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.     

Pull-down of Calmodulin-binding Proteins

Calcium (Ca²⁺) is an ion vital in regulating cellular function through a variety of mechanisms. Much of Ca²⁺ signaling is mediated through the calcium-binding protein known as calmodulin (CaM)^1,2. CaM is involved at multiple levels in almost all cellular processes, including apoptosis, metabolism, smooth muscle contraction, synaptic plasticity, nerve growth, inflammation and the immune response. A number of proteins help regulate these pathways through their interaction with CaM. Many of these interactions depend on the conformation of CaM, which is distinctly different when bound to Ca²⁺ (Ca²⁺-CaM) as opposed to its Ca²⁺-free state (ApoCaM)³.While most target proteins bind Ca²⁺-CaM, certain proteins only bind to ApoCaM. Some bind CaM through their IQ-domain, including neuromodulin⁴, neurogranin (Ng)⁵, and certain myosins⁶. These proteins have been shown to play important roles in presynaptic function⁷, postsynaptic function⁸, and muscle contraction⁹, respectively. Their ability to bind and release CaM in the absence or presence of Ca²⁺ is pivotal in their function. In contrast, many proteins only bind Ca²⁺-CaM and require this binding for their activation. Examples include myosin light chain kinase¹⁰, Ca²⁺/CaM-dependent kinases (CaMKs)¹¹ and phosphatases (e.g. calcineurin)¹², and spectrin kinase¹³, which have a variety of direct and downstream effects¹⁴.The effects of these proteins on cellular function are often dependent on their ability to bind to CaM in a Ca²⁺-dependent manner. For example, we tested the relevance of Ng-CaM binding in synaptic function and how different mutations affect this binding. We generated a GFP-tagged Ng construct with specific mutations in the IQ-domain that would change the ability of Ng to bind CaM in a Ca²⁺-dependent manner. The study of these different mutations gave us great insight into important processes involved in synaptic function^8,15. However, in such studies, it is essential to demonstrate that the mutated proteins have the expected altered binding to CaM.Here, we present a method for testing the ability of proteins to bind to CaM in the presence or absence of Ca²⁺, using CaMKII and Ng as examples. This method is a form of affinity chromatography referred to as a CaM pull-down assay. It uses CaM-Sepharose beads to test proteins that bind to CaM and the influence of Ca²⁺ on this binding. It is considerably more time efficient and requires less protein relative to column chromatography and other assays. Altogether, this provides a valuable tool to explore Ca²⁺/CaM signaling and proteins that interact with CaM.     

Capping of the N‐terminus of PSD‐95 by calmodulin triggers its postsynaptic release

Postsynaptic density protein‐95 (PSD‐95) is a central element of the postsynaptic architecture of glutamatergic synapses. PSD‐95 mediates postsynaptic localization of AMPA receptors and NMDA receptors and plays an important role in synaptic plasticity. PSD‐95 is released from postsynaptic membranes in response to Ca²⁺ influx via NMDA receptors. Here, we show that Ca²⁺/calmodulin (CaM) binds at the N‐terminus of PSD‐95. Our NMR structure reveals that both lobes of CaM collapse onto a helical structure of PSD‐95 formed at its N‐terminus (residues 1–16). This N‐terminal capping of PSD‐95 by CaM blocks palmitoylation of C3 and C5, which is required for postsynaptic PSD‐95 targeting and the binding of CDKL5, a kinase important for synapse stability. CaM forms extensive hydrophobic contacts with Y12 of PSD‐95. The PSD‐95 mutant Y12E strongly impairs binding to CaM and Ca²⁺‐induced release of PSD‐95 from the postsynaptic membrane in dendritic spines. Our data indicate that CaM binding to PSD‐95 serves to block palmitoylation of PSD‐95, which in turn promotes Ca²⁺‐induced dissociation of PSD‐95 from the postsynaptic membrane.     

Ca2+/calmodulin binding to PSD‐95 mediates homeostatic synaptic scaling down

Postsynaptic density protein‐95 (PSD‐95) localizes AMPA‐type glutamate receptors (AMPARs) to postsynaptic sites of glutamatergic synapses. Its postsynaptic displacement is necessary for loss of AMPARs during homeostatic scaling down of synapses. Here, we demonstrate that upon Ca²⁺ influx, Ca²⁺/calmodulin (Ca²⁺/CaM) binding to the N‐terminus of PSD‐95 mediates postsynaptic loss of PSD‐95 and AMPARs during homeostatic scaling down. Our NMR structural analysis identified E17 within the PSD‐95 N‐terminus as important for binding to Ca²⁺/CaM by interacting with R126 on CaM. Mutating E17 to R prevented homeostatic scaling down in primary hippocampal neurons, which is rescued via charge inversion by ectopic expression of CaM^R126E, as determined by analysis of miniature excitatory postsynaptic currents. Accordingly, increased binding of Ca²⁺/CaM to PSD‐95 induced by a chronic increase in Ca²⁺ influx is a critical molecular event in homeostatic downscaling of glutamatergic synaptic transmission.     

Phosphatidylinositol-4,5 bisphosphate (PIP2) inhibits apo-calmodulin binding to protein 4.1

Membrane skeletal protein 4.1R⁸⁰ plays a key role in regulation of erythrocyte plasticity. Protein 4.1R⁸⁰ interactions with transmembrane proteins, such as glycophorin C (GPC), are regulated by Ca²⁺-saturated calmodulin (Ca²⁺/CaM) through simultaneous binding to a short peptide (pep11; A²⁶⁴KKLWKVCVEHHTFFRL) and a serine residue (Ser¹⁸⁵), both located in the N-terminal 30 kDa FERM domain of 4.1R⁸⁰ (H·R30). We have previously demonstrated that CaM binding to H·R30 is Ca²⁺-independent and that CaM binding to H·R30 is responsible for the maintenance of H·R30 β-sheet structure. However, the mechanisms responsible for the regulation of CaM binding to H·R30 are still unknown. To investigate this, we took advantage of similarities and differences in the structure of Coracle, the Drosophila sp. homologue of human 4.1R⁸⁰, i.e. conservation of the pep11 sequence but substitution of the Ser¹⁸⁵ residue with an alanine residue. We show that the H·R30 homologue domain of Coracle, Cor30, also binds to CaM in a Ca²⁺-independent manner and that the Ca²⁺/CaM complex does not affect Cor30 binding to the transmembrane protein GPC. We also document that both H·R30 and Cor30 bind to phosphatidylinositol-4,5 bisphosphate (PIP₂) and other phospholipid species and that that PIP₂ inhibits Ca²⁺-free CaM but not Ca²⁺-saturated CaM binding to Cor30. We conclude that PIP₂ may play an important role as a modulator of apo-CaM binding to 4.1R⁸⁰ throughout evolution.     

Dissociation of Calmodulin-Target Peptide Complexes by the Lipid Mediator Sphingosylphosphorylcholine: IMPLICATIONS IN CALCIUM SIGNALING*

