The Calmodulin Regulator Protein,PEP-19, Sensitizes ATP-induced Ca2+ Release

PEP-19 is a small, intrinsically disordered protein that binds to the C-domain of calmodulin (CaM) via an IQ motif and tunes its Ca²⁺ binding properties via an acidic sequence. We show here that the acidic sequence of PEP-19 has intrinsic Ca²⁺ binding activity, which may modulate Ca²⁺ binding to CaM by stabilizing an initial Ca²⁺-CaM complex or by electrostatically steering Ca²⁺ to and from CaM. Because PEP-19 is expressed in cells that exhibit highly active Ca²⁺ dynamics, we tested the hypothesis that it influences ligand-dependent Ca²⁺ release. We show that PEP-19 increases the sensitivity of HeLa cells to ATP-induced Ca²⁺ release to greatly increase the percentage of cells responding to sub-saturating doses of ATP and increases the frequency of Ca²⁺ oscillations. Mutations in the acidic sequence of PEP-19 that inhibit or prevent it from modulating Ca²⁺ binding to CaM greatly inhibit its effect on ATP-induced Ca²⁺ release. Thus, this cellular effect of PEP-19 does not depend simply on binding to CaM via the IQ motif but requires its acidic metal binding domain. Tuning the activities of Ca²⁺ mobilization pathways places PEP-19 at the top of CaM signaling cascades, with great potential to exert broad effects on downstream CaM targets, thus expanding the biological significance of this small regulator of CaM signaling.     

Arrhythmogenic Calmodulin Mutations Affect the Activation and Termination of Cardiac Ryanodine Receptor-mediated Ca2+ Release

The intracellular Ca²⁺ sensor calmodulin (CaM) regulates the cardiac Ca²⁺ release channel/ryanodine receptor 2 (RyR2), and mutations in CaM cause arrhythmias such as catecholaminergic polymorphic ventricular tachycardia (CPVT) and long QT syndrome. Here, we investigated the effect of CaM mutations causing CPVT (N53I), long QT syndrome (D95V and D129G), or both (CaM N97S) on RyR2-mediated Ca²⁺ release. All mutations increased Ca²⁺ release and rendered RyR2 more susceptible to store overload-induced Ca²⁺ release (SOICR) by lowering the threshold of store Ca²⁺ content at which SOICR occurred and the threshold at which SOICR terminated. To obtain mechanistic insights, we investigated the Ca²⁺ binding of the N- and C-terminal domains (N- and C-domain) of CaM in the presence of a peptide corresponding to the CaM-binding domain of RyR2. The N53I mutation decreased the affinity of Ca²⁺ binding to the N-domain of CaM, relative to CaM WT, but did not affect the C-domain. Conversely, mutations N97S, D95V, and D129G had little or no effect on Ca²⁺ binding to the N-domain but markedly decreased the affinity of the C-domain for Ca²⁺. These results suggest that mutations D95V, N97S, and D129G alter the interaction between CaM and the CaMBD and thus RyR2 regulation. Because the N53I mutation minimally affected Ca²⁺ binding to the C-domain, it must cause aberrant regulation via a different mechanism. These results support aberrant RyR2 regulation as the disease mechanism for CPVT associated with CaM mutations and shows that CaM mutations not associated with CPVT can also affect RyR2. A model for the CaM-RyR2 interaction, where the Ca²⁺-saturated C-domain is constitutively bound to RyR2 and the N-domain senses increases in Ca²⁺ concentration, is proposed.     

Thermodynamic linkage between calmodulin domains binding calcium and contiguous sites in the C-terminal tail of Ca(V)1.2

Calmodulin (CaM) binding to the intracellular C-terminal tail (CTT) of the cardiac L-type Ca²⁺ channel (Ca_V1.2) regulates Ca²⁺ entry by recognizing sites that contribute to negative feedback mechanisms for channel closing. CaM associates with Ca_V1.2 under low resting [Ca²⁺], but is poised to change conformation and position when intracellular [Ca²⁺] rises. CaM binding Ca²⁺, and the domains of CaM binding the CTT are linked thermodynamic functions. To better understand regulation, we determined the energetics of CaM domains binding to peptides representing pre-IQ sites A₁₅₈₈, and C₁₆₁₄ and the IQ motif studied as overlapping peptides IQ₁₆₄₄ and IQ′₁₆₅₀ as well as their effect on calcium binding. (Ca²⁺)₄-CaM bound to all four peptides very favorably (K_d ≤ 2 nM). Linkage analysis showed that IQ_1644-1670 bound with a K_d ~ 1 pM. In the pre-IQ region, (Ca²⁺)₂-N-domain bound preferentially to A₁₅₈₈, while (Ca²⁺)₂-C-domain preferred C₁₆₁₄. When bound to C₁₆₁₄, calcium binding in the N-domain affected the tertiary conformation of the C-domain. Based on the thermodynamics, we propose a structural mechanism for calcium-dependent conformational change in which the linker between CTT sites A and C buckles to form an A-C hairpin that is bridged by calcium-saturated CaM.     

Acidic/IQ motif regulator of calmodulin

The small IQ motif proteins PEP-19 (62 amino acids) and RC3 (78 amino acids) greatly accelerate the rates of Ca(2+) binding to sites III and IV in the C-domain of calmodulin (CaM). We show here that PEP-19 decreases the degree of cooperativity of Ca(2+) binding to sites III and IV, and we present a model showing that this could increase Ca(2+) binding rate constants. Comparative sequence analysis showed that residues 28 to 58 from PEP-19 are conserved in other proteins. This region includes the IQ motif (amino acids 39-62), and an adjacent acidic cluster of amino acids (amino acids 28-40). A synthetic peptide spanning residues 28-62 faithfully mimics intact PEP-19 with respect to increasing the rates of Ca(2+) association and dissociation, as well as binding preferentially to the C-domain of CaM. In contrast, a peptide encoding only the core IQ motif does not modulate Ca(2+) binding, and binds to multiple sites on CaM. A peptide that includes only the acidic region does not bind to CaM. These results show that PEP-19 has a novel acidic/IQ CaM regulatory motif in which the IQ sequence provides a targeting function that allows binding of PEP-19 to CaM, whereas the acidic residues modify the nature of this interaction, and are essential for modulating Ca(2+) binding to the C-domain of CaM.     

Neurogranin Alters the Structure and Calcium Binding Properties of Calmodulin

Neurogranin (Ng) is a member of the IQ motif class of calmodulin (CaM)-binding proteins, and interactions with CaM are its only known biological function. In this report we demonstrate that the binding affinity of Ng for CaM is weakened by Ca²⁺ but to a lesser extent (2–3-fold) than that previously suggested from qualitative observations. We also show that Ng induced a >10-fold decrease in the affinity of Ca²⁺ binding to the C-terminal domain of CaM with an associated increase in the Ca²⁺ dissociation rate. We also discovered a modest, but potentially important, increase in the cooperativity in Ca²⁺ binding to the C-lobe of CaM in the presence of Ng, thus sharpening the threshold for the C-domain to become Ca²⁺-saturated. Domain mapping using synthetic peptides indicated that the IQ motif of Ng is a poor mimetic of the intact protein and that the acidic sequence just N-terminal to the IQ motif plays an important role in reproducing Ng-mediated decreases in the Ca²⁺ binding affinity of CaM. Using NMR, full-length Ng was shown to make contacts largely with residues in the C-domain of CaM, although contacts were also detected in residues in the N-terminal domain. Together, our results can be consolidated into a model where Ng contacts residues in the N- and C-lobes of both apo- and Ca²⁺-bound CaM and that although Ca²⁺ binding weakens Ng interactions with CaM, the most dramatic biochemical effect is the impact of Ng on Ca²⁺ binding to the C-terminal lobe of CaM.     

CaMKII Autonomy Is Substrate-dependent and Further Stimulated by Ca2+/Calmodulin

A hallmark feature of Ca²⁺/calmodulin (CaM)-dependent protein kinase II (CaMKII) regulation is the generation of Ca²⁺-independent autonomous activity by Thr-286 autophosphorylation. CaMKII autonomy has been regarded a form of molecular memory and is indeed important in neuronal plasticity and learning/memory. Thr-286-phosphorylated CaMKII is thought to be essentially fully active (∼70–100%), implicating that it is no longer regulated and that its dramatically increased Ca²⁺/CaM affinity is of minor functional importance. However, this study shows that autonomy greater than 15–25% was the exception, not the rule, and required a special mechanism (T-site binding; by the T-substrates AC2 or NR2B). Autonomous activity toward regular R-substrates (including tyrosine hydroxylase and GluR1) was significantly further stimulated by Ca²⁺/CaM, both in vitro and within cells. Altered K_m and V_max made autonomy also substrate- (and ATP) concentration-dependent, but only over a narrow range, with remarkable stability at physiological concentrations. Such regulation still allows molecular memory of previous Ca²⁺ signals, but prevents complete uncoupling from subsequent cellular stimulation.     

Troponin Regulatory Function and Dynamics Revealed by H/D Exchange-Mass Spectrometry

Muscle contraction is tightly regulated by Ca²⁺ binding to the thin filament protein troponin. The mechanism of this regulation was investigated by detailed mapping of the dynamic properties of cardiac troponin using amide hydrogen exchange-mass spectrometry. Results were obtained in the presence of either saturation or non-saturation of the regulatory Ca²⁺ binding site in the NH₂ domain of subunit TnC. Troponin was found to be highly dynamic, with 60% of amides exchanging H for D within seconds of exposure to D₂O. In contrast, portions of the TnT-TnI coiled-coil exhibited high protection from exchange, despite 6 h in D₂O. The data indicate that the most stable portion of the trimeric troponin complex is the coiled-coil. Regulatory site Ca²⁺ binding altered dynamic properties (i.e. H/D exchange protection) locally, near the binding site and in the TnI switch helix that attaches to the Ca²⁺-saturated TnC NH₂ domain. More notably, Ca²⁺ also altered the dynamic properties of other parts of troponin: the TnI inhibitory peptide region that binds to actin, the TnT-TnI coiled-coil, and the TnC COOH domain that contains the regulatory Ca²⁺ sites in many invertebrate as opposed to vertebrate troponins. Mapping of these affected regions onto the troponin highly extended structure suggests that cardiac troponin switches between alternative sets of intramolecular interactions, similar to previous intermediate resolution x-ray data of skeletal muscle troponin.     

A new role for IQ motif proteins in regulating calmodulin function

IQ motifs are found in diverse families of calmodulin (CaM)-binding proteins. Some of these, like PEP-19 and RC3, are highly abundant in neuronal tissues, but being devoid of catalytic activity, their biological roles are not understood. We hypothesized that these IQ motif proteins might have unique effects on the Ca2+ binding properties of CaM, since they bind to CaM in the presence or absence of Ca2+. Here we show that PEP-19 accelerates by 40 to 50-fold both the slow association and dissociation of Ca2+ from the C-domain of free CaM, and we identify the sites of interaction between CaM and PEP-19 using NMR. Importantly, we demonstrate that PEP-19 can also increase the rate of dissociation of Ca2+ from CaM when bound to intact CaM-dependent protein kinase II. Thus, PEP-19, and presumably similar members of the IQ family of proteins, has the potential to alter the Ca2+-binding dynamics of free CaM and CaM that is bound to other target proteins. Since Ca2+ binding to the C-domain of CaM is the rate-limiting step for activation of CaM-dependent enzymes, the data reveal a new concept of importance in understanding the temporal dynamics of Ca2+-dependent cell signaling.     

