Solution Structure of Calmodulin Bound to the Binding Domain of the HIV-1 Matrix Protein

Subcellular distribution of calmodulin (CaM) in human immunodeficiency virus type-1 (HIV-1)-infected cells is distinct from that observed in uninfected cells. CaM co-localizes and interacts with the HIV-1 Gag protein in the cytosol of infected cells. Although it has been shown that binding of Gag to CaM is mediated by the matrix (MA) domain, the structural details of this interaction are not known. We have recently shown that binding of CaM to MA induces a conformational change that triggers myristate exposure, and that the CaM-binding domain of MA is confined to a region spanning residues 8–43 (MA-(8–43)). Here, we present the NMR structure of CaM bound to MA-(8–43). Our data revealed that MA-(8–43), which contains a novel CaM-binding motif, binds to CaM in an antiparallel mode with the N-terminal helix (α1) anchored to the CaM C-terminal lobe, and the C-terminal helix (α2) of MA-(8–43) bound to the N-terminal lobe of CaM. The CaM protein preserves a semiextended conformation. Binding of MA-(8–43) to CaM is mediated by numerous hydrophobic interactions and stabilized by favorable electrostatic contacts. Our structural data are consistent with the findings that CaM induces unfolding of the MA protein to have access to helices α1 and α2. It is noteworthy that several MA residues involved in CaM binding have been previously implicated in membrane binding, envelope incorporation, and particle production. The present findings may ultimately help in identification of the functional role of CaM in HIV-1 replication.     

Structural and Biophysical Characterization of the Interactions between Calmodulin and the Pleckstrin Homology Domain of Akt

The translocation of Akt, a serine/threonine kinase, to the plasma membrane is a critical step in the Akt activation pathway. It is established that membrane binding of Akt is mediated by direct interactions between its pleckstrin homology domain (PHD) and phosphatidylinositol 3,4,5-trisphosphate (PI(3,4,5)P₃). There is now evidence that Akt activation in many breast cancer cells is also modulated by the calcium-binding protein, calmodulin (CaM). Upon EGF stimulation of breast cancer cells, CaM co-localizes with Akt at the plasma membrane to enhance activation. However, the molecular details of Akt(PHD) interaction with CaM are not known. In this study, we employed NMR, biochemical, and biophysical techniques to characterize CaM binding to Akt(PHD). Our data show that CaM forms a tight complex with the PHD of Akt (dissociation constant = 100 nm). The interaction between CaM and Akt(PHD) is enthalpically driven, and the affinity is greatly dependent on salt concentration, indicating that electrostatic interactions are important for binding. The CaM-binding interface in Akt(PHD) was mapped to two loops adjacent to the PI(3,4,5)P₃ binding site, which represents a rare CaM-binding motif and suggests a synergistic relationship between CaM and PI(3,4,5)P₃ upon Akt activation. Elucidation of the mechanism by which Akt interacts with CaM will help in understanding the activation mechanism, which may provide insights for new potential targets to control the pathophysiological processes of cell survival.     

Ionic interactions are essential for TRPV1 C-terminus binding to calmodulin

Calmodulin (CaM) is known to play an important role in the regulation of TRP channels activity. Although it has been reported that CaM binds to the C-terminus of TRPV1 (TRPV1-CT), no classic CaM-binding motif was found in this region. In this work, we explored this unusual TRPV1 CaM-binding motif in detail and found that five residues from a putative CaM-binding motif are important for TRPV1-CT’s binding to CaM, with arginine R785 being the most essential residue. The homology modelling suggests that a CaM-binding motif of TRPV1-CT forms an alpha helix that docks into the central cavity of CaM.     

Calmodulin signaling: analysis and prediction of a disorder-dependent molecular recognition

Calmodulin (CaM) signaling involves important, wide spread eukaryotic protein-protein interactions. The solved structures of CaM associated with several of its binding targets, the distinctive binding mechanism of CaM, and the significant trypsin sensitivity of the binding targets combine to indicate that the process of association likely involves coupled binding and folding for both CaM and its binding targets. Here, we use bioinformatics approaches to test the hypothesis that CaM-binding targets are intrinsically disordered. We developed a predictor of CaM-binding regions and estimated its performance. Per residue accuracy of this predictor reached 81%, which, in combination with a high recall/precision balance at the binding region level, suggests high predictability of CaM-binding partners. An analysis of putative CaM-binding proteins in yeast and human strongly indicates that their molecular functions are related to those of intrinsically disordered proteins. These findings add to the growing list of examples in which intrinsically disordered protein regions are indicated to provide the basis for cell signaling and regulation.     

Identification of the calmodulin binding domain of connexin 43

Calmodulin (CaM) has been implicated in mediating the Ca(2+)-dependent regulation of gap junctions. This report identifies a CaM-binding motif comprising residues 136-158 in the intracellular loop of Cx43. A 23-mer peptide encompassing this CaM-binding motif was shown to bind Ca(2+)-CaM with 1:1 stoichiometry by using various biophysical approaches, including surface plasmon resonance, circular dichroism, fluorescence spectroscopy, and NMR. Far UV circular dichroism studies indicated that the Cx43-derived peptide increased its alpha-helical contents on CaM binding. Fluorescence and NMR studies revealed conformational changes of both the peptide and CaM following formation of the CaM-peptide complex. The apparent dissociation constant of the peptide binding to CaM in physiologic K(+) is in the range of 0.7-1 microM. Upon binding of the peptide to CaM, the apparent K(d) of Ca(2+) for CaM decreased from 2.9 +/- 0.1 to 1.6 +/- 0.1 microM, and the Hill coefficient n(H) increased from 2.1 +/- 0.1 to 3.3 +/- 0.5. Transient expression in HeLa cells of two different mutant Cx43-EYFP constructs without the putative Cx43 CaM-binding site eliminated the Ca(2+)-dependent inhibition of Cx43 gap junction permeability, confirming that residues 136-158 in the intracellular loop of Cx43 contain the CaM-binding site that mediates the Ca(2+)-dependent regulation of Cx43 gap junctions. Our results provide the first direct evidence that CaM binds to a specific region of the ubiquitous gap junction protein Cx43 in a Ca(2+)-dependent manner, providing a molecular basis for the well characterized Ca(2+)-dependent inhibition of Cx43-containing gap junctions.     

钙不依赖性钙调素结合蛋白的研究进展

钙调素是普遍存在于真核生物细胞中、发挥多种生物学调控作用的信号组分.钙调素不仅在有Ca2 情况下通过与钙依赖性钙调素结合蛋白作用而传递信号,也能在相对无Ca2 条件下直接结合钙不依赖性钙调素结合蛋白而传递信号.综述了无钙离子结合钙调素及钙不依赖性钙调素结合蛋白的结构特性、钙不依赖性钙调素结合蛋白的种类及其可能的生物学作用,这将有助于我们深入认识钙调素介导信号途径的特异性、复杂性和多样性.     

Physical interaction of calmodulin with the 5-hydroxytryptamine2C receptor C-terminus is essential for G protein-independent, arrestin-dependent receptor signaling

The serotonin (5-hydroxytryptamine; 5-HT)_2C receptor is a G protein-coupled receptor (GPCR) exclusively expressed in CNS that has been implicated in numerous brain disorders, including anxio-depressive states. Like many GPCRs, 5-HT_2C receptors physically interact with a variety of intracellular proteins in addition to G proteins. Here, we show that calmodulin (CaM) binds to a prototypic Ca²⁺-dependent “1-10” CaM-binding motif located in the proximal region of the 5-HT_2C receptor C-terminus upon receptor activation by 5-HT. Mutation of this motif inhibited both β-arrestin recruitment by 5-HT_2C receptor and receptor-operated extracellular signal-regulated kinase (ERK) 1,2 signaling in human embryonic kidney-293 cells, which was independent of G proteins and dependent on β-arrestins. A similar inhibition was observed in cells expressing a dominant-negative CaM or depleted of CaM by RNA interference. Expression of the CaM mutant also prevented receptor-mediated ERK1,2 phosphorylation in cultured cortical neurons and choroid plexus epithelial cells that endogenously express 5-HT_2C receptors. Collectively, these findings demonstrate that physical interaction of CaM with recombinant and native 5-HT_2C receptors is critical for G protein-independent, arrestin-dependent receptor signaling. This signaling pathway might be involved in neurogenesis induced by chronic treatment with 5-HT_2C receptor agonists and their antidepressant-like activity.     

