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.     

Closer proximity between opposing domains of vertebrate calmodulin following deletion of Met(145)-Lys(148)

To investigate the structural linkage between the opposing globular domains in vertebrate calmodulin (CaM), we have constructed a CaM mutant (CaMX(145)) deficient in the last four amino acids between Met(145) and Lys(148) at the carboxyl terminal. Circular dichroism and fluorescence spectroscopic measurements were used to detect changes in the average secondary and tertiary structure of CaMX(145) in comparison to full-length CaM. Complementary measurements of the maximal calcium-binding stoichiometry and ability to activate the plasma membrane (PM) Ca-ATPase permit an assessment of the functional significance of observed structural changes. In comparison with native CaM, we find that CaMX(145) exhibits (i) a large reduction in alpha-helical content, (ii) a dramatic decrease in the average spatial separation between the opposing globular domains, (iii) the loss of one high-affinity calcium-binding site, and (iv) a diminished binding affinity for the PM-Ca-ATPase. Thus, the sequence near the carboxyl terminus functions to stabilize high-affinity calcium binding at one site and facilitates important intramolecular interactions that maintain CaM in an extended conformation. However, despite the large conformational changes resulting from deletion of the last four amino acids at the carboxyl terminal, CaMX(145) can fully activate the PM-Ca-ATPase. These results indicate that target protein binding can restore the nativelike structure critical to function, emphasizing that the structure of the central helix is not critical to CaM function under equilibrium conditions. Rather, the central helix functions to maintain the spatial separation between the opposing domains in CaM that may be critical to high-affinity binding and the rapid activation of the PM-Ca-ATPase, which are necessary for optimal calcium signaling. Thus, following initial association between CaM and target proteins, structural changes involving the carboxyl-terminal sequence have the potential to play an important role in triggering the structural collapse of CaM that facilitates the rapid and cooperative binding of the opposing globular domains with target proteins, which is important to high-affinity binding and rapid enzyme activation.     

Dynamic motion of helix A in the amino-terminal domain of calmodulin is stabilized upon calcium activation

Calcium-dependent changes in the internal dynamics and average structures of the opposing globular domains of calmodulin (CaM), as well as their relative spatial arrangement, contribute to the productive association between CaM and a range of different target proteins, affecting their functional activation. To identify dynamic structural changes involving individual alpha-helical elements and their modulation by calcium activation, we have used site-directed mutagenesis to engineer a tetracysteine binding motif within helix A near the amino terminus of calmodulin (CaM), permitting the selective and rigid attachment of the fluorescent probe 4',5'-bis(1,3,2-dithioarsolan-2-yl)fluorescein (FlAsH) with full retention of function. The rigid tetracoordinate linkage of FlAsH to CaM, in conjunction with frequency domain fluorescence anisotropy measurements, allows assessment of dynamic changes associated with calcium activation without interference from independent probe motion. Taking advantage of the large fluorescence enhancement associated with binding of FlAsH to CaM, we determined rates of binding of FlAsH to apo-CaM and calcium-activated CaM to be 2800 +/- 80 and 310 +/- 10 M(-)(1) s(-)(1), respectively. There is no difference in the solvent accessibility of the bound FlAsH irrespective of calcium binding to CaM. Thus, given that FlAsH selectively labels disordered structures, the large difference in rates of FlAsH binding indicates that calcium binding stabilizes helix A. Frequency domain anisotropy measurements of bound FlAsH indicate that prior to calcium activation, helix A undergoes large amplitude nanosecond motions. Following calcium activation, helix A becomes immobile, and structurally coupled to the overall rotation of CaM. We discuss these results in the context of a model that suggests stabilization of helix A relative to other domain elements in the CaM structure is critical to defining high-affinity binding clefts, and in promoting specific and ordered binding of the opposing lobes of CaM to target proteins.     

Loss of conformational stability in calmodulin upon methionine oxidation.