Thermodynamics and molecular dynamics simulations of calcium binding to the regulatory site of human cardiac troponin C: evidence for communication with the structural calcium binding sites

Human cardiac troponin C (HcTnC), a member of the EF hand family of proteins, is a calcium sensor responsible for initiating contraction of the myocardium. Ca²⁺ binding to the regulatory domain induces a slight change in HcTnC conformation which modifies subsequent interactions in the troponin–tropomyosin–actin complex. Herein, we report a calorimetric study of Ca²⁺ binding to HcTnC. Isotherms obtained at 25 °C (10 mM 2-morpholinoethanesulfonic acid, 50 mM KCl, pH 7.0) provided thermodynamic parameters for Ca²⁺ binding to both the high-affinity and the low-affinity domain of HcTnC. Ca²⁺ binding to the N-domain was shown to be endothermic in 2-morpholinoethanesulfonic acid buffer and allowed us to extract the thermodynamics of Ca²⁺ binding to the regulatory domain. This pattern stems from changes that occur at the Ca²⁺ site rather than structural changes of the protein. Molecular dynamics simulations performed on apo and calcium-bound HcTnC_1–89 support this claim. The values of the Gibbs free energy for Ca²⁺ binding to the N-domain in the full-length protein and to the isolated domain (HcTnC_1–89) are similar; however, differences in the entropic and enthalpic contributions to the free energy provide supporting evidence for the cooperativity of the C-domain and the N-domain. Thermograms obtained at two additional temperatures (10 and 37 °C) revealed interesting trends in the enthalpies and entropies of binding for both thermodynamic events. This allowed the determination of the change in heat capacity (?C _p ) from a plot of ?H verses temperature and may provide evidence for positive cooperativity of Ca²⁺ binding to the C-domain.     

Essential Role of the CBD1-CBD2 Linker in Slow Dissociation of Ca2+ from the Regulatory Two-domain Tandem of NCX1

In NCX proteins CBD1 and CBD2 domains are connected through a short linker (3 or 4 amino acids) forming a regulatory tandem (CBD12). Only three of the six CBD12 Ca²⁺-binding sites contribute to NCX regulation. Two of them are located on CBD1 (K_d = ∼0.2 μm), and one is on CBD2 (K_d = ∼5 μm). Here we analyze how the intrinsic properties of individual regulatory sites are affected by linker-dependent interactions in CBD12 (AD splice variant). The three sites of CBD12 and CBD1 + CBD2 have comparable K_d values but differ dramatically in their Ca²⁺ dissociation kinetics. CBD12 exhibits multiphasic kinetics for the dissociation of three Ca²⁺ ions (k_r = 280 s⁻¹, k_f = 7 s⁻¹, and k_s = 0.4 s⁻¹), whereas the dissociation of two Ca²⁺ ions from CBD1 (k_f = 16 s⁻¹) and one Ca²⁺ ion from CBD2 (k_r = 125 s⁻¹) is monophasic. Insertion of seven alanines into the linker (CBD12–7Ala) abolishes slow dissociation of Ca²⁺, whereas the kinetic and equilibrium properties of three Ca²⁺ sites of CBD12–7Ala and CBD1 + CBD2 are similar. Therefore, the linker-dependent interactions in CBD12 decelerate the Ca²⁺ on/off kinetics at a specific CBD1 site by 50–80-fold, thereby representing Ca²⁺ “occlusion” at CBD12. Notably, the kinetic and equilibrium properties of the remaining two sites of CBD12 are “linker-independent,” so their intrinsic properties are preserved in CBD12. In conclusion, the dynamic properties of three sites are specifically modified, conserved, diversified, and integrated by the linker in CBD12, thereby generating a wide range dynamic sensor.     

Crystal Structures of Progressive Ca2+ Binding States of the Ca2+ Sensor Ca2+ Binding Domain 1 (CBD1) from the CALX Na+/Ca2+ Exchanger Reveal Incremental Conformational Transitions

Na⁺/Ca²⁺ exchangers (NCX) constitute a major Ca²⁺ export system that facilitates the re-establishment of cytosolic Ca²⁺ levels in many tissues. Ca²⁺ interactions at its Ca²⁺ binding domains (CBD1 and CBD2) are essential for the allosteric regulation of Na⁺/Ca²⁺ exchange activity. The structure of the Ca²⁺-bound form of CBD1, the primary Ca²⁺ sensor from canine NCX1, but not the Ca²⁺-free form, has been reported, although the molecular mechanism of Ca²⁺ regulation remains unclear. Here, we report crystal structures for three distinct Ca²⁺ binding states of CBD1 from CALX, a Na⁺/Ca²⁺ exchanger found in Drosophila sensory neurons. The fully Ca²⁺-bound CALX-CBD1 structure shows that four Ca²⁺ atoms bind at identical Ca²⁺ binding sites as those found in NCX1 and that the partial Ca²⁺ occupancy and apoform structures exhibit progressive conformational transitions, indicating incremental regulation of CALX exchange by successive Ca²⁺ binding at CBD1. The structures also predict that the primary Ca²⁺ pair plays the main role in triggering functional conformational changes. Confirming this prediction, mutagenesis of Glu⁴⁵⁵, which coordinates the primary Ca²⁺ pair, produces dramatic reductions of the regulatory Ca²⁺ affinity for exchange current, whereas mutagenesis of Glu⁵²⁰, which coordinates the secondary Ca²⁺ pair, has much smaller effects. Furthermore, our structures indicate that Ca²⁺ binding only enhances the stability of the Ca²⁺ binding site of CBD1 near the hinge region while the overall structure of CBD1 remains largely unaffected, implying that the Ca²⁺ regulatory function of CBD1, and possibly that for the entire NCX family, is mediated through domain interactions between CBD1 and the adjacent CBD2 at this hinge.     

Calmodulin Mediates the Ca-Dependent Regulation of Cx44 Gap Junctions

We have shown previously that the Ca²⁺-dependent inhibition of lens epithelial cell-to-cell communication is mediated in part by the direct association of calmodulin (CaM) with connexin43 (Cx43), the major connexin in these cells. We now show that elevation of [Ca²⁺]_i in HeLa cells transfected with the lens fiber cell gap junction protein sheep Cx44 also results in the inhibition of cell-to-cell dye transfer. A peptide comprising the putative CaM binding domain (aa 129-150) of the intracellular loop region of this connexin exhibited a high affinity, stoichiometric interaction with Ca²⁺-CaM. NMR studies indicate that the binding of Cx44 peptide to CaM reflects a classical embracing mode of interaction. The interaction is an exothermic event that is both enthalpically and entropically driven in which electrostatic interactions play an important role. The binding of the Cx44 peptide to CaM increases the CaM intradomain cooperativity and enhances the Ca²⁺-binding affinities of the C-domain of CaM more than twofold by slowing the rate of Ca²⁺ release from the complex. Our data suggest a common mechanism by which the Ca²⁺-dependent inhibition of the α-class of gap junction proteins is mediated by the direct association of an intracellular loop region of these proteins with Ca²⁺-CaM.     

Intrinsically disordered PEP-19 confers unique dynamic properties to apo and calcium calmodulin

PEP-19 (Purkinje cell protein 4) is an intrinsically disordered protein with an IQ calmodulin (CaM) binding motif. Expression of PEP-19 was recently shown to protect cells from apoptosis and cell death due to Ca(2+) overload. Our initial studies showed that PEP-19 causes novel and dramatic increases in the rates of association of Ca(2+) with and dissociation of Ca(2+) from the C-domain of CaM. The goal of this work was to study interactions between the C-domain of CaM (C-CaM) and PEP-19 by solution nuclear magnetic resonance (NMR) to identify mechanisms by which PEP-19 regulates binding of Ca(2+) to CaM. Our results show that PEP-19 causes a greater structural change in apo C-CaM than in Ca(2+)-C-CaM, and that the first Ca(2+) binds preferentially to site IV in the presence of PEP-19 with exchange characteristics that are consistent with a decrease in Ca(2+) binding cooperativity. Relatively weak binding of PEP-19 has distinct effects on chemical and conformational exchange on the microsecond to millisecond time scale. In apo C-CaM, PEP-19 binding causes a redistribution of residues that experience conformational exchange, leading to an increase in the number of residues around Ca(2+) binding site IV that undergo conformational exchange on the microsecond to millisecond time scale. This appears to be caused by an allosteric effect because these residues are not localized to the PEP-19 binding site. In contrast, PEP-19 increases the number of residues that exhibit conformational exchange in Ca(2+)-C-CaM. These residues are primarily localized to the PEP-19 binding site but also include Asp93 in site III. These results provide working models for the role of protein dynamics in the regulation of binding of Ca(2+) to CaM by PEP-19.     

Ca2+-independent Activation of Ca2+/Calmodulin-dependent Protein Kinase II Bound to the C-terminal Domain of CaV2.1 Calcium Channels

Ca²⁺/calmodulin-dependent protein kinase II (CaMKII) forms a major component of the postsynaptic density where its functions in synaptic plasticity are well established, but its presynaptic actions are poorly defined. Here we show that CaMKII binds directly to the C-terminal domain of Ca_V2.1 channels. Binding is enhanced by autophosphorylation, and the kinase-channel signaling complex persists after dephosphorylation and removal of the Ca²⁺/CaM stimulus. Autophosphorylated CaMKII can bind the Ca_V2.1 channel and synapsin-1 simultaneously. CaMKII binding to Ca_V2.1 channels induces Ca²⁺-independent activity of the kinase, which phosphorylates the enzyme itself as well as the neuronal substrate synapsin-1. Facilitation and inactivation of Ca_V2.1 channels by binding of Ca²⁺/CaM mediates short term synaptic plasticity in transfected superior cervical ganglion neurons, and these regulatory effects are prevented by a competing peptide and the endogenous brain inhibitor CaMKIIN, which blocks binding of CaMKII to Ca_V2.1 channels. These results define the functional properties of a signaling complex of CaMKII and Ca_V2.1 channels in which both binding partners are persistently activated by their association, and they further suggest that this complex is important in presynaptic terminals in regulating protein phosphorylation and short term synaptic plasticity.     

The neuronal voltage-dependent sodium channel type II IQ motif lowers the calcium affinity of the C-domain of calmodulin

Calmodulin (CaM) is the primary calcium sensor in eukaryotes. Calcium binds cooperatively to pairs of EF-hand motifs in each domain (N and C). This allows CaM to regulate cellular processes via calcium-dependent interactions with a variety of proteins, including ion channels. One neuronal target is NaV1.2, voltage-dependent sodium channel type II, to which CaM binds via an IQ motif within the NaV1.2 C-terminal tail (residues 1901-1938) [Mori, M., et al. (2000) Biochemistry 39, 1316-1323]. Here we report on the use of circular dichroism, fluorescein emission, and fluorescence anisotropy to study the interaction between CaM and NaV1.2 at varying calcium concentrations. At 1 mM MgCl2, both full-length CaM (CaM1-148) and a C-domain fragment (CaM76-148) exhibit tight (nanomolar) calcium-independent binding to the NaV1.2 IQ motif, whereas an N-domain fragment of CaM (CaM1-80) binds weakly, regardless of calcium concentration. Equilibrium calcium titrations of CaM at several concentrations of the NaV1.2 IQ peptide showed that the peptide reduced the calcium affinity of the CaM C-domain sites (III and IV) without affecting the N-domain sites (I and II) significantly. This leads us to propose that the CaM C-domain mediates constitutive binding to the NaV1.2 peptide, but that interaction then distorts calcium-binding sites III and IV, thereby reducing their affinity for calcium. This contrasts with the CaM-binding domains of voltage-dependent Ca2+ channels, kinases, and phosphatases, which increase the calcium binding affinity of the C-domain of CaM.     

Critical Roles of Interdomain Interactions for Modulatory ATP Binding to Sarcoplasmic Reticulum Ca2+-ATPase

ATP has dual roles in the reaction cycle of sarcoplasmic reticulum Ca²⁺-ATPase. Upon binding to the Ca₂E1 state, ATP phosphorylates the enzyme, and by binding to other conformational states in a non-phosphorylating modulatory mode ATP stimulates the dephosphorylation and other partial reaction steps of the cycle, thereby ensuring a high rate of Ca²⁺ transport under physiological conditions. The present study elucidates the mechanism underlying the modulatory effect on dephosphorylation. In the intermediate states of dephosphorylation the A-domain residues Ser¹⁸⁶ and Asp²⁰³ interact with Glu⁴³⁹ (N-domain) and Arg⁶⁷⁸ (P-domain), respectively. Single mutations to these residues abolish the stimulation of dephosphorylation by ATP. The double mutation swapping Asp²⁰³ and Arg⁶⁷⁸ rescues ATP stimulation, whereas this is not the case for the double mutation swapping Ser¹⁸⁶ and Glu⁴³⁹. By taking advantage of the ability of wild type and mutant Ca²⁺-ATPases to form stable complexes with aluminum fluoride (E2·AlF) and beryllium fluoride (E2·BeF) as analogs of the E2·P phosphoryl transition state and E2P ground state, respectively, of the dephosphorylation reaction, the mutational effects on ATP binding to these intermediates are demonstrated. In the wild type Ca²⁺-ATPase, the ATP affinity of the E2·P phosphoryl transition state is higher than that of the E2P ground state, thus explaining the stimulation of dephosphorylation by nucleotide-induced transition state stabilization. We find that the Asp²⁰³-Arg⁶⁷⁸ and Ser¹⁸⁶-Glu⁴³⁹ interdomain bonds are critical, because they tighten the interaction with ATP in the E2·P phosphoryl transition state. Moreover, ATP binding and the Ser¹⁸⁶-Glu⁴³⁹ bond are mutually exclusive in the E2P ground state.     

Fluorescence polarization assay for calmodulin binding to plasma membrane Ca-ATPase: Dependence on enzyme and Ca concentrations

Calmodulin (CaM) is a Ca²⁺ signaling protein that binds to a wide variety of target proteins, and it is important to establish methods for rapid characterization of these interactions. Here we report the use of fluorescence polarization (FP) to measure the K_d for the interaction of CaM with the plasma membrane Ca²⁺-ATPase (PMCA), a Ca²⁺ pump regulated by binding of CaM. Previous assays of PMCA-CaM interactions were indirect, based on activity or kinetics measurements. We also investigated the Ca²⁺ dependence of CaM binding to PMCA. FP assays directly detect CaM-target interactions and are rapid, sensitive, and suitable for high-throughput screening assay formats. Values for the dissociation constant K_d in the nanomolar range are readily measured. We measured the changes in anisotropy of CaM labeled with Oregon Green 488 on titration with PMCA, yielding a K_d value of CaM with PMCA (5.8 ± 0.5 nM) consistent with previous indirect measurements. We also report the binding affinity of CaM with oxidatively modified PMCA (K_d = 9.8 ± 2.0 nM), indicating that the previously reported loss in CaM-stimulated activity for oxidatively modified PMCA is not a result of reduced CaM binding. The Ca²⁺ dependence follows a simple Hill plot demonstrating cooperative binding of Ca²⁺ to the binding sites in CaM.     

NMR analysis of free and lipid nanodisc anchored CEACAM1 membrane proximal peptides with Ca2+/CaM

CEACAM1, a homotypic transmembrane receptor with 12 or 72 amino acid cytosolic domain isoforms, is converted from inactive cis-dimers to active trans-dimers by calcium-calmodulin (Ca²⁺/CaM). Previously, the weak binding of Ca²⁺/CaM to the human 12 AA cytosolic domain was studied using C-terminal anchored peptides. We now show the binding of ¹⁵N labeled Phe-454 cytosolic domain peptides in solution or membrane anchored using NMR demonstrates a significant role for the lipid bilayer. Although binding is increased by the mutation Phe454Ala, this mutation was previously shown to abrogate actin binding. On the other hand, Ca²⁺/CaM binding is abrogated by phosphorylation of nearby Thr-457, a post-translation modification required for actin binding and subsequent in vitro lumen formation. Binding of Ca²⁺/CaM to a membrane proximal peptide from the long 72 AA cytosolic domain anchored to lipid nanodiscs was very weak compared to lipid free conditions, suggesting membrane specific effects between the two isoforms. NMR analysis of ¹⁵N labeled Ca²⁺/CaM with unlabeled peptides showed the C-lobe of Ca²⁺/CaM is involved in peptide interactions, and hydrophobic residues such as Met-109, Val-142 and Met-144 play important roles in binding peptide. This information was incorporated into transmembrane models of CEACAM1 binding to Ca²⁺/CaM. The lack of Ca²⁺/CaM binding to phosphorylated Thr-457, a residue we have previously shown to be phosphorylated by CaMK2D, also dependent on Ca²⁺/CaM, suggests stepwise binding of the cytosolic domain first to Ca²⁺/CaM and then to actin.     

Calcium-induced refolding of the calmodulin V136G mutant studied by NMR spectroscopy: evidence for interaction between the two globular domains

The Ca(2+) titration of the (15)N-labeled mutant V136G calmodulin has been monitored using (1)H-(15)N HSQC NMR spectra. Up to a [Ca(2+)]/[CaM] ratio of 2, the Ca(2+) ions bind predominantly to sites I and II on the N-domain in contrast with the behavior of the wild-type calmodulin where the C-terminal domain has the higher affinity for Ca(2+). Surprisingly, the Ca(2+)-binding affinity for the N-domain in the mutant calmodulin is greater than that for the N-domain in the wild-type protein. The mutated C-domain is observed as a mixture of unfolded, partially folded (site III occupied), and native-like folded (sites III and IV occupied) conformations, with relative populations dependent on the [Ca(2+)]/[CaM] ratio. The occupancy of site III independently of site IV in this mutant shows that the cooperativity of Ca(2+) binding in the C-domain is mediated by the integrity of the domain structure. Several NH signals from residues in the Ca(2+)-bound N-domain appear as two signals during the Ca(2+) titration indicating separate species in slow exchange, and it can be deduced that these result from the presence and absence of interdomain interactions in the mutant. It is proposed that an unfolded part of the mutated C-domain interacts with sites on the N-domain that normally bind to target proteins. This would also account for the increase in the Ca(2+) affinity for the N-domain in the mutant compared with the wild-type calmodulin. The results therefore show the wide-ranging effects of a point mutation in a single Ca(2+)-binding site, providing details of the involvement of individual residues in the calcium-induced folding reactions.     

Distal Histidine Stabilizes Bound O2 and Acts as a Gate for Ligand Entry in Both Subunits of Adult Human Hemoglobin

The role of the distal histidine in regulating ligand binding to adult human hemoglobin (HbA) was re-examined systematically by preparing His(E7) to Gly, Ala, Leu, Gln, Phe, and Trp mutants of both Hb subunits. Rate constants for O₂, CO, and NO binding were measured using rapid mixing and laser photolysis experiments designed to minimize autoxidation of the unstable apolar E7 mutants. Replacing His(E7) with Gly, Ala, Leu, or Phe causes 20–500-fold increases in the rates of O₂ dissociation from either Hb subunit, demonstrating unambiguously that the native His(E7) imidazole side chain forms a strong hydrogen bond with bound O₂ in both the α and β chains (ΔG_{His(E7)H-bond} ≈ −8 kJ/mol). As the size of the E7 amino acid is increased from Gly to Phe, decreases in k_O2′, k_NO′, and calculated bimolecular rates of CO entry (k_entry′) are observed. Replacing His(E7) with Trp causes further decreases in k_O2′, k_NO′, and k_entry′ to 1–2 μm⁻¹ s⁻¹ in β subunits, whereas ligand rebinding to αTrp(E7) subunits after photolysis is markedly biphasic, with fast k_O2′, k_CO′, and k_NO′ values ≈150 μm⁻¹ s⁻¹ and slow rate constants ≈0.1 to 1 μm⁻¹ s⁻¹. Rapid bimolecular rebinding to an open α subunit conformation occurs immediately after photolysis of the αTrp(E7) mutant at high ligand concentrations. However, at equilibrium the closed αTrp(E7) side chain inhibits the rate of ligand binding >200-fold. These data suggest strongly that the E7 side chain functions as a gate for ligand entry in both HbA subunits.