of Cav1.2 with CaM. A, scheme depicting the structure of the C-terminal cytoplasmic region of Cav1.2 on the C-side of the fourth transmembrane domain (IV) and the positions of the EF-hand like structure (EF), the CB and IQ peptides. All map positions are assigned according to rat Cav1.2 sequence (GenBankTM accession no. M67515). Sequences of CB and IQ peptides used in this study are shown above (the CB sequence used here is the same as the CB-L-D peptide described previously (18) but does not contain the 11 residues on the N-side necessary for direct Ca2+ binding (19)). His6-tagged fusion proteins shown below are mapped onto the channel sequence. B, gel-shift experiments showing the interaction between the fusion proteins and CaM. Fusion proteins and CaM were incubated 30 min at a concentration of 10 µM for each partner in buffer containing 1 mM CaCl2 and run on non-denaturing 15% acrylamide gels in the presence of the same amount of Ca2+ in the running buffer and in the gel. Proteins were revealed by Coomassie Blue staining.

As reported previously (14, 16, 18), peptides CB and IQ bound to CaM with 1:1 stoichiometry in the presence of saturating Ca2+ concentrations (Fig. 2A) and no interaction was observed in 2 mM EGTA. When the ratio of CB to CaM was 2 or higher a complex of still lower mobility appeared, this could represent the binding of more than one peptide to CaM. Since incubations and electrophoresis were performed at rather high concentrations (at least 10 µM amounts of each partner), we concluded that nonspecific interactions happened due to our experimental set-up and did not characterize them further. Competition of CB and IQ for CaM binding displayed a major band comigrating with the complex CaM-IQ (Fig. 2B). A minor one of CB-CaM was sometimes observed. Manipulations of relative peptide ratios, provided they were both in excess to CaM, did not alter this pattern significantly (data not shown). This result is consistent with studies showing that a peptide containing the CB sequence, even in a 20-fold molar excess, is entirely displaced by IQ (18).


View larger version (50K):
[in this window]
[in a new window]
 
Fig. 2.   Interaction of peptides CB and IQ with CaM in the presence of 1 mM Ca2+. CaM (10 µM) was incubated with CB or IQ at the indicated peptide (Pep.)/CaM molar ratios and run on 15% non-denaturing polyacrylamide gels. A, stoichiometric interaction of CB and IQ with CaM. Both peptides interact with a 1:1 stoichiometry. Note the appearance of larger complexes of CB and CaM when CB is provided in large excess. B, competition of CB and IQ for binding to CaM. C, competition of CB or IQ with PF2 for binding to CaM. CaM and PF2 were both at 10 µM.

We performed competition experiments for both of these peptides with PF2 for Ca2+-dependent CaM binding at equimolar ratios (Fig. 2C). Both peptides effectively competed with PF2, as shown by the decrease in intensity of the PF2-CaM band. At this level of resolution, neither of the peptide seemed to be more effective than the other in displacing PF2. Moreover, the competitive effect of the two peptides did not appear to be additive.

Surface Plasmon Resonance-- Interactions between CaM and peptides CB and IQ were further studied by SPR spectroscopy. The biotinylated peptides were immobilized on streptavidin-coated sensor chips, and various CaM concentrations were run. Recorded SPR sensorgrams show that, in the presence of 2 mM Ca2+, CaM binds with fast kinetics to both peptides, displaying typical saturation curves (Fig. 3). The interactions are Ca2+-dependent since 2 mM EGTA readily reversed the interaction (data not shown). Determinations of the affinities yielded complex results. When analysis was performed using the plateau values of binding, it yielded Kd values of 349 ± 46 nM and 218 ± 22 nM for the interactions CaM-CB and CaM-IQ, respectively. However, kinetics of their association and dissociation indicated that these interactions are heterogeneous. The kon value of CaM-CB is in the range of 107 M-1 s-1, and the limitations of the analysis set-up did not allow to measure confidently on-rates higher than 106 M-1 s-1 (21). Moreover, dissociation rates could only be fitted with a minimum of two exponentials, with koff values of 0.024 and 0.33 s-1. Using a minimal kon of 106 M-1 s-1, upper limits of the Kd values were of 24 and 330 nM. For the CaM-IQ interaction, a kon of 5.0 × 105 M-1 s-1 and two koff values of 0.02 and 0.4 s-1 were obtained, yielding Kd of 40 and 400 nM, respectively. These latter values can be compared with results previously obtained in fluorescence studies for the dansyl-CaM- IQ interaction, yielding a Kd of 50 nM (17). Plasmon resonance spectroscopy indicated thus that two or more classes of binding sites, possibly interconvertible, exist when these short peptides are immobilized.


View larger version (28K):
[in this window]
[in a new window]
 
Fig. 3.   Quantitative analysis of CaM binding to CB and IQ peptides using SPR spectroscopy. Left panels, sensorgrams recorded with biotinylated synthetic peptides immobilized on SA sensor chips and CaM (15.6, 31.2, 62.5, 125, 250, 500, 1000, and 2000 nM) in BIAcoreTM. The immobilization density was 0.2 ng peptide/mm2. During recording, running buffer contained 2 mM Ca2+ (open bars) and CaM + 2 mM Ca2+ (filled bars). Right panels, saturating curves plotting response at plateau signal versus CaM concentration. Curves are fitted by an hyperbolic function. A, binding of CaM to IQ peptide, Kd = 218 ± 22 nM. B, binding of CaM to CB peptide, Kd = 349 ± 46 nM.

In order to obtain information on the interactions of CaM with IQ and CB and their Ca2+ dependence in solution without isolating the complexes, we turned to fluorescence spectroscopy, taking advantage of the distribution of tyrosine and tryptophan. CaM contains only two Tyr located both in the C-terminal lobe, IQ contains two Tyr, and CB a single tryptophan that has been shown to exhibit a blue-shift upon binding to CaM (18).

Dependence of the Formation of Complexes IQ-CaM on Ca2+ Concentration-- Fluorescence spectra of CaM and IQ at 1 µM each were recorded with excitation at 270 nm, first in 1 mM EGTA and then the concentration of Ca2+ was gradually increased (Fig. 4). In the absence of Ca2+, CaM alone displayed a faint fluorescence peak, consistent with the frequent quenching of tyrosines in proteins due to their interaction with nearby functional groups (22). When the Ca2+ concentration was raised, a sharp rise in quantum yield was observed in the region of pCa 6.4, indicative of cooperative binding of the first two Ca2+ to the high affinity C-terminal lobe bearing the two tyrosines. IQ alone displayed a typical Tyr spectrum independent of the Ca2+ concentration. When mixed together in the absence of Ca2+, CaM and IQ exhibited a peak at 304 nm, which was the sum of the spectra of the two species. However, a rise of fluorescence was observed in the region of pCa 6.4. This rise was 35% higher than what could be expected from the CaM transition alone. This indicates that an interaction between CaM and IQ indeed takes place at high Ca2+ concentrations.


View larger version (17K):
[in this window]
[in a new window]
 
Fig. 4.   Ca2+-dependent interaction of IQ and CaM measured by fluorescence emission of the tyrosines. IQ and CaM diluted to 1 µM in interaction buffer. Excitation wavelength, 270 nm; input and output slit, 1 nm; emission recorded between 286 and 400 nm by steps of 2 nm; integration time, 0.2 s. Spectra are averages of three recordings, and buffer contribution to the spectra was subtracted. A, spectra recorded in 1 mM EGTA and at pCa 3.5. Dashed line, CaM alone; thin line, IQ alone; thick line, CaM + IQ; dotted line, summation of the individual spectra from CaM and IQ alone. B, titration with Ca2+. Each point is the mean ± S.D. of three measurements. , CaM alone; , IQ alone; open circle , CaM + IQ.

Ca2+ Dependence of the CB-CaM Interaction-- The Ca2+-dependent interaction between CaM and CB, was monitored by recording spectra from the single tryptophan of CB. When excited at 295 nm, tyrosines do not absorb light and spectra of CaM and IQ were, as expected, virtually silent (Fig. 5, A and B). CB alone displayed a typical Trp peak at 346-348 nm. The mixture of CaM and CB in the absence of Ca2+ did not display any change in the fluorescence spectrum. When the Ca2+ concentration was increased, a sharp blue shift to 328 nm was observed with an increase in peak fluorescence between pCa 7 and pCa 6, indicating that the Trp of CB is placed in a more hydrophobic environment upon binding to CaM. Sample spectra are shown in Fig. 5A and a contour plot of all spectra recorded at different Ca2+ concentrations is shown in Fig. 5C. When recorded in the presence of IQ, the interaction between CaM and CB yielded less pronounced changes in the fluorescence spectra of Trp upon Ca2+ titration. During the transition between pCa 7 and pCa 6, a decrease in quantum yield and a small blue shift to 336 nm were observed (Fig. 5, B and D). Mixtures of CB and IQ in the absence of CaM did not exhibit any spectral changes upon Ca2+ titration (data not shown). Transitions of the CaM-CB interaction upon Ca2+ titration were compared in the presence and absence of IQ, using their 316/350 nm fluorescence ratio as an index of wavelength shift of the peak. As shown in Fig. 5E, the pCa of transition was the same in the presence and absence of IQ.


View larger version (35K):
[in this window]
[in a new window]
 
Fig. 5.   Ca2+-dependent interactions of CB and CaM in the presence and absence of IQ measured by fluorescence of the tryptophan. CB, CaM, and IQ were diluted in interaction buffer to final concentrations of 1 µM. Excitation wavelength 295 nm; input and output slit, 1 nm; emission spectra recorded between 310 and 450 nm by steps of 2 nm; integration time, 0.2 s. Spectra are averages of three recordings, buffer contribution was subtracted. A, sample spectra of an equimolar mix of CaM and CB at different Ca2+ concentrations: thin line, 1 mM EGTA; dashed line, pCa 7; thick line, pCa 3.5; open circles, CaM alone in 1 mM EGTA; dots, CB alone in 1 mM EGTA. B, sample spectra of an equimolar mix of CaM, CB, and IQ at different Ca2+ concentrations: thin line, 1 mM EGTA; dashed line, pCa 6.7; thick line, pCa 3.5; open circles, CaM + IQ in the absence of CB in 1 mM EGTA. C, contour plot showing the evolution of the spectra of CaM + CB with increasing Ca2+ concentrations. Contour lines are interpolations of isoemissive points from the spectra expressed in photons/s × 10-4; arrows on the right indicate the sampling of spectra used to construct the plot. D, contour plot of the spectra of CaM + CB + IQ as a function of Ca2+ concentration. E, measurement of the Ca2+-induced blue-shift of interacting CB and CaM in the presence and absence of IQ. In order to directly compare the transitions observed in the presence and absence of IQ, the ratio of fluorescence emission 316/350 nm was plotted versus Ca2+ concentration. Each data point represents the mean ± S.D. of three recordings. open circle , CaM + CB in the absence of IQ; , CaM + CB in the presence of IQ; , CB alone. Curves were obtained using either a non-linear four-parameter sigmoid fitting program or a linear regression.

Titration of CaM with CB-- CaM (1 µM) was titrated with increasing amounts of CB at a concentration of Ca2+ above the transition. In this experiment, excitation was performed at 270 nm and fluorescence recorded at 320 nm, since we observed that the fluorescence of the complex is more intense when tyrosines are excited (data not shown). This is most probably due to fluorescence energy transfer between one of the Tyr of CaM and the Trp of CB. As shown in Fig. 6A, this titration is biphasic; the fluorescence rises sharply below the equimolar concentration. When CB is present in excess, this increase is linear and parallels the fluorescence of CB alone. Regression analysis showed that, above the equimolar point, CaM plus excess CB displays a slope identical to that of CB alone. This indicates that CaM and CB form a 1:1 complex with a Kd well below the micromolar range. The titration was repeated at 0.1 µM CaM, corresponding to the lowest limit for obtaining a reasonable signal. We plotted the data by first subtracting to each point the signal of CaM alone and the signal of equal amounts of CB alone and then by normalizing the saturation, generating the binding profile shown in Fig. 6B. This manipulation is legitimate if one assumes that the total fluorescence signal is a linear combination of the individual signals of the mixed species, complexes, and free fluorophores. This condition is fulfilled when inner filter effects are negligible, which is the case here, as indicated by the linearity of the fluorescence increase even at concentrations well above the measurement range. The data points were fitted with an equation assuming a 1:1 binding (see legend to Fig. 6) and yielded a Kd of 12.4 ± 2.8 nM (r = 0.98), 1 order of magnitude lower than the value obtained from the plateau values of Biacore experiments but in agreement with the high affinity site characterized by kinetic-derived values.


View larger version (15K):
[in this window]
[in a new window]
 
Fig. 6.   Binding of CB to CaM at pCa 3.5. CaM was diluted at the indicated concentration in interaction buffer set to pCa 3.5, and increasing amounts of CB were successively added in small aliquots. Excitation was at 270 nm, and emission was recorded at 320 nm. Each point is the mean ± S.D. of three recordings and buffer contribution has been subtracted. A, CaM 1.0 µM, emission plotted versus total CB concentration: , CB in the presence of 1.0 µM CaM, linear regression below 1.2 µM CB yielded a slope of 1.03 × 105 (r = 0.998) and above 1.2 µM, a slope = 6.04 × 104 (r = 0.997); , CB alone; linear regression: slope = 5.98 × 104 (r = 0.999). B, CaM 0.1 µM, binding curve as a function of total CB concentration. The contribution of CaM and the emission of free CB at the same concentration were subtracted for each individual point. Values were normalized assuming that saturation is complete above 1.2 µM CB. Thick line, data points were fitted with the equation relating bound CB (Lb) to the total concentrations of CaM (C) and CB (L): Lb = 1/2{(Kd + L + C) -[(Kd + L + C)2 - 4LC]0.5} and yielded a Kd of 12.4 ± 2.8 nM.

In the Presence of IQ, the Complex of CB with CaM at High Ca2+ Concentrations Depends on Interactions at Low Ca2+-- Unexpectedly, when we tried to record titrations of CaM with CB in the presence of IQ at high Ca2+ concentrations, fluorescence spectra did not display any blue-shift of the Trp peak. We also consistently observed an absence of blue shift after mixing of CaM, CB, and IQ above pCa 6.5. As these results seemed to contradict the Ca2+ titration experiments shown in Fig. 5, we suspected that the binding of CB to CaM in the presence of IQ might require an initial interaction at low Ca2+ concentration. In view of the emerging consensus that CaM should be intrinsically bound in the neighborhood of the C-terminal region of Cav1.2 (16), it seemed logical to assume that during biosynthesis CaM associates with the channel at the resting Ca2+ concentration of the cytoplasm, i.e. below or around pCa 7. In order to check this hypothesis, we applied a three-step protocol consisting in the mixture of equimolar amounts of CaM, CB, and IQ in interaction buffer containing 1 mM EGTA. Spectra were recorded, and then pCa was adjusted to 7.0 for fluorescence recording and finally set to 3.5, corresponding approximately to the Ca2+ level reached during channel opening. As shown in Fig. 7, Trp displayed a marked blue shift in fluorescence to 336 nm at high Ca2+ concentration. When the peptides and CaM were directly diluted in buffer at pCa 3.5, this blue shift was not observed. Both protocols were repeated several times (n = 7 for the three step protocol and n = 3 for the direct dilution at pCa 3.5) and yielded consistent results. It indicates that the initial interaction, although not visible in fluorescence, must take place at low Ca2+ in order to observe a binding of CB above pCa 6.5. The observation of a decrease in fluorescence intensity at pCa 7.0 favors this interpretation (Fig. 7). However, when IQ was absent, a fluorescence blue shift of CB upon interaction with CaM readily takes place at pCa 3.5, and did not require a preliminary interaction at lower Ca2+ concentration (data not shown). Making a titration of CaM with CB in the presence of IQ proved to be unfeasible, due to the complexity of the protocol involved and the large interference of IQ fluorescence with the titration, generating poor signal/noise ratios. In order to evaluate the proportion of CB involved in the interaction, we compared the shape of the fluorescence spectrum of Trp at pCa 3.5 obtained using the three-step protocol with the spectrum observed in the absence of Ca2+. This was done by normalizing both spectra to their peak value and shifting them along the wavelength axis in order to superimpose their peaks. If CB distributed between an interacting pool and a free pool, one would expect to observe a significant spreading of the spectrum at pCa 3.5. As shown in the inset of Fig. 7, both peaks are superimposable, indicating that the majority of CB interacts with CaM. The spectra of the CB-CaM complexes in the absence and presence of IQ differed significantly in terms of quantum yield and amplitude of the blue shift (see Fig. 5), and the interaction of CB with CaM is quantitative both in absence and presence of IQ. Thus, we can deduce that a ternary complex CaM-CB-IQ is formed at high Ca2+ concentration, and that this complex mimics the interaction of CaM with the C-terminal region of Cav1.2 during Ca2+ inactivation of the channel. When applying the three-step protocol to gel-shift experiments, we did not find any other complexes except those shown in Fig. 2B.