We have used electrospray ionization mass spectrometry (ESI-MS), circular dichroism (CD), and fluorescence spectroscopy to investigate the secondary and tertiary structural consequences that result from oxidative modification of methionine residues in wheat germ calmodulin (CaM), and prevent activation of the plasma membrane Ca-ATPase. Using ESI-MS, we have measured rates of modification and molecular mass distributions of oxidatively modified CaM species (CaMox) resulting from exposure to H2O2. From these rates, we find that oxidative modification of methionine to the corresponding methionine sulfoxide does not predispose CaM to further oxidative modification. These results indicate that methionine oxidation results in no large-scale alterations in the tertiary structure of CaMox, because the rates of oxidative modification of individual methionines are directly related to their solvent exposure. Likewise, CD measurements indicate that methionine oxidation results in little change in the apparent alpha-helical content at 28 degrees C, and only a small (0.3 +/- 0.1 kcal mol(-1)) decrease in thermal stability, suggesting the disruption of a limited number of specific noncovalent interactions. Fluorescence lifetime, anisotropy, and quenching measurements of N-(1-pyrenyl)-maleimide (PMal) covalently bound to Cys26 indicate local structural changes around PMal in the amino-terminal domain in response to oxidative modification of methionine residues in the carboxyl-terminal domain. Because the opposing globular domains remain spatially distant in both native and oxidatively modified CaM, the oxidative modification of methionines in the carboxyl-terminal domain are suggested to modify the conformation of the amino-terminal domain through alterations in the structural features involving the interdomain central helix. The structural basis for the linkage between oxidative modification and these global conformational changes is discussed in terms of possible alterations in specific noncovalent interactions that have previously been suggested to stabilize the central helix in CaM.     

Mutation of Tyr138 disrupts the structural coupling between the opposing domains in vertebrate calmodulin

We have used circular dichroism and frequency-domain fluorescence spectroscopy to determine how the site-specific substitution of Tyr138 with either Phe138 or Gln138 affects the structural coupling between the opposing domains of calmodulin (CaM). A double mutant was constructed involving conservative substitution of Tyr99 --> Trp99 and Leu69 --> Cys69 to assess the structural coupling between the opposing domains, as previously described [Sun, H., Yin, D., and Squier, T. C. (1999) Biochemistry 38, 12266-12279]. Trp99 acts as a fluorescence resonance energy transfer (FRET) donor in distance measurements to probe the conformation of the central helix. Cys69 provides a reactive group for the covalent attachment of 5-((((2-iodoacetyl)amino)ethyl)amino)naphthalene-1-sulfonic acid (IAEDANS), which functions as a FRET acceptor and permits the measurement of the rotational dynamics of the amino-terminal domain. These CaM mutants demonstrate normal calcium-dependent gel-mobility shifts and changes in their near-UV CD spectra, have similar secondary structures to wild-type CaM following calcium activation, and retain the ability to fully activate the plasma membrane Ca-ATPase. The global folds, therefore, of both the carboxyl- and amino-terminal domains in these CaM mutants are similar to that of wild-type CaM. However, in comparison to wild-type CaM, the substitution of Tyr138 with either Phe138 or Gln138 results in (i) alterations in the average spatial separation and increases in the conformational heterogeneity between the opposing globular domains and (ii) the independent rotational dynamics of the amino-terminal domain. These results indicate that alterations in either the hydrogen bond between Tyr138 and Glu82 or contact interactions between aromatic amino acid side chains have the potential to initiate the structural collapse of CaM normally associated with target protein binding and activation.     

Calcium-dependent structural coupling between opposing globular domains of calmodulin involves the central helix.

We have used fluorescence spectroscopy to investigate the average structure and extent of conformational heterogeneity associated with the central helix in calmodulin (CaM), a sequence that contributes to calcium binding sites 2 and 3 and connects the amino- and carboxyl-terminal globular domains. Using site-directed mutagenesis, a double mutant was constructed involving conservative substitution of Tyr(99) --> Trp(99) and Leu(69) --> Cys(69) with no significant effect on the secondary structure of CaM. These mutation sites are at opposite ends of the central helix. Trp(99) acts as a fluorescence resonance energy transfer (FRET) donor in distance measurements of the conformation of the central helix. Cys(69) provides a reactive group for the covalent attachment of the FRET acceptor 5-((((2-iodoacetyl)amino)ethyl)amino)naphthalene-1-sulfonic acid (IAEDANS). AEDANS-modified CaM fully activates the plasma membrane (PM) Ca-ATPase, indicating that the native structure is retained following site-directed mutagenesis and chemical modification. We find that the average spatial separation between Trp(99) and AEDANS covalently bound to Cys(69) decreases by approximately 7 +/- 2 A upon calcium binding. However, irrespective of calcium binding, there is little change in the conformational heterogeneity associated with the central helix under physiologically relevant conditions (i.e., pH 7.5, 0.1 M KCl). These results indicate that calcium activation alters the spatial arrangement of the opposing globular domains between two defined conformations. In contrast, under conditions of low ionic strength or pH the structure of CaM is altered and the conformational heterogeneity of the central helix is decreased upon calcium activation. These results suggest the presence of important ionizable groups that affect the structure of the central helix, which may play an important role in mediating the ability of CaM to rapidly bind and activate target proteins.     

Calcium occupancy of N-terminal sites within calmodulin induces inhibition of the ryanodine receptor calcium release channel

Calmodulin (CaM) regulates calcium release from intracellular stores in skeