Demonstration of Binding of Neuronal Calcium Sensor-1 to the Cav2.1 P/Q-Type Calcium Channel

In neurons, entry of extracellular calcium (Ca2+) into synaptic terminals through Cav2.1 (P/Q-type) Ca2+ channels is the driving force for exocytosis of neurotransmitter-containing synaptic vesicles. This class of Ca2+ channel is, therefore, pivotal during normal neurotransmission in higher organisms. In response to channel opening and Ca2+ influx, specific Ca2+-binding proteins associate with cytoplasmic regulatory domains of the P/Q channel to modulate subsequent channel opening. Channel modulation in this way influences synaptic plasticity with consequences for higher-level processes such as learning and memory acquisition. The ubiquitous Ca2+-sensing protein calmodulin (CaM) regulates the activity of all types of mammalian voltage-gated Ca2+ channels, including the P/Q class, by direct binding to specific regulatory motifs. More recently, experimental evidence has highlighted a role for additional Ca2+-binding proteins, particularly of the CaBP and NCS families in the regulation of P/Q channels. NCS-1 is a protein found from yeast to humans and that regulates a diverse number of cellular functions. Physiological and genetic evidence indicates that NCS-1 regulates P/Q channel activity, including calcium-dependent facilitation, although a direct physical association between the proteins has yet to be demonstrated. In this study, we aimed to determine if there is a direct interaction between NCS-1 and the C-terminal cytoplasmic tail of the Cav2.1 α-subunit. Using distinct but complementary approaches, including in vitro binding of bacterially expressed recombinant proteins, fluorescence spectrophotometry, isothermal titration calorimetry, nuclear magnetic resonance, and expression of fluorescently tagged proteins in mammalian cells, we show direct binding and demonstrate that CaM can compete for it. We speculate about how NCS-1/Cav2.1 association might add to the complexity of calcium channel regulation mediated by other known calcium-sensing proteins and how this might help to fine-tune neurotransmission in the mammalian central nervous system.

Ca v 2.1 P/Q-type channels are responsible for the entry of Ca 2+ into synaptic terminals in many brain regions. 1 P/Q-type function is therefore pivotal in the regulation of neurotransmitter release and communication throughout the central nervous system (CNS). Indeed, mutations in the gene encoding the human P/Q α 1 subunit are responsible for a number of clinically relevant neurological disorders. 2 An interesting feature of many Ca v proteins (Ca v 1.x and Ca v 2.x), including the P/Q channel, is that channel activity is itself regulated by Ca 2+ . 3 Ca 2+ -dependent channel modulation manifests as two distinct phenomena termed Ca 2+ -dependent inactivation (CDI) 4 and Ca 2+ -dependent facilitation (CDF). 5 CDI represents a mechanism by which channels become refractory to further opening in the presence of a sustained stimuli, whereas CDF manifests as the opposite process whereby Ca 2+ augments channel currents. 6 Specific Ca 2+binding proteins can respond to the entry of Ca 2+ through Ca v channels by interacting directly with regulatory motifs present in the intracellular domains of the α-subunit. 7−10 These interactions, by currently poorly understood mechanisms, alter channel behavior to elicit either CDI or CDF. CDI and CDF both have a direct impact on synaptic neurotransmitter release, the strength of synaptic signaling, and ultimately synaptic plasticity. Understanding the basic modes of Ca v regulation at the molecular level therefore generates insights into more abstract, higher-level, processes, including learning, memory acquisition, and reasoning.
Of the characterized Ca 2+ -binding proteins that control Ca v activity, the ubiquitous small EF-hand-containing protein calmodulin (CaM) has been most intensively studied. CaM has been shown to interact with a consensus isoleucineglutamine "IQ" motif present in the carboxy terminus of the channel, although the precise details of the interaction differ for Ca v 1.x and Ca v 2.x subtypes. 11,12 A second Ca 2+ -dependent CaM-binding motif immediately C-terminal to the IQ domain has also been characterized in Ca v 2.1 P/Q-type channels. 13 This CaM-binding domain (CBD) has been found to influence P/Q channel activity in some studies 13 but not others, 7 and its true significance remains somewhat controversial.
A number of CaM-related Ca 2+ -binding proteins are enriched in the mammalian CNS and have been found to modulate the properties of Ca v channels. In all instances thus far characterized, channel regulation is distinct from that observed with CaM, suggesting nonredundant functions that have been thought to permit complex modes of channel regulation and neuronal signaling. 12 At present, two CaM-related Ca 2+ -binding proteins, Ca 2+ -binding protein-1 (CaBP1) and visinin-like protein-2 (VILIP-2), have been shown to directly interact with P/Q-type α-subunits to exert unique regulatory outcomes. 10,14 Large numbers of additional CaM-related small EFhand-containing proteins are also expressed in the mammalian CNS. Neuronal Ca 2+ sensor-1 (NCS-1) is a CaM-related protein that is evolutionarily conserved from yeast to humans 15 and has been implicated in specific human neuronal disorders. 16−19 Evidence of a regulatory role of NCS-1 on P/ Q-type channels has been reported on the basis of physiological experiments in mammalian cells, including an effect on CDF, 20−22 and a genetic study in Drosophila, 23 although no direct interaction between the two proteins has thus far been demonstrated.
In this paper, we aimed to use exclusive yet complementary analytical methods to rigorously determine if there is a direct interaction between NCS-1 and the α-subunit of the P/Q-type channel and to provide the first evidence of an interaction between a defined region of the C-terminal domain of the P/Q α-subunit and NCS-1. We show that a segment of the P/Q αsubunit encoding the IQ motif and CBD interacts with NCS-1 in a Ca 2+ -dependent manner. Using mutagenesis and NMR experiments, we further refine the NCS-1-binding site to the IQ motif and show that the interaction is competitive with CaM. We provide further evidence using an ex vivo HeLa cell model that NCS-1 and the C-terminal tail of Ca v 2.1 interact. These novel observations expand the repertoire of P/Q-type interacting proteins and add to the potential variety of modes by which such channels can be controlled.
Cell Culture and Plasmid Transfections. HeLa cells were cultured in DMEM supplemented with 10% (v/v) fetal bovine serum, 1% (v/v) penicillin/streptomycin, and 1% (v/v) nonessential amino acids. All cells were maintained in a humidified 95% air/5% CO 2 atmosphere at 37°C. Cells were plated onto sterile 13 mm round coverslips at a density of 0.25 × 10 6 cells/well. After 24 h, cells were transiently transfected with the indicated expression vectors using GeneJuice transfection reagent (Novagen) according to the manufacturer's protocol. For single and double transfections, 1 μg of each plasmid was used.
Cell Fixation and Confocal Imaging Analysis. Twentyfour hours post-transfection, cells on coverslips were washed with phosphate-buffered saline [137 mM NaCl, 2.7 mM KCl, 10 mM Na 2 PO 4 , and 2 mM NaH 2 PO 4 (pH 7.4)] and then fixed with 4% (v/v) formaldehyde in PBS for 6 min at room temperature. Coverslips were subsequently air-dried and mounted onto microscope slides using Prolong antifade glycerol (Life Technologies). Fixed cells were imaged using a Leica TCS-SP2 confocal system (Leica Microsystems, Heidelberg, Germany) with a pinhole set to 1 Airy unit and a 63× oil immersion objective with a numerical aperture of 1.3. Images were exported as TIFF files and compiled, processed, and analyzed with ImageJ and CorelDraw X6 applications.
In Vitro Binding Assays. For the In vitro protein binding assays, 5 μM GST fusion protein (GST-P/Q, GST-P/Q IM→EE , or GST-CBD) was immobilized onto 30 μL of glutathioneagarose resin (Thermo Scientific) that had been prewashed in binding buffer (BB) [150 mM KCl, 20 mM HEPES (pH 7.4), 10% (v/v) glycerol, 5 mM NTA, 5 mM EGTA, 1 mM DTT, and 0.1% (v/v) NP-40] or BB supplemented with 1 μM free Ca 2+ (BB+Ca 2+ ) by incubation for 30 min with constant agitation at 4°C. GST-free NCS-1 and CaM were added to samples at concentrations of 5 μM (total final binding assay volumes of 100 μL) and incubations continued for 1 h with constant agitation at 4°C. For competition binding assays, 5 μM GST-P/Q was prebound to glutathione-agarose resin in BB +Ca 2+ by incubation for 30 min at 4°C with constant agitation; 5 μM NCS-1 was then added to samples in the presence of increasing concentrations of CaM ranging from 0 to 10 μM. Binding reactions were continued for 1 h at 4°C while the mixtures were constantly agitated. For the Ca 2+ dose dependency of the NCS-1/GST-P/Q interaction, 1 μM GST-P/Q was incubated with 1 μM NCS-1 in the presence of increasing concentrations of free Ca 2+ . For all binding assays, glutathioneagarose pellets were collected by centrifugation (3000 rpm for 1 min at 4°C) and washed three times with 1 mL of BB or BB +Ca 2+ and bound proteins were extracted by boiling of final bead pellets for 5 min in 50 μL of SDS dissociation buffer [125 mM HEPES (pH 6.8), 10% (w/v) sucrose, 10% (v/v) glycerol, 4% (w/v) SDS, 1% (v/v) β-mercaptoethanol, and 2 mM EDTA]. Proteins were resolved on 4 to 12% Tris-glycine gradient gels (Novex, Life Technologies) and transferred to nitrocellulose membranes for Western blotting by transverse electrophoresis.
Western Blots. Nitrocellulose filters were blocked by incubation in a blocking solution [3% (w/v) skim milk powder in PBS] for 1 h at room temperature. Filters were subsequently incubated with a primary antibody [rabbit anti-NCS-1 (1:1000 26 ) or rabbit anti-calmodulin (1:500) (AbCam)] diluted in a blocking solution overnight at 4°C with constant agitation. Filters were washed three times in PBS supplemented with 0.05% (v/v) Tween 20 (PBST) and twice with PBS before being incubated with a HRP-conjugated species specific secondary antibody (1:400, anti-rabbit HRP, Sigma) in a blocking solution for 1 h at room temperature. Filters were washed three times with PBST and twice with PBS prior to application of ECL reagents and visualization of immunoreactivity using a Chemidoc automated gel/blot documentation system (Bio-Rad). Densitometry analysis of developed Western blots was performed using Quantity-1 (Bio-Rad). For the Ca 2+ dose dependency of the NCS-1/GST-P/Q interaction, densitometry data were analyzed by applying nonlinear curve fitting with OriginPro8 (OriginLab).
Synthetic Peptide. The peptide used corresponds to residues 1903−1929 of the human P/Q receptor. The synthetic P/Q peptide, TVGKIYAAMMIMEYYRQSKAKKLQAMR (hereafter termed the PQIQ peptide), was purchased from GenicBio. The peptide was delivered >95% pure.
Protein Expression and Purification. NCS-1 was expressed in Escherichia coli strain BL21(DE3) (Novagen) and purified as previously described. 27 Expression was induced overnight at 18°C; cells were harvested, resuspended into lysis buffer [50 mM Tris-HCl (pH 7.5), 200 mM NaCl, 5 mM CaCl 2 , and Complete EDTA Free Protease Inhibitor (Roche Applied Science)], lysed, centrifuged, filtered, and loaded onto the Hiprep 16/10 Phenyl FF High Sub (GE Healthcare) column that was pre-equilibrated with buffer A [50 mM Tris-HCl (pH 7.5), 200 mM NaCl, and 5 mM CaCl 2 ]. The column was extensively washed with buffer A and NCS-1 eluted using Milli-Q water. The eluted protein was buffer exchanged into 50 mM Tris (pH 7.4) and 500 mM NaCl, and the N-terminal His tag was removed by incubating the protein overnight at 4°C using TEV protease (1:20 TEV protease:NCS-1 molar ratio). His-tagged uncleaved NCS-1 and TEV protease were separated for cleaved NCS-1 using a HisTrap FF 5 mL affinity column (GE Healthcare). The cleaved NCS-1 was further purified using a Superdex 75 Hiload 26/60 (Amersham Biosciences) sizeexclusion column [50 mM Tris-HCl (pH 7.5) and 150 mM NaCl]. The purity of the sample was assessed by sodium dodecyl sulfate−polyacrylamide gel electrophoresis (SDS− PAGE) and deemed to be >95% pure. The eluted peak was concentrated and stored at −80°C.