View larger version (19K):
[in this window]
[in a new window]
 
Fig. 7.   Dependence of CaM-CB complex formation in the presence of IQ when preincubated at low Ca2+ concentration. Samples were excited at 295 nm, and fluorescence spectra were recorded between 310 and 450 nm. The three-step protocol consisted of mixing CaM, CB, and IQ, each at 1 µM final concentration, into interaction buffer in the absence of Ca2+. Three spectra were recorded and averaged (thick solid line), and then pCa was adjusted to 7 and another set of spectra recorded (dotted line); then pCa was adjusted to 3.5 and spectra recorded (dashed line). Usually, 5 min elapsed between the recordings, although longer incubations did not change the fluorescence signal. The single-step protocol consisted of mixing CaM, CB, and IQ directly in interaction buffer adjusted to pCa 3.5 (thin solid line). Inset, the spectra of the mixed peptides at zero Ca2+ and at pCa 3.5 as obtained from the three-step protocol were normalized and shifted in order to superimpose their peak value: line, normalized spectrum obtained in the absence of Ca2+; small circles, normalized spectrum obtained at pCa 3.5 and shifted 10 nm toward longer wavelength.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Recent work has provided new insights to our understanding of Ca2+ inactivation of L-type Ca2+ channels, in particular characterization of their molecular determinants. The Ca2+ effect has been shown to be triggered by CaM, which binds to a 20 residues long IQ motif (14) of the C-terminal tail of Cav1.2. CaM has also been shown to bind to the CB motif in a Ca2+-dependent way (18), at relatively low concentrations of this divalent ion (19). Isolation of the complexes in gel-shift experiments indicated that the association of CaM with CB does not occur if IQ is present. Therefore, the role of CB remains enigmatic. More recently, a Ca2+ binding site has been described on the N-side of CB (19). Here we have reexamined the interaction of CaM with the CB and IQ motifs of Cav1.2, using three independent experimental approaches. Gel-shift experiments allowed isolation of complexes, whereas SPR gave access to kinetic parameters of these interactions, and fluorescence spectroscopy provided information on the complexes at equilibrium.

We first confirmed previous studies (14-16, 18, 19) in gel-shift experiments showing that CaM binds with CB or IQ in the presence of saturating concentration of Ca2+ and demonstrated that it cannot bind to other motifs of the C-terminal tail of Cav1.2. As noted previously (18), when CB and IQ were allowed to bind to CaM simultaneously, the CaM-IQ complex was the predominant species, suggesting a competitive binding of the two peptides. In the absence of Ca2+, no complexes of CaM with either the peptides or the fusion protein PF2 were observed, although Romanin et al. (19) showed that under certain circumstances, presumably depending on folding or removal of bound Ca2+, a fusion protein similar to PF2 binds to CaM in the absence of Ca2+. Gel-shift experiments present several drawbacks in analyzing these complexes that needed to be addressed. Firstly, migrations in native gels depend on both net charge and Stoke's radius of the species, and comigration of complexes of different compositions cannot be excluded when using a single condition of migration. However, using gels of porosities varying from 7.5% to 20% acrylamide, we obtained consistent results confirming the homogeneity of the observed bands. A second point concerns the stability of the isolated complexes. As the free peptides migrate in the opposite direction, a rapid dissociation rate could prevent the observation of a complex existing at equilibrium. Another inconvenience is due to the technical difficulties in controlling the Ca2+ concentration in a medium of varying ionic strength, pH, and temperature during the migration. To circumvent these last two points, other technical approaches were necessary. We therefore turned to SPR in order to precise the binary interactions between CaM and the peptides. Although binding occurred in the presence of saturating Ca2+ levels, measurement of binding affinities yielded complex results. Kinetics analyses showed that on-rates are high and off-rates are heterogeneous, suggesting that more than one class of binding site occurs when peptides are immobilized. For the CaM-IQ interaction, the lower value of Kd (40 nM) is consistent with published results (50 nM; Ref. 17). A first approximation of the CaM-CB interaction yielded a Kd below 24 nM, and a precise value of 12 nM was obtained by fluorescence spectroscopy. It is worth noting that CB displays a 4-fold higher affinity for CaM than IQ at high Ca2+ and that the interaction kinetics are rapid for both peptides. If their binding to CaM were competitive, one would expect, in contradiction to the gel-shift results, that the formation of CaM-CB would be favored when the three partners are allowed to interact simultaneously. We concluded that the ternary interaction is more complex than a simple competitive binding to CaM and may involve conformational transitions that are not evident in gel-shift analysis. Actually, the fluorescence study at equilibrium showed that a ternary complex CaM-CB-IQ is formed at high Ca2+ concentration.