Previously we have identified the lipid mediator sphingosylphosphorylcholine (SPC) as the first potentially endogenous inhibitor of the ubiquitous Ca²⁺ sensor calmodulin (CaM) (Kovacs, E., and Liliom, K. (2008) Biochem. J. 410, 427–437). Here we give mechanistic insight into CaM inhibition by SPC, based on fluorescence stopped-flow studies with the model CaM-binding domain melittin. We demonstrate that both the peptide and SPC micelles bind to CaM in a rapid and reversible manner with comparable affinities. Furthermore, we present kinetic evidence that both species compete for the same target site on CaM, and thus SPC can be considered as a competitive inhibitor of CaM-target peptide interactions. We also show that SPC disrupts the complex of CaM and the CaM-binding domain of ryanodine receptor type 1, inositol 1,4,5-trisphosphate receptor type 1, and the plasma membrane Ca²⁺ pump. By interfering with these interactions, thus inhibiting the negative feedback that CaM has on Ca²⁺ signaling, we hypothesize that SPC could lead to Ca²⁺ mobilization in vivo. Hence, we suggest that the action of the sphingolipid on CaM might explain the previously recognized phenomenon that SPC liberates Ca²⁺ from intracellular stores. Moreover, we demonstrate that unlike traditional synthetic CaM inhibitors, SPC disrupts the complex between not only the Ca²⁺-saturated but also the apo form of the protein and the target peptide, suggesting a completely novel regulation for target proteins that constitutively bind CaM, such as ryanodine receptors.     

Multifunctional Ca2+/calmodulin-dependent protein kinase

Multifunctional Ca²⁺/calmodulin-dependent protein kinase (CaM kinase) is a prominent mediator of neurotransmitters which elevate Ca²⁺. It coordinates cellular responses to external stimuli by phosphorylating proteins involved in neurotransmitter synthesis, neurotransmitter release, carbohydrate metabolism, ion flux and neuronal plasticity. Structure/function studies of CaM kinase have provided insights into how it decodes Ca²⁺ signals. The kinase is kept relatively inactive in its basal state by the presence of an autoinhibitory domain. Binding of Ca²⁺/calmodulin eliminates this inhibitory constraint and allows the kinase to phosphorylate its substrates, as well as itself. This autophosphorylation significantly slows dissociation of calmodulin, thereby trapping calmodulin even when Ca²⁺ levels are subthreshold. The kinase may respond particularly wel to multiple Ca²⁺ spikes since trapping may enable a spike frequency-dependent recruitment of calmodulin with each successive Ca²⁺ spike leading to increased activation of the kinase. Once calmodulin dissociates, CaM kinase remains partially active until it is dephosphorylated, providing for an additional period in which its response to brief Ca²⁺ transients is potentiated.Special issue dedicated to Dr. Paul Greengard.     

Novel Mechanism of Regulation of Protein 4.1G Binding Properties Through Ca2+/Calmodulin-Mediated Structural Changes

Protein 4.1G (4.1G) is a widely expressed member of the protein 4.1 family of membrane skeletal proteins. We have previously reported that Ca²⁺-saturated calmodulin (Ca²⁺/CaM) modulates 4.1G interactions with transmembrane and membrane-associated proteins through binding to Four.one-ezrin–radixin–moesin (4.1G FERM) domain and N-terminal headpiece region (GHP). Here we identify a novel mechanism of Ca²⁺/CaM-mediated regulation of 4.1G interactions using a combination of small-angle X-ray scattering, nuclear magnetic resonance spectroscopy, and circular dichroism spectroscopy analyses. We document that GHP intrinsically disordered coiled structure switches to a stable compact structure upon binding of Ca²⁺/CaM. This dramatic conformational change of GHP inhibits in turn 4.1G FERM domain interactions due to steric hindrance. Based upon sequence homologies with the Ca²⁺/CaM-binding motif in protein 4.1R headpiece region, we establish that the 4.1G S⁷¹RGISRFIPPWLKKQKS peptide (pepG) mediates Ca²⁺/CaM binding. As observed for GHP, the random coiled structure of pepG changes to a relaxed globular shape upon complex formation with Ca²⁺/CaM. The resilient coiled structure of pepG, maintained even in the presence of trifluoroethanol, singles it out from any previously published CaM-binding peptide. Taken together, these results show that Ca²⁺/CaM binding to GHP, and more specifically to pepG, has profound effects on other functional domains of 4.1G.     