Calmodulin was cloned into a pET-15b (Novagen) vector (gift from A. Kitmitto, University of Manchester, Manchester, U.K.) and expressed in E. coli strain BL21(DE3) (Novagen) at 37°C. Harvested cells were resuspended in lysis buffer [50 mM Tris (pH 7.5) and 2 mM DTT], disrupted using a French press (Sim Aminco) at 1000 psi, and centrifuged, and the supernatant was recovered, CaCl 2 added to a final concentration of 2 mM, and the protein solution loaded onto a 20 mL HiPrep phenyl sepharose hydrophobic column (GE Healthcare), pre-equilibrated with CaM buffer A [50 mM Tris (pH 7.5), 200 mM NaCl, 2 mM CaCl 2 , and 0.5 mM DTT]. The column was washed with CaM buffer A, followed by buffer B [50 mM Tris (pH 7.5), 0.5 mM CaCl 2 , and 0.5 mM DTT], and pure calmodulin eluted with CaM buffer C [50 mM Tris (pH 7.5), 1 mM EGTA, and 0.5 mM DTT]. The protein was further purified using a 26/60 Superdex 75 (GE Healthcare) sizeexclusion column pre-equilibrated with CaM gel filtration (GF) buffer [50 mM Tris (pH 7.5), 200 mM NaCl, 10 mM CaCl 2 , and 0.5 mM DTT]. The sample was loaded before isocratic elution. The purity of the sample was assessed by SDS−PAGE and deemed to be >95% pure. CaM was dialyzed against water and lyophilized before being stored at −20°C. 15 Healthcare) size-exclusion column. The eluted protein was dialyzed against Milli-Q water and stored as lyophilized samples. Confirmation of the identity of purified PQIQ 1909−2035 was achieved via matrix-assisted laser desorption ionization time-of-flight mass spectrometry performed on unlabeled PQIQ 1909−2035 prepared using a procedure identical to that described above.
Isothermal Titration Calorimetry. ITC experiments were performed using a MicroCal ITC 200 instrument. Because of limitations in PQIQ peptide solubility, NCS-1 was titrated into the peptide. Ca 2+ /NCS-1 at 1 mM was prepared by buffer exchange using a PD10 column equilibrated in 50 mM Tris (pH 7.5), 50 mM NaCl, and 5 mM CaCl 2 , and the PQIQ peptide solution at 100 μM was prepared using the same buffer. If necessary, minor adjustments were made to the pH of the peptide solution. Experiments were conducted using 200 μL of 100 μM PQIQ peptide in the cell and 60 μL of 1 mM NCS-1 in the syringe at 25°C. One injection of 0.2 μL, followed by 20 injections of 2 μL, was made with a 180 s spacing to allow the baseline to return after each injection. All experiments were performed in triplicate. The data were analyzed with a one-site (three-parameter) curve fitting conducted using the MicroCalsupported ITC module within Origin version 7.