We studied the Ca2+ dependence of the binary interaction between CaM and the peptides and that of the ternary complex CaM-CB-IQ. All interactions displayed a marked cooperative transition in spectral properties between pCa 7.0 and pCa 6.0 and these transitions occurred at the same Ca2+ concentration as the spectral change of CaM alone upon binding of two Ca2+ to the C-terminal lobe. Two caveats apply to the interpretation of these results. First, one must bear in mind that, if changes in fluorescence signal arising from mixing of two or more components are a clue to an interaction, an absence of signal modification does not necessarily imply that the molecules do not interact with each other. It only means that the local environment of the probing aromatic residue is unaffected. Thus, rather than interpreting spectral changes as true bindings of peptides to CaM, we prefer to express them as transitions that could possibly be transconformations of preexisting "invisible" complexes. A second restriction is related to well known observations showing that the Ca2+-dependent binding of peptides enhances cooperatively the affinity of CaM for Ca2+ (23-27). If a single lobe of CaM is preferentially involved in the binding of one or the other of the peptides, its Ca2+ binding properties could be affected and consequently the observed transition may not be directly related to the CaM domain. The use of mutant CaMs, which are unable to bind Ca2+ on one or the other of their lobes, should resolve this issue.

Under physiological conditions, estimated Ca2+ basal levels range between 40 and 70 nM Ca2+, Ca2+-activated small conductance K+ channels open in the range of 0.1-1 µM (28, 29) and transmitter release requires at least 10 µM Ca2+ (30). The Ca2+ IC50 of Cav1.2 has been estimated to be around 400 nM in smooth muscles (31) and 4 µM in cardiac cells (32). The large Ca2+ concentrations instantaneously attained upon photolysis of Ca2+ caging DM-nitrophen lead to inactivation of Cav1.2 (4), whereas the smaller Ca2+ concentration probably attained upon photolysis of Ca2+ caging nitr-5 gives rise to a facilitation (6), although precise measurements of Ca2+ concentration could not be achieved. Thus, our observation of consistent fluorescence transitions around pCa 6.5 are compatible with an activation process taking place during Ca2+ channel opening.

Interestingly, the ternary complex can be formed only if the three partners have been first allowed to interact at low Ca2+. This implies that a complex should exist at Ca2+ concentrations below the transition, although we could not visualize it experimentally, and that it is a prerequisite for the formation of the ternary complex above this Ca2+ concentration. This view is supported by the finding that a fusion protein containing the two motifs can bind to CaM in the absence of Ca2+ and that peptides analogue to CB bind to CaM at 50 nM Ca2+ (19). Since mutated CaMs, which are unable to bind Ca2+ on more than one of their binding sites, exerted a dominant negative effect leading to a loss of Ca2+ inactivation, CaM is most likely constitutively associated with the channel (14, 16, 17). Moreover, the Ca2+-induced inactivation is a fast process requiring less than 7 ms (4), suggesting that free CaM diffusing and binding could not easily account for these kinetics. Since interactions of CaM with the IQ or the CB motifs at first appeared strictly Ca2+-dependent, some authors postulated that the constitutive site should be located in other domains of the channel (16). The possible existence of a CaM-peptide complex below the Ca2+-induced transition level, as inferred from our results, suggests the possibility that either CB or IQ motif, or a combination of both as a covalently connected sequence, constitutes the attachment point of CaM to the channel. In summary, our results show that a combination of CaM and the two motifs CB and IQ displays the essential features of a minimal Ca2+-induced molecular switch. When placed in the context of the whole channel, the initial rearrangement of the CaM-CB-IQ interaction is linked to features that need to be further evaluated. An additional factor is certainly the recently described calcium sensor domain lying on the N-side of CB (19), which has not been addressed here. This region directly binds Ca2+ without impairing CaM binding and has been shown to partly contribute to the Ca2+ dependence of inactivation. The influence of the covalent connection of these motifs in a single polypeptide also needs to be assessed. Subsequent domain movements acting in a relay system, which eventually obstructs the pore, are probably involved. A good candidate for a place in this relay would be the EF-hand-like domain, which is essential for inactivation but does not yet find a place in the switch process (9). Other relaying candidates are suggested by recent observations, demonstrating that the inactivation process involves the I-II intracellular loop and associated beta  subunit for both Cav1.2 and Cav2.1 (33-35). These results suggest that voltage-dependent and Ca2+-dependent inactivations involve common relays. In this frame, a chain of events involving several cytoplasmic domains could contribute to Cav1.2 channel blockade (31). Once the Ca2+-induced CaM-CB-IQ ternary interaction has occurred, the C-terminal tail could act in synergy with the I-II loop. Alternatively, the C-terminal switch domain may keep the channel activatable in basal conditions by protecting the pore from the blocking effect of the other cytoplasmic loops and upon Ca2+ binding adopt a distinct conformation leading to a more conventional voltage-dependent inactivation. In support of this latter hypothesis are several observations showing that deletions (12, 36) or mutations (10, 11, 14), which alter the CB-IQ region of Cav1.2 and cause Ca2+ insensitivity, enhance clearly the inactivation, when Ba2+ is used as the permeant ion, rather than suppressing inactivation altogether. When determined, the IBa inactivation kinetics of these variants has been shown to be strongly voltage-dependent (10, 11), leading to the emerging idea that Ca2+ channels subject to Ca2+-dependent or voltage-dependent inactivations are closed by a common mechanism.

    ACKNOWLEDGEMENTS

We thank T. Tahouly for technical assistance in preparing the plasmid constructs and fusion proteins, Dr. A. Janoshazi for providing easy access to the fluorescence spectroscopy facility, Dr. C. Lugnier for providing purified calmodulin, and Dr. N. Grant-Takeda for help in the correction of the manuscript.

    FOOTNOTES

* This work was supported by the CNRS and by a doctoral fellowship from the Ministère de l'Education Nationale de la Recherche et de la Technologie attributed to J. Mouton.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger To whom correspondence should be addressed. Tel.: 33-388-45-66-34; Fax: 33-388-60-16-64; E-mail: maulet@neurochem.u-strasbg.fr.

Published, JBC Papers in Press, April 9, 2001, DOI 10.1074/jbc.M100755200

    ABBREVIATIONS

The abbreviations used are: CaM, calmodulin; PCR, polymerase chain reaction; SPR, surface plasmon resonance spectroscopy; MOPS, 3-(N-morpholino)propanesulfonic acid; dansyl, 5-dimethylaminonaphthalene-1-sulfonyl.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

1. Eckert, R., and Chad, J. E. (1984) Prog. Biophys Mol. Biol. 44, 215-267[CrossRef][Medline] [Order article via Infotrieve]
2. Morad, M., Davies, N. W., Kaplan, J. H., and Lux, H. D. (1988) Science 241, 842-844[Medline] [Order article via Infotrieve]
3. Plant, T. D., Standen, N. B., and Ward, T. A. (1983) J. Physiol. (Lond.) 334, 189-212[Abstract]
4. Hadley, R. W., and Lederer, W. J. (1991) J. Physiol. (Lond.) 444, 257-268[Abstract]
5. Zygmunt, A. C., and Maylie, J. (1990) J. Physiol. (Lond.) 428, 653-671[Abstract]
6. Gurney, A. M., Charnet, P., Pye, J. M., and Nargeot, J. (1989) Nature 341, 65-68[CrossRef][Medline] [Order article via Infotrieve]
7. De Leon, M., Wang, Y., Jones, L., Perez-Reyes, E., Wei, X., Soong, T. W., Snutch, T. P., and Yue, D. T. (1995) Science 270, 1502-1506[Abstract]
8. Zhou, J., Olcese, R., Qin, N., Noceti, F., Birnbaumer, L., and Stefani, E. (1997) Proc. Natl. Acad. Sci. U. S. A. 94, 2301-2305[Abstract/Free Full Text]
9. Peterson, B. Z., Lee, J. S., Mulle, J. G., Wang, L., de Leon, M., and Yue, D. T. (2000) Biophys. J. 78, 1906-1920[Abstract/Free Full Text]
10. Soldatov, N. M., Zühlke, R. D., Bouron, A., and Reuter, H. (1997) J. Biol. Chem. 272, 3560-3566[Abstract/Free Full Text]
11. Soldatov, N. K., Oz, M., O'Brien, K. A., Abernethy, D. R., and Morad, M. (1998) J. Biol. Chem. 273, 957-963[Abstract/Free Full Text]
12. Zühlke, R. D., and Reuter, H. (1998) Proc. Natl. Acad. Sci. U. S. A. 95, 3287-3294[Abstract/Free Full Text]
13. Rhoads, A. R., and Friedberg, F. (1997) FASEB J. 11, 331-340[Abstract/Free Full Text]
14. Zühlke, R. D., Pitt, G. S., Deisseroth, K., Tsien, R. W., and Reuter, H. (1999) Nature 399, 159-162[CrossRef][Medline] [Order article via Infotrieve]
15. Qin, N., Olcese, R., Bransby, M., Lin, T., and Birnbaumer, L. (1999) Proc. Natl. Acad. Sci. U. S. A. 96, 2435-2438[Abstract/Free Full Text]