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.     

Regulation of a recombinant pea nuclear apyrase by calmodulin and casein kinase II

A cDNA encoding a pea nuclear apyrase was previously cloned. Overexpressions of a full-length and a truncated cDNA have been successfully expressed in Escherichia coli BL21(DE3). The resulting fusion proteins, apyrase and the C-terminus (residues 315-453) of apyrase, were used for calmodulin (CaM) binding and phosphorylation studies. Fusion protein apyrase but not the C-terminus of apyrase can be recognized by polyclonal antibody pc480. This suggested that the motif recognized by pc480 was located in the N-terminal region of apyrase. The recombinant apyrase protein also showed an activity 70 times higher than that of endogenous apyrase using ATP as a substrate. The recombinant apyrase has a preference for ATP more than other nucleoside triphosphate substrates. CaM can bind to recombinant apyrase, but not to the C-terminus of apyrase. This implies that the CaM-binding domain must be in the first 315 amino acids of the N-terminal region of apyrase. We found that one segment from residue 293 to 308 was a good candidate for the CaM-binding domain. This segment 293 FNKCKNTIRKALKLNY 308 has a basic amphiphilic-helical structure, which shows the predominance of basic residues on one side and hydrophobic residues on the other when displayed on a helical wheel plot. Using the gel mobility shift binding assay, this synthetic peptide was shown to bind to CaM, indicating that it is the CaM-binding domain. Both recombinant apyrase and the C-terminus of apyrase can be phosphorylated by a recombinant human protein kinase CKII. Phosphorylation does not affect CaM binding to recombinant apyrase. However, CaM does inhibit CKII phosphorylation of recombinant apyrase and this inhibition can be blocked by 5 mM EGTA.     

Isolation and characterization of a novel calmodulin-binding protein from potato.

Tuberization in potato is controlled by hormonal and environmental signals. Ca(2+), an important intracellular messenger, and calmodulin (CaM), one of the primary Ca(2+) sensors, have been implicated in controlling diverse cellular processes in plants including tuberization. The regulation of cellular processes by CaM involves its interaction with other proteins. To understand the role of Ca(2+)/CaM in tuberization, we have screened an expression library prepared from developing tubers with biotinylated CaM. This screening resulted in isolation of a cDNA encoding a novel CaM-binding protein (potato calmodulin-binding protein (PCBP)). Ca(2+)-dependent binding of the cDNA-encoded protein to CaM is confirmed by (35)S-labeled CaM. The full-length cDNA is 5 kb long and encodes a protein of 1309 amino acids. The deduced amino acid sequence showed significant similarity with a hypothetical protein from another plant, Arabidopsis. However, no homologs of PCBP are found in nonplant systems, suggesting that it is likely to be specific to plants. Using truncated versions of the protein and a synthetic peptide in CaM binding assays we mapped the CaM-binding region to a 20-amino acid stretch (residues 1216-1237). The bacterially expressed protein containing the CaM-binding domain interacted with three CaM isoforms (CaM2, CaM4, and CaM6). PCBP is encoded by a single gene and is expressed differentially in the tissues tested. The expression of CaM, PCBP, and another CaM-binding protein is similar in different tissues and organs. The predicted protein contained seven putative nuclear localization signals and several strong PEST motifs. Fusion of the N-terminal region of the protein containing six of the seven nuclear localization signals to the reporter gene beta-glucuronidase targeted the reporter gene to the nucleus, suggesting a nuclear role for PCBP.     