Spectrofluorimetry. To monitor the intrinsic tryptophan fluorescence of NCS proteins, 28,29 purified recombinant NCS-1 at a concentration of 1 μM in a buffer [50 mM Tris (pH 7.5), 50 mM NaCl, and 5 mM CaCl 2 ] was excited at room temperature with 280 nm wavelength light and the emission measured between 290 and 410 nm with a slit width of 20 nm using a CARY Eclipse spectrofluorimeter. The PQIQ peptide (stocks ranging from 50 μM to 1 mM) was then added to give an incremental increase in peptide concentration, and emission spectra were acquired after each addition. Experiments were performed in triplicate. The data for the measured tryptophan fluorescence change at each peptide concentration were fit to a logistic equation using nonlinear curve fitting in OriginPro version 9.0. NMR Spectroscopy. NCS-1 was prepared in Tris buffer (pH 6.8) in the presence of 5 mM CaCl 2 . NMR spectra were recorded at 298 K on Bruker Avance II 800 and 600 MHz spectrometers equipped with cryoprobes. Data were processed using Bruker Software TopSpin and analyzed using CCPN. 30 Sequence specific assignment of the PQIQ peptide was achieved using homonuclear two-dimensional TOCSY, COSY, and NOESY data. 13

■ RESULTS
The aim of this study was to test, using a range of complementary methods, the possibility that the small calcium-sensing protein NCS-1 directly interacts with the Ca v 2.1 P/Q-type Ca 2+ channel as has been indirectly suggested in prior functional studies. 20−23 With the knowledge that other known small EF-hand Ca 2+ -binding proteins interact with the α-subunit of the P/Q channel predominantly through motifs located in the C-terminal tail, we reasoned that the same domains represent the most likely sites for an NCS-1 interaction. In initial experiments, we generated a recombinant, GST-tagged, form of the P/Q α 1 subunit C-terminal tail domain corresponding to residues 1898−2035 (Figure 1, GST-PQ). This fragment encompasses both the IQ motif (IM in the P/Q-type channel) and the CaM-binding domain (CBD). 10 Two further constructs derived from this precursor were the CBD alone [residues 1950−2035 (Figure 1, GST-CBD)] and an IQ motif mutant in which the P/Q channel IM residues at positions 1913 and 1914 were mutated to glutamic acid to  (Figure 1, GST IM→EE ). This mutation has been previously shown to abolish CaMdependent CDF and CDI of the human P/Q-type channel. 7 We used these constructs to investigate whether recombinant NCS-1 could associate with P/Q-type C-terminal regulatory domains in vitro. NCS-1 exhibited Ca 2+ -dependent binding to GST-PQ but was not observed to bind to either GST-CBD or GST IM→EE under any tested conditions (Figure 1A), suggesting a specific interaction with residues in the IQ region of the channel. Averaged densitometry data from three independent binding experiments are listed in Table 1.
A Ca 2+ titration of binding of NCS-1 to GST-PQ confirmed the Ca 2+ dependency of the interaction and allowed us to derive a K d of 0.7 μM based on densitometry quantification of Western blot data ( Figure 1B). For comparison, we performed the same binding analysis with CaM ( Figure 1C). Similar to our results with NCS-1, CaM displayed Ca 2+ -dependent binding to GST-PQ but no detectable binding under any conditions to either GST-CBD or GST IM→EE .
Our initial data suggested that both NCS-1 and CaM could interact with the same IQ motif region of the rat P/Q-type channel, and therefore, we extended our binding studies to evaluate the potential existence of a common, overlapping, binding site for both proteins. Competitive association of both proteins with GST-PQ was assessed by binding of NCS-1 to GST-PQ in the presence of increasing concentrations of recombinant CaM (Figure 2). Western blot results from these experiments highlighted a clear displacement of NCS-1 from GST-PQ that was first apparent at a CaM concentration between 0.3 and 1 μM (Figure 2A). Densitometry analysis of the Western blot data confirmed a competitive association between NCS-1 and CaM for GST-PQ ( Figure 2B). Our initial experiments indicated that the IQ-like motif of the P/Q-type channel is important for interaction with both NCS-1 and CaM, and therefore, in subsequent NMR and ITC analyses, we focused on only this region of the channel.
Further testing of the ability of NCS-1 to bind the P/Q-type channel and to delineate the NCS-1-and CaM-binding regions of the P/Q-type channel was performed using NMR experiments. A sample of 15 N-labeled P/Q spanning residues 1909− 2035 (encompassing much of the IQ motif and the CBD) was prepared. Addition of CaM shows chemical shift perturbations of glycine and tryptophan residues, whereas NCS-1 has no effect on either group of residues (Figure 3). Glycine and tryptophan residues are located in the CBD region but not in or around the IQ segment. Hence, it is clear that NCS-1 does not bind to the CBD of the P/Q channel, although there is an indication that there is weak binding of CaM to this site.
Knowing from the experiments described above that the major site of binding of NCS-1 on the P/Q C-terminal domain was likely to be the IQ motif, we used a synthetic PQIQ peptide in subsequent experiments. The intrinsic tryptophan fluorescence of NCS-1 was used to measure interactions with the PQIQ peptide (Figure 4), using an approach similar to that described for the interactions with the D2 dopamine receptor peptide. 27 NCS-1 has two tryptophan residues; addition of the PQIQ peptide resulted in a decrease in fluorescence and allowed titration of the peptide over a range of concentrations ( Figure 2A). The data for the change in fluorescence versus concentration were analyzed using a logistic fit. The dose response upon titration with the PQIQ indicated half-maximal binding at 1.036 ± 0.07 μM with a Hill coefficient of 1.7. Hill coefficients greater than 1 would be consistent with a 2:1 stoichiometry of peptide binding to NCS-1 because NCS-1 itself was monomeric. 27 ITC shows that the interaction is entropically driven. Because of the tendency of the protein complex to aggregate at the high peptide (100 μM) and protein concentrations (1 mM) required to observe binding by this method, it was not possible to obtain reliable equilibrium binding constants using ITC. The affinity obtained for the interaction of NCS-1 with the PQIQ peptide is almost 1 order of magnitude lower than the reported affinities involving the calmodulin lobes. From ITC experiments, K d values of 51 ± 20 and 4.32 ± 0.39 nM were obtained for binding of the Ca 2+ /N  and Ca 2+ /C lobes, respectively, to the IQ domain of the PQ channel. 31 The two lobes in NCS-1 are intimately linked, and attempts to express the two NCS-1 lobes as independently folded domains soluble at micomolar concentrations have met with little success so far. Therefore, experiments that aimed to disentangle the relative affinities of the two NCS-1 domains for the PQIQ peptide have not been possible.
To determine which region of the PQIQ peptide forms the NCS-1-binding site, we again used NMR. In these experiments, [ 13 C, 15 N]NCS-1 was titrated into a sample of the unlabeled PQIQ peptide and 13 C-and 15 N-filtered TOCSY and NOESY data were acquired. Analysis of the side chain resonances, in particular the methyl and tyrosine resonances, reveals selective line broadening for 14 residues, YAAMMIMEYYRQSK ( Figure  5A). Hence, a subset of the 27 amino acids in the polypeptide sequence forms the main interaction site for NCS-1 binding, with the residues beyond this core peptide region further enhancing the interaction. The length of this motif correlates well with the recently reported structure of NCS-1 in complex with the C-terminal peptide from the human D2 dopamine receptor (Protein Data Bank entry 2YOU). The 14-amino acid motif is short enough for it to bind NCS-1 with a stoichiometry of 2:1 (peptide:NCS-1) and supports the fluorescence binding data.
NMR 1 H− 15 N HSQC of NCS-1 in the presence of a 2-fold excess of PQIQ shows resonances that are universally broadened although still discernible to confirm that the protein   Figure 5B). Addition of equimolar amounts of unlabeled CaM/Ca 2+ to the preformed 15 N-labeled NCS-1/ PQIQ complex led to a complete reversion of the 1 H− 15 N HSQC C spectrum to that of free NCS-1. This is further confirmation that NCS-1 and CaM bind to similar sites on the PQ channel, with, as expected, CaM binding the peptide sufficiently strongly to displace it from NCS-1.
The experiments described above show that a direct interaction of NCS-1 with the P/Q C-terminus could be detected using three distinct in vitro biochemical approaches. To provide evidence of the interaction of NCS-1 with the P/Q channel regulatory domain in a more physiological setting, we studied the localization of these proteins ex vivo in cultured HeLa cells. For these experiments, we returned to the use of a longer recombinant construct encompassing both the IQ and CBD domains of the P/Q C-terminus. We first examined the cellular localization of both NCS-1-mCherry 18 and a Cterminally YFP-tagged variant of P/Q 1898−2035 to which an N-terminal myristoylation consensus sequence had been attached ( myr PQ-YFP). In previous studies, this approach has been used to successfully direct isolated soluble domains of plasma membrane proteins to the plasma membrane for functional analyses. 25 NCS-1-mCherry exhibited a predominantly perinuclear localization consistent with its association with the TGN in addition to some plasma membrane localization ( Figure 6A). 32 myr PQ-YFP was observed to target the plasma membrane and/or large cytosolic puncta ( Figure  6A). Plasma membrane association of myr PQ-YFP suggested that myristoylation of the peptide was accurately targeting a fraction of PQ to the expected location. Interestingly, in cells exhibiting myr PQ-YFP puncta, co-expressed NCS-1-mCherry failed to localize to the TGN or plasma membrane and instead colocalized with myr PQ-YFP on the enlarged punctate structures ( Figure 6B). We quantified these phenomena and were able to demonstrate that in 39.5 ± 9.2% of cells cotransfected with NCS-1-mCherry and myr PQ-YFP puncta were observed and that in 100% of this subpopulation NCS-1 protein was associated with large myr PQ-YFP positive punctate structures ( Figure 6C, NCS-1-mCh + myr PQ-YFP). This was similar to the number of cells exhibiting puncta in myr PQ-YFP/mCherry controls [43.6 ± 3% ( Figure 6C, myr PQ-YFP + mCherry)]. In contrast, control cells expressing NCS-1-mCherry along with EYFP protein exhibited no observable formation of puncta ( Figure 6C, NCS-1-mCh + EYFP). It should be noted that

■ DISCUSSION
In this paper, we set out to examine whether NCS-1 is able to interact directly with the C-terminus of the α 1 subunit of the P/ Q-type channel. To avoid a potentially misleading indication of a positive interaction, we tested this using three separate in vitro biochemical/biophysical assays using either a long construct from the P/Q C-terminus or a synthetic IQ domain peptide as well as a test through cellular colocalization. The use of multiple techniques gives a more rigorous approach to addressing the question of whether a significant direct interaction does exist. In all cases, we were able to detect a direct interaction between NCS-1 and P/Q-type Ca 2+ channels. P/Q-type channel regulation by small Ca 2+ -binding proteins is essential in the mammalian CNS for the processes of CDI and CDF that drive short-term presynaptic plasticity. 6 Alterations in synaptic plasticity of this form in turn influence information processing and neural network behavior that underpin the normal functioning of the CNS. 33 A large body of experimental evidence that describes at the molecular level how CaM is able to regulate all Ca v -type channels, including those of the P/Q subtype, has accumulated. CaM is constitutively associated with the P/Q α subunit and is considered an auxiliary subunit of the channel. Apo-CaM is believed to bind to the P/Q α subunit at a site outside of, but in the proximity of, the Ca 2+ -dependent IQ-binding site, as determined using a Forster resonance energy transfer approach in cultured mammalian cells. 34 It has been suggested that this arrangement locates CaM within striking distance of the regulatory IQ motif to ensure fast responses to Ca 2+ influx on channel opening. 34 Ca 2+ -dependent binding of CaM to the IQ motif is then able to modulate both CDI and CDF depending on the precise nature of the Ca 2+ signal. Mechanistically, this system has been resolved in elegant experiments showing that Ca 2+ entry through individual P/Qα channels selectively activates the CaM C-lobe to mediate CDF. Larger Ca 2+ signals emanating from multiple local channel opening events conversely activate the CaM N-lobe to drive CDI. 3,7,35 Our data confirming a Ca 2+ -dependent interaction of CaM with the P/Q containing the IQ motif are consistent with previous biochemical 7 and structural analyses. 31 A second CaM-binding site, the CaM-binding domain (CBD), has been reported in related studies of P/Q−channel interactions. 5,13 In this study, although we have been unable to replicate binding of CaM to this region of the rat α 1A CBD using pull-down experiments, the NMR data suggest that CaM, but not NCS-1, binds to the proposed CBD, albeit rather weakly. The weak nature of this interaction might explain why there are discrepancies in the literature regarding the significance of the CBD. Pull-down-type experiments select for high-affinity interactions, whereas NMR approaches are able to detect lower-affinity transient binding events consistent with these results. Our data help reconcile apparently conflicting experimental data as some studies do observe a CaM−CBD interaction 5,13 whereas others do not. 7 NCS-1, a multifunctional Ca 2+ sensor conserved from yeast to humans, has documented roles in the regulation of membrane trafficking, 36,37 ion channel activity, 38,39 dopamine receptor signaling, 27,40 long-term depression, 41 autism, 18,42 and memory acquisition. 43,44 NCS-1 exhibits enriched expression in mammalian brain tissue, 45 and many of the aforementioned functions are related to neuronal activity. NCS-1 interacts with a number of targets in common with CaM, 24 and a previous functional study identified links between NCS-1 and CDF of P/Q-type channel activity in rat primary neurons. 20 Other studies have additionally indicated a cellular connection between NCS-1 and P/Q-type channel activity in bovine adrenal chromaffin cells 21,22 and Drosophila. 23 With this information in mind, we have tested the possibility that NCS-1 can directly bind to P/Q regulatory elements in common with CaM and other EF-hand-containing Ca 2+ sensors. 10,14 Our data show that NCS-1 can associate with the IQ motif of rat P/ Qα 1A in a Ca 2+ -dependent manner and that this binding site must overlap to some extent with that of CaM because CaM can compete for binding to the same region leading to NCS-1 displacement. This is the first example of a CaM-related Ca 2+sensing protein behaving in a manner almost identical to that of CaM with respect to IQ binding. Both CaBP1 10 and VILIP-2 14 interact with the CBD or require this domain for functional activity. CaM binds predominantly to the IQ domain with a possible weak interaction with the CBD, and NCS-1 binds to only the IQ domain in the presence of Ca 2+ . The weak CaM− CBD interaction that we have observed in this study might also help to explain why CaBP1 and VILIP-2 are able to effectively compete with CaM at this site. 10,14 The precise details of the NCS-1 interaction are still to be elucidated. In rat primary neurons, NCS-1 appears to play a role during CDF, 20 and in Drosophila, loss of the NCS-1 orthologue Frequenin leads to a reduced level of entry of Ca 2+ into neurons and defective synaptic transmission. 23 These data suggest that at least one function of NCS-1 is in positively regulating P/Q channel opening. Our data now provide an attractive biochemical explanation for these cellular studies and act as a platform for further cellular and structural investigations studying the interplay between CaM and NCS-1 during regulation of P/Q channel activity. CaM is expressed in all neurons, and one possibility is that specific neuronal populations that also express NCS-1 are able to utilize this Ca 2+ sensor as an additional modulator of P/Q activity. NCS-1 has a Ca 2+ affinity higher than that of CaM 15,46 and therefore could potentially interact with the IQ motif over a different range of local Ca 2+ concentrations to modulate activity in a manner independent of CaM. As Ca 2+ concentrations increase, CaM could then displace NCS-1 to exert its documented roles in CDF and CDI. The N-and C-lobes of CaM, as described, exert distinct modes of P/Q channel regulation. NCS-1, unlike CaM, does not have distinct lobes but rather a compact globular structure. 47 The orientations of the N-and C-lobes with respect to one another differ in the two proteins, giving rise to different conformations of the ligand-binding site. Residues from both lobes in NCS-1 together form a large, contiguous solvent-exposed hydrophobic ligand-binding crevice, resembling the palm of a partially open hand. In the Ca 2+ / CaM−PQIQ complex, the hydrophobic binding pocket is more enclosed, resembling a closed hand that envelops the PQIQ peptide. It is, therefore, not possible to model a structure of NCS-1 in complex with the PQIQ peptide based on the Ca 2+ / CaM complex structure. It is likely that binding the PQIQ peptide would require a significant conformational change to the overall structure of NCS-1 to accommodate the peptide.
Using a combination of in vitro biochemical, NMR and ITC biophysical, and cellular approaches, we provide the first evidence of a direct interaction of NCS-1 with P/Q-type voltage-gated Ca 2+ channels. Voltage-gated Ca 2+ channel modulation has direct implications for synaptic plasticity and complex neural processing in higher organisms. Our work expands the number of small Ca 2+ -sensing proteins that can interact with the essential P/Q-type neuronal channel and provides further insights into the complexity of the regulation of voltage-gated Ca 2+ channels in the mammalian CNS. Extensive further work will be required to determine the full structural basis for the interaction of NCS-1 with the P/Q IQ domain.