Ca-Calmodulin Increases RyR2 Open Probability yet Reduces Ryanoid Association with RyR2

We have shown that physiological levels of Ca²⁺-calmodulin (Ca²⁺CaM; 50-100 nM) activate cardiac ryanodine receptors (RyR2) incorporated into bilayers and increase the frequency of Ca²⁺ sparks and waves in cardiac cells. In contrast, it is well known that Ca²⁺CaM inhibits [³H]ryanodine binding to cardiac sarcoplasmic reticulum. Since the [³H]ryanodine binding technique does not reflect the effects of Ca²⁺CaM on RyR2 open probability (Po), we have investigated, using the reversible ryanoid, ryanodol, whether Ca²⁺CaM can directly influence the binding of ryanoids to single RyR2 channels independently of Po. We demonstrate that Ca²⁺CaM reduces the rate of ryanodol association to RyR2 without affecting the rate of dissociation. We also find that ryanodol-bound channels fluctuate between at least two distinct subconductance states, M₁ and M₂, in a voltage-dependent manner. Ca²⁺CaM significantly alters the equilibrium between these two states. The results suggest that Ca²⁺CaM binding to RyR2 causes a conformation change to regions of the channel that include the ryanoid binding site, thereby leading to a decrease in ryanoid association rate and modulation of gating within the ryanoid/RyR2 bound state. Our data provide a possible explanation for why the effects of Ca²⁺CaM at the single-channel level are not mirrored by [³H]ryanodine binding studies.     

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.     

Determination of the Dissociation Constants for Ca2+ and Calmodulin from the Plasma Membrane Ca2+ Pump by a Lipid Probe That Senses Membrane Domain Changes

The purpose of this work was to obtain information about conformational changes of the plasma membrane Ca²⁺-pump (PMCA) in the membrane region upon interaction with Ca²⁺, calmodulin (CaM) and acidic phospholipids. To this end, we have quantified labeling of PMCA with the photoactivatable phosphatidylcholine analog [¹²⁵I]TID-PC/16, measuring the shift of conformation E₂ to the auto-inhibited conformation E₁I and to the activated E₁A state, titrating the effect of Ca²⁺ under different conditions. Using a similar approach, we also determined the CaM-PMCA dissociation constant. The results indicate that the PMCA possesses a high affinity site for Ca²⁺ regardless of the presence or absence of activators. Modulation of pump activity is exerted through the C-terminal domain, which induces an apparent auto-inhibited conformation for Ca²⁺ transport but does not modify the affinity for Ca²⁺ at the transmembrane domain. The C-terminal domain is affected by CaM and CaM-like treatments driving the auto-inhibited conformation E₁I to the activated E₁A conformation and thus modulating the transport of Ca²⁺. This is reflected in the different apparent constants for Ca²⁺ in the absence of CaM (calculated by Ca²⁺-ATPase activity) that sharply contrast with the lack of variation of the affinity for the Ca²⁺ site at equilibrium. This is the first time that equilibrium constants for the dissociation of Ca²⁺ and CaM ligands from PMCA complexes are measured through the change of transmembrane conformations of the pump. The data further suggest that the transmembrane domain of the PMCA undergoes major rearrangements resulting in altered lipid accessibility upon Ca²⁺ binding and activation.     

The role of calcium in the interaction between calmodulin and a minimal functional construct of eukaryotic elongation factor 2 kinase

Eukaryotic elongation factor 2 kinase (eEF‐2K) regulates protein synthesis by phosphorylating eukaryotic elongation factor 2 (eEF‐2), thereby reducing its affinity for the ribosome and suppressing global translational elongation rates. eEF‐2K is regulated by calmodulin (CaM) through a mechanism that is distinct from that of other CaM‐regulated kinases. We had previously identified a minimal construct of eEF‐2K (TR) that is activated similarly to the wild‐type enzyme by CaM in vitro and retains its ability to phosphorylate eEF‐2 efficiently in cells. Here, we employ solution nuclear magnetic resonance techniques relying on Ile δ1‐methyls of TR and Ile δ1‐ and Met ε‐methyls of CaM, as probes of their mutual interaction and the influence of Ca²⁺ thereon. We find that in the absence of Ca²⁺, CaM exclusively utilizes its C‐terminal lobe (CaM_C) to engage the N‐terminal CaM‐binding domain (CBD) of TR in a high‐affinity interaction. Avidity resulting from additional weak interactions of TR with the Ca²⁺‐loaded N‐terminal lobe of CaM (CaM_N) at increased Ca²⁺ levels serves to enhance the affinity further. These latter interactions under Ca²⁺ saturation result in minimal perturbations in the spectra of TR in the context of its complex with CaM, suggesting that the latter is capable of driving TR to its final, presumably active conformation, in the Ca²⁺‐free state. Our data are consistent with a scenario in which Ca²⁺ enhances the affinity of the TR/CaM interactions, resulting in the increased effective concentration of the CaM‐bound species without significantly modifying the conformation of TR within the final, active complex.     

Calcium/calmodulin-dependent inhibition of microtubule assembly by brain synaptic junction

The effect of synaptic junction (SJ) on microtubule assembly was examined. After preincubation with ATP at 37°C, rat SJ decreased the initial velocity and the extent of the porcine brain microtubule assembly (initiated by the addition of GTP) in a Ca²⁺/calmodulin (CaM)-dependent manner. The degree of the inhibition reached 35% of the control assembly (0-min preincubation) after 20-min preincubation with ATP. There was no inhibition either with heat-treated SJ, at 0°C, or in the presence of EGTA or W-7 (CaM antagonist). The inhibition was due neither to protease(s) nor CaM contaminating the preparations. Free Ca²⁺ concentration level required for the inhibition of microtubule assembly was 10^–6 M. Phosphorylation of microtubule proteins was inhibited by SJ in a Ca²⁺/CaM-dependent manner, and the inhibition occurred in a physiological increase range of intracellular Ca²⁺ concentration (10^–6M) The heat-treated SJ caused no inhibition. The result suggested that the microtubule assembly in the postsynaptic region was regulated by a Ca²⁺/CaM-dependent protein kinase associated with SJ; i. e., major postsynaptic density protein.Abbreviations used CaM calmodulin - DTT dithiothreitol - MAPs microtubule-associated proteins - MES 2-(N-morphorino)ethanesulfonic acid - mPSDp major postsynaptic density protein - PSD postsynaptic density - SDS PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - W-7 N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide hydrochloride     

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.     

Unique Structural Changes in Calcium-Bound Calmodulin Upon Interaction with Protein 4.1R FERM Domain: Novel Insights into the Calcium-dependent Regulation of 4.1R FERM Domain Binding to Membrane Proteins by Calmodulin

Calmodulin (CaM) binds to the FERM domain of 80 kDa erythrocyte protein 4.1R (R30) independently of Ca²⁺ but, paradoxically, regulates R30 binding to transmembrane proteins in a Ca²⁺-dependent manner. We have previously mapped a Ca²⁺-independent CaM-binding site, pep11 (A²⁶⁴KKLWKVCVEHHTFFR), in 4.1R FERM domain and demonstrated that CaM, when saturated by Ca²⁺ (Ca²⁺/CaM), interacts simultaneously with pep11 and with Ser¹⁸⁵ in A¹⁸¹KKLSMYGVDLHKAKD (pep9), the binding affinity of Ca²⁺/CaM for pep9 increasing dramatically in the presence of pep11. Based on these findings, we hypothesized that pep11 induced key conformational changes in the Ca²⁺/CaM complex. By differential scanning calorimetry analysis, we established that the C-lobe of CaM was more stable when bound to pep11 either in the presence or absence of Ca²⁺. Using nuclear magnetic resonance spectroscopy, we identified 8 residues in the N-lobe and 14 residues in the C-lobe of pep11 involved in interaction with CaM in both of presence and absence of Ca²⁺. Lastly, Kratky plots, generated by small-angle X-ray scattering analysis, indicated that the pep11/Ca²⁺/CaM complex adopted a relaxed globular shape. We propose that these unique properties may account in part for the previously described Ca²⁺/CaM-dependent regulation of R30 binding to membrane proteins.     