16. Peterson, B. Z., DeMaria, C. D., Adelman, J. P., and Yue, D. T. (1999) Neuron 22, 549-558[Medline] [Order article via Infotrieve]
17. Zühlke, R. D., Pitt, G. S., Tsien, R. W., and Reuter, H. (2000) J. Biol. Chem. 275, 21121-21129[Abstract/Free Full Text]
18. Pate, P., Mochca-Morales, J., Wu, Y., Zhang, J. Z., Rodney, G., Serysheva, I., Williams, B. Y., Anderson, M. E., and Hamilton, S. L. (2000) J. Biol. Chem. 275, 39786-39792[Abstract/Free Full Text]
19. Romanin, C., Gamsjaeger, R., Kahr, H., Schaufler, D., Carlson, O, Abernethy, D. R., and Soldatov, N. M. (2000) FEBS Lett. 487, 301-306[CrossRef][Medline] [Order article via Infotrieve]
20. Slavik, K. J., Wang, J. P., Aghdasi, B., Zhang, J. Z., Mandel, F., Malouf, N., and Hamilton, S. L. (1997) Am. J. Physiol. 272, C1475-C1481[Abstract/Free Full Text]
21. Hall, D. R., Cann, J. R., and Winzor, D. J. (1996) Anal. Biochem. 235, 175-184[CrossRef][Medline] [Order article via Infotrieve]
22. Lakowicz, J. R. (1983) Principles of Fluorescence Spectroscopy , pp. 341-379, Plenum Publishing Corporation, New York
23. Maulet, Y., and Cox, J. A. (1983) Biochemistry 22, 5680-5686[Medline] [Order article via Infotrieve]
24. Olwin, B. B., and Storm, D. R. (1985) Biochemistry 24, 8081-8086[Medline] [Order article via Infotrieve]
25. Yazawa, M., Ikura, M., Hikichi, K., Ying, L., and Yagi, K. (1987) J. Biol. Chem. 262, 10951-10954[Abstract/Free Full Text]
26. Yazawa, M., Vorherr, T., James, P., Carafoli, E., and Yagi, K. (1992) Biochemistry 31, 3171-3176[Medline] [Order article via Infotrieve]
27. Martin, S. R., Bayley, P. M., Brown, S. E., Porumb, T., Zhang, M., and Ikura, M. (1996) Biochemistry 35, 3506-3517
28. Lang, D. G., and Ritchie, A. K. (1987) Pflügers Arch. 410, 614-622[Medline] [Order article via Infotrieve]
29. Capiod, T., and Ogden, D. C. (1989) J. Physiol. (Lond.) 409, 285-295[Abstract]
30. Schneggenburger, R., and Neher, E. (2000) Nature 406, 889-893[CrossRef][Medline] [Order article via Infotrieve]
31. Schuhmann, K., Romanin, C., Baumgartner, W., and Groschner, K. (1997) J. Gen. Physiol. 110, 503-513[Abstract/Free Full Text]
32. Hofer, G. F., Hohenthanner, K., Baumgartner, W., Groschner, K., Klugbauer, N., Hofmann, F., and Romanin, C. (1997) Biophys. J. 73, 1857-1865[Abstract]
33. Cens, T., Restituito, S., Galas, S., and Charnet, P. (1999) J. Biol. Chem. 274, 5483-5490[Abstract/Free Full Text]
34. Cens, T., Restituito, S., and Charnet, P. (1999) FEBS Lett. 450, 17-22[CrossRef][Medline] [Order article via Infotrieve]
35. Restituito, S., Cens, T., Barrere, C., Geib, S., Galas, S., De Waard, M., and Charnet, P. (2000) J. Neurosci. 20, 9046-9052[Abstract/Free Full Text]
36. Klöckner, U., Mikala, G., Varadi, M., Varadi, G., and Schwartz, A. (1995) J. Biol. Chem. 270, 17306-17310[Abstract/Free Full Text]


Copyright © 2001 by The American Society for Biochemistry and Molecular Biology, Inc.