Matrin 3 is a Ca2+/calmodulin-binding protein cleaved by caspases

Matrin 3 is a nuclear matrix protein that has been implicated in interacting with other nuclear proteins to anchor hyperedited RNAs to the nuclear matrix, in modulating the activity of proximal promoters, and as the main PKA substrate following NMDA receptor activation. In our proteome-wide selections for calmodulin (CaM) binding proteins and for caspase substrates using mRNA-displayed human proteome libraries, matrin 3 was identified as both a Ca(2+)-dependent CaM-binding protein and a downstream substrate of caspases. We report here, the in vitro characterization of the CaM-binding motif and the caspase cleavage site on matrin 3. Significantly, the Ca(2+)/CaM-binding motif is partially overlapped by the RRM of matrin 3 and is also very close to the bipartite NLS that is essential for its nuclear localization. The caspase cleavage site is downstream of the NLS but upstream of the second U1-like zinc finger. Our results suggest that the functions of matrin 3 could be regulated by both Ca(2+)-dependent interaction with CaM and caspase-mediated cleavage.     

Structural uncoupling between opposing domains of oxidized calmodulin underlies the enhanced binding affinity and inhibition of the plasma membrane Ca-ATPase

Stabilization of the plasma membrane Ca-ATPase (PMCA) in an inactive conformation upon oxidation of multiple methionines in the calcium regulatory protein calmodulin (CaM) is part of an adaptive cellular response to minimize ATP utilization and the generation of reactive oxygen species (ROS) under conditions of oxidative stress. To differentiate oxidant-induced structural changes that selectively modify the amino-terminal domain of CaM from those that modulate the conformational coupling between the opposing domains, we have engineered a tetracysteine binding motif within helix A in the amino-terminal domain of calmodulin (CaM) that permits the selective and rigid attachment of the conformationally sensitive fluorescent probe 4',5'-bis(1,3,2-dithioarsolan-2-yl)fluorescein-(1,2-ethanedithiol)(2) (FlAsH-EDT(2)). The position of the FlAsH label in the amino-terminal domain provides a signal for monitoring its binding to the CaM-binding sequence of the PMCA. Following methionine oxidation, there is an enhanced binding affinity between the amino-terminal domain and the CaM-binding sequence of the PMCA. To identify oxidant-induced structural changes, we used frequency domain fluorescence anisotropy measurements to assess the structural coupling between helix A and the amino- and carboxyl-terminal domains of CaM. Helix A undergoes large amplitude motions in apo-CaM; following calcium activation, helix A is immobilized as part of a conformational switch that couples the opposing domains of CaM to stabilize the high-affinity binding cleft associated with target protein binding. Methionine oxidation disrupts the structural coupling between opposing globular domains of CaM, without affecting the calcium-dependent immobilization of helix A associated with activation of the amino-terminal domain to promote high-affinity binding to target proteins. We suggest that this selective disruption of the structural linkage between the opposing globular domains of CaM relieves steric constraints associated with high-affinity target binding, permitting the formation of new contact interactions between the amino-terminal domain and the CaM-binding sequence that stabilizes the PMCA in an inhibited conformation.     

The identification and characterization of a noncontinuous calmodulin-binding site in noninactivating voltage-dependent KCNQ potassium channels

We show here that in a yeast two-hybrid assay calmodulin (CaM) interacts with the intracellular C-terminal region of several members of the KCNQ family of potassium channels. CaM co-immunoprecipitates with KCNQ2, KCNQ3, or KCNQ5 subunits better in the absence than in the presence of Ca2+. Moreover, in two-hybrid assays where it is possible to detect interactions with apo-CaM but not with Ca2+-bound calmodulin, we localized the CaM-binding site to a region that is predicted to contain two alpha-helices (A and B). These two helices encompass approximately 85 amino acids, and in KCNQ2 they are separated by a dispensable stretch of approximately 130 amino acids. Within this CaM-binding domain, we found an IQ-like CaM-binding motif in helix A and two overlapping consensus 1-5-10 CaM-binding motifs in helix B. Point mutations in helix A or B were capable of abolishing CaM binding in the two-hybrid assay. Moreover, glutathione S-transferase fusion proteins containing helices A and B were capable of binding to CaM, indicating that the interaction with KCNQ channels is direct. Full-length CaM (both N and C lobes) and a functional EF-1 hand were required for these interactions to occur. These observations suggest that apo-CaM is bound to neuronal KCNQ channels at low resting Ca2+ levels and that this interaction is disturbed when the [Ca2+] is raised. Thus, we propose that CaM acts as a mediator in the Ca2+-dependent modulation of KCNQ channels.     

Identification of the Calmodulin-Binding Domains of Fas Death Receptor

The extrinsic apoptotic pathway is initiated by binding of a Fas ligand to the ectodomain of the surface death receptor Fas protein. Subsequently, the intracellular death domain of Fas (FasDD) and that of the Fas-associated protein (FADD) interact to form the core of the death-inducing signaling complex (DISC), a crucial step for activation of caspases that induce cell death. Previous studies have shown that calmodulin (CaM) is recruited into the DISC in cholangiocarcinoma cells and specifically interacts with FasDD to regulate the apoptotic/survival signaling pathway. Inhibition of CaM activity in DISC stimulates apoptosis significantly. We have recently shown that CaM forms a ternary complex with FasDD (2:1 CaM:FasDD). However, the molecular mechanism by which CaM binds to two distinct FasDD motifs is not fully understood. Here, we employed mass spectrometry, nuclear magnetic resonance (NMR), biophysical, and biochemical methods to identify the binding regions of FasDD and provide a molecular basis for the role of CaM in Fas–mediated apoptosis. Proteolytic digestion and mass spectrometry data revealed that peptides spanning residues 209–239 (Fas-Pep1) and 251–288 (Fas-Pep2) constitute the two CaM-binding regions of FasDD. To determine the molecular mechanism of interaction, we have characterized the binding of recombinant/synthetic Fas-Pep1 and Fas-Pep2 peptides with CaM. Our data show that both peptides engage the N- and C-terminal lobes of CaM simultaneously. Binding of Fas-Pep1 to CaM is entropically driven while that of Fas-Pep2 to CaM is enthalpically driven, indicating that a combination of electrostatic and hydrophobic forces contribute to the stabilization of the FasDD–CaM complex. Our data suggest that because Fas-Pep1 and Fas-Pep2 are involved in extensive intermolecular contacts with the death domain of FADD, binding of CaM to these regions may hinder its ability to bind to FADD, thus greatly inhibiting the initiation of apoptotic signaling pathway.     

Different conformational switches underlie the calmodulin-dependent modulation of calcium pumps and channels

We have used fluorescence spectroscopy to investigate the structure of calmodulin (CaM) bound with CaM-binding sequences of either the plasma membrane Ca-ATPase or the skeletal muscle ryanodine receptor (RyR1) calcium release channel. Following derivatization with N-(1-pyrene)maleimide at engineered sites (T34C and T110C) within the N- and C-domains of CaM, contact interactions between these opposing domains of CaM resulted in excimer fluorescence that permits us to monitor conformational states of bound CaM. Complementary measurements take advantage of the unique conserved Trp within CaM-binding sequences that functions as a hydrophobic anchor in CaM binding and permits measurements of both a local and global peptide structure. We find that CaM binds with high affinity in a collapsed structure to the CaM-binding sequences of both the Ca-ATPase and RyR1, resulting in excimer formation that is indicative of contact interactions between the N- and the C-domains of CaM in complex with these CaM-binding peptides. There is a 4-fold larger amount of excimer formation for CaM bound to the CaM-binding sequence of the Ca-ATPase in comparison to RyR1, indicating a closer structural coupling between CaM domains in this complex. Prior to CaM association, the CaM-binding sequences of the Ca-ATPase and RyR1 are conformationally disordered. Upon CaM association, the CaM-binding sequence of the Ca-ATPase assumes a highly ordered structure. In comparison, the CaM-binding sequence of RyR1 remains conformationally disordered irrespective of CaM binding. These results suggest an important role for interdomain contact interactions between the opposing domains of CaM in stabilizing the structure of the peptide complex. The substantially different structural responses associated with CaM binding to Ca-ATPase and RyR1 indicates a plasticity in their respective binding mechanisms that accomplishes different physical mechanisms of allosteric regulation, involving either the dissociation of a C-terminal regulatory domain necessary for pump activation or the modulation of intersubunit interactions to diminish RyR1 channel activity.     

Calmodulin interaction with peptides from G-protein coupled receptors measured with S-Tag labeling

We have developed a quantitative assay of calmodulin (CaM) binding to S-Tag labeled peptides derived from G-protein coupled receptor (GPCR) sequences. CaM binding of peptides derived from the third intracellular loop (i3) of mu opioid receptor (MOR) was confirmed and the CaM-binding motif refined. A MORi3 peptide with a Lys > Ala substitution--shown to reduce CaM-binding of intact MOR--bound fivefold less avidly than the wild-type peptide. Screening peptides derived from i3 loops of other GPCR families confirmed 5HT1A, and identified muscarinic receptor 3, and melanocortin receptor 1, as proteins carrying CaM-binding domains. The use of S-Tag labeling can serve for rapid screening of putative CaM-binding domains in GPCRs.     

Distribution of calmodulin and calmodulin-binding proteins in bovine pituitary: association of myosin light chain kinase with pituitary secretory granule membranes

Calcium is necessary for secretion of pituitary hormones. Many of the biological effects of Ca²⁺ are mediated by the Ca²⁺-binding protein calmodulin (CaM), which interacts specifically with proteins regulated by the Ca²⁺-CaM complex. One of these proteins is myosin light chain kinase (MLCK), a Ca²⁺-calmodulin dependent enzyme that phosphorylates the regulatory light chains of myosin, and has been implicated in motile processes in both muscle and non-muscle tissues. We determined the content and distribution of CaM and CaM-binding proteins in bovine pituitary homogenates, and subcellular fractions including secretory granules and secretory granule membranes. CaM measured by radioimmunoassay was found in each fraction; although approximately one-half was in the cytosolic fraction, CaM was also associated with the plasma membrane and secretory granule fractions. CaM-binding proteins were identified by an ²⁵¹-CaM gel overlay technique and quantitated by densitometric analysis of the autoradiograms. Pituitary homogenates contained nine major CaM-binding proteins of 146, 131, 90, 64, 58, 56, 52, 31 and 22 kilodaltons (kDa). Binding to all the bands was specific, Cat+-sensitive, and displaceable with excess unlabeled CaM. Severe heat treatment (100°C, 15 min), which results in a 75% reduction in phosphodiesterase activation by CaM, markedly decreased ²⁵¹I-CaM binding to all protein bands. Secretory granule membranes showed enhancement for CaM-binding proteins with molecular weights of 184, 146, 131, 90, and 52000. A specific, affinity purified antibody to chicken gizzard MLCK bound to the 146 kDa band in homogenates, centrifugal subcellular fractions, and secretory granule membranes. No such binding was associated with the granule contents. The enrichment of MLCK and other CaM-binding proteins in pituitary secretory granule membranes suggests a possible role for CaM and/or CaM-binding proteins in granule membrane function and possibly exocytosis.     

Calmodulin binding to the Fas death domain. Regulation by Fas activation

Fas (APO-1/CD95) is a cell surface receptor that initiates apoptotic pathways, and its cytoplasmic domain interacts with various molecules suggesting that Fas signaling is complex and regulated by multiple proteins. Calmodulin (CaM) is an intracellular Ca(2+)-binding protein, and it mediates many of the effects of Ca2+. Here, we demonstrate that CaM binds to Fas directly and identify the CaM-binding site on the cytoplasmic death domain (DD) of Fas. Fas binds to CaM-Sepharose and is co-immunoprecipitated with CaM. Other death receptors, such as tumor necrosis factor receptor, DR4, and DR5 do not bind to CaM. The interaction between Fas and CaM is Ca(2+)-dependent. Deletion mapping analysis with various GST-fused Fas cytoplasmic domain fragments revealed that the fragment containing helices 1, 2, and 3 of the Fas DD has the CaM-binding ability. Sequence analysis of this fragment predicted a potential CaM-binding site in helix 2 and connected loops. A valine 254 to asparagine mutation in this region, which is analogous to the identified mutant allele of Fas in lpr mice that have a deficiency in Fas-mediated apoptosis, showed reduced CaM binding. Computer modeling of the interaction between CaM and helix 2 of the Fas DD predicted that amino acids, which are important for Fas-CaM binding, and point mutations of these amino acids caused reduced Fas-CaM binding. The interaction between Fas and CaM is increased approximately 2-fold early upon Fas activation (at 30 min) and is decreased to approximately 50% of control at 2 h. These findings suggest a novel function of CaM in Fas-mediated apoptosis.     

Identification of a conserved calmodulin-binding motif in the sequence of F0F1 ATPsynthase inhibitor protein

The natural inhibitor proteins IF1 regulate mitochondrial F0F1 ATPsynthase in a wide range of species. We characterized the interaction of CaM with purified bovine IF1, two bovine IF1 synthetic peptides, as well as two homologous proteins from yeast, namely IF1 and STF1. Fluorometric analyses showed that bovine and yeast inhibitors bind CaM with a 1:1 stoichiometry in the pH range between 5 and 8 and that CaM-IF1 interaction is Ca2+-dependent. Bovine and yeast IF1 have intermediate binding affinity for CaM, while the Kd (dissociation constant) of the STF1-CaM interaction is slightly higher. Binding studies of CaM with bovine IF1 synthetic peptides allowed us to identify bovine IF1 sequence 33-42 as the putative CaM-binding region. Sequence alignment revealed that this region contains a hydrophobic motif for CaM binding, highly conserved in both yeast IF1 and STF1 sequences. In addition, the same region in bovine IF1 has an IQ motif for CaM binding, conserved as an IQ-like motif in yeast IF1 but not in STF1. Based on the pH and Ca2+ dependence of IF1 interaction with CaM, we suggest that the complex can be formed outside mitochondria, where CaM could regulate IF1 trafficking or additional IF1 roles not yet clarified.     

Structural determinants of calmodulin binding to the intracellular C-terminal domain of the metabotropic glutamate receptor 7A

Calmodulin (CaM) binds in a Ca2+-dependent manner to the intracellular C-terminal domains of most group III metabotropic glutamate receptors (mGluRs). Here we combined mutational and biophysical approaches to define the structural basis of CaM binding to mGluR 7A. Ca2+/CaM was found to interact with mGluR 7A primarily via its C-lobe at a 1:1 CaM:C-tail stoichiometry. Pulldown experiments with mutant CaM and mGluR 7A C-tail constructs and high resolution NMR with peptides corresponding to the CaM binding region of mGluR 7A allowed us to define hydrophobic and ionic interactions required for Ca2+/CaM binding and identified a 1-8-14 CaM-binding motif. The Ca2+/CaM.mGluR 7A peptide complex displays a classical wraparound structure that closely resembles that formed by Ca2+/CaM upon binding to smooth muscle myosin light chain kinase. Our data provide insight into how Ca2+/CaM regulates group III mGluR signaling via competition with intracellular proteins for receptor-binding sites.