Dissecting cooperative calmodulin binding to CaM kinase II: a detailed stochastic model

Calmodulin (CaM) is a major Ca²⁺ binding protein involved in two opposing processes of synaptic plasticity of CA1 pyramidal neurons: long-term potentiation (LTP) and depression (LTD). The N- and C-terminal lobes of CaM bind to its target separately but cooperatively and introduce complex dynamics that cannot be well understood by experimental measurement. Using a detailed stochastic model constructed upon experimental data, we have studied the interaction between CaM and Ca²⁺-CaM-dependent protein kinase II (CaMKII), a key enzyme underlying LTP. The model suggests that the accelerated binding of one lobe of CaM to CaMKII, when the opposing lobe is already bound to CaMKII, is a critical determinant of the cooperative interaction between Ca²⁺, CaM, and CaMKII. The model indicates that the target-bound Ca²⁺ free N-lobe has an extended lifetime and may regulate the Ca²⁺ response of CaMKII during LTP induction. The model also reveals multiple kinetic pathways which have not been previously predicted for CaM-dissociation from CaMKII.     

Tropomyosin dynamics in cardiac thin filaments: a multisite forster resonance energy transfer and anisotropy study

Cryoelectron microscopy studies have identified distinct locations of tropomyosin (Tm) within the Ca²⁺-free, Ca²⁺-saturated, and myosin-S1-saturated states of the thin filament. On the other hand, steady-state Förster resonance energy transfer (FRET) studies using functional, reconstituted thin filaments under physiological conditions of temperature and solvent have failed to detect any movement of Tm upon Ca²⁺ binding. In this investigation, an optimized system for FRET and anisotropy analyses of cardiac tropomyosin (cTm) dynamics was developed that employed a single tethered donor probe within a Tm dimer. Multisite FRET and fluorescence anisotropy analyses showed that S1 binding to Ca²⁺ thin filaments triggered a uniform displacement of cTm toward F-actin but that Ca²⁺ binding alone did not change FRET efficiency, most likely due to thermally driven fluctuations of cTm on the thin filament that decreased the effective separation of the donor probe between the blocked and closed states. Although Ca²⁺ binding to the thin filament did not significantly change FRET efficiency, such a change was demonstrated when the thin filament was partially saturated with S1. FRET was also used to show that stoichiometric binding of S1 to Ca²⁺-activated thin filaments decreased the amplitude of Tm fluctuations and revealed a strong correlation between the cooperative binding of S1 to the closed state and the movement of cTm.     

Calmodulin·(Ca2+)4 is the active calmodulin-calcium species activating the calcium-, calmodulin-dependent protein kinase of cardiac sarcoplasmic reticulum in the regulation of the calcium pump

Calcium-, calmodulin-dependent phosphorylation of cardiac sarcoplasmic reticulum increases the rate of calcium transport. The complex dependence of calmodulin-dependent phosphoester formation on free calcium and total calmodulin concentrations can be satisfactorily explained by assuming that CaM · (Ca²⁺)₄ is the sole calmodulin-calcium species which activates the calcium-, calmodulin-dependent, membrane-bound protein kinase. The apparent dissociation constant of the E · CaM · (Ca²⁺)₄ complex determined from the calcium dependence of calmodulin-dependent phosphoester formation over a 100-fold range of total calmodulin concentrations (0.01–1 μ M) was 0.9 nM; the respective apparent dissoclation constant at 0.8 mM free calcium, 1 mM free magnesium with low calmodulin concentrations (0.1–50 nM) was 2.60 nM. These results are in good agreement with the apparent dissociation constant of 2.54 nM of high affinity calmodulin binding determined by ¹²⁵I-labelled calmodulin binding to sarcoplasmic reticulum fractions at 1 mM free calcium, 1 mM free magnesium and total calmodulin concentration ranging from 0.1 to 150 nM, i.e. conditions where approximately 98% of the total calmodulin is present as CaM · (Ca²⁺)₄. The apparent dissociation constant of the calcium-free calmodulin-enzyme complex (E · CaM) is at least 100-fold greater than the apparent dissociation constant of the E · CaM · (Ca²⁺)₄ complex, as judged from non-saturation ¹²⁵I-labelled calmodulin binding at total calmodulin concentrations of up to 150 nM, in the absence of calcium.     

The Potassium Channel Interacting Protein 3 (DREAM/KChIP3) Heterodimerizes with and Regulates Calmodulin Function

Downstream regulatory element antagonistic modulator (DREAM/KChIP3), a neuronal EF-hand protein, modulates pain, potassium channel activity, and binds presenilin 1. Using affinity capture of neuronal proteins by immobilized DREAM/KChIP3 in the presence and absence of calcium (Ca²⁺) followed by mass spectroscopic identification of interacting proteins, we demonstrate that in the presence of Ca²⁺, DREAM/KChIP3 interacts with the EF-hand protein, calmodulin (CaM). The interaction of DREAM/KChIP3 with CaM does not occur in the absence of Ca²⁺. In the absence of Ca²⁺, DREAM/KChIP3 binds the EF-hand protein, calcineurin subunit-B. Ca²⁺-bound DREAM/KChIP3 binds CaM with a dissociation constant of ∼3 μm as assessed by changes in DREAM/KChIP3 intrinsic protein fluorescence in the presence of CaM. Two-dimensional ¹H,¹⁵N heteronuclear single quantum coherence spectra reveal changes in chemical shifts and line broadening upon the addition of CaM to ¹⁵N DREAM/KChIP3. The amino-terminal portion of DREAM/KChIP3 is required for its binding to CaM because a construct of DREAM/KChIP3 lacking the first 94 amino-terminal residues fails to bind CaM as assessed by fluorescence spectroscopy. The addition of Ca²⁺-bound DREAM/KChIP3 increases the activation of calcineurin (CN) by calcium CaM. A DREAM/KChIP3 mutant incapable of binding Ca²⁺ also stimulates calmodulin-dependent CN activity. The shortened form of DREAM/KChIP3 lacking the NH₂-terminal amino acids fails to activate CN in the presence of calcium CaM. Our data demonstrate the interaction of DREAM/KChIP3 with the important EF-hand protein, CaM, and show that the interaction alters CN activity.     

Study of conformational rearrangement and refinement of structural homology models by the use of heteronuclear dipolar couplings

For an increasing fraction of proteins whose structures are being studied, sequence homology to known structures permits building of low resolution structural models. It is demonstrated that dipolar couplings, measured in a liquid crystalline medium, not only can validate such structural models, but also refine them. Here, experimental ¹H-¹⁵N, ¹H-¹³C, and ¹³C-¹³C dipolar couplings are shown to decrease the backbone rmsd between various homology models of calmodulin (CaM) and its crystal structure. Starting from a model of the Ca²⁺-saturated C-terminal domain of CaM, built from the structure of Ca²⁺-free recoverin on the basis of remote sequence homology, dipolar couplings are used to decrease the rmsd between the model and the crystal structure from 5.0 to 1.25 Å. A better starting model, built from the crystal structure of Ca²⁺-saturated parvalbumin, decreases in rmsd from 1.25 to 0.93 Å. Similarly, starting from the structure of the Ca²⁺-ligated CaM N-terminal domain, experimental dipolar couplings measured for the Ca²⁺-free form decrease the backbone rmsd relative to the refined solution structure of apo-CaM from 4.2 to 1.0 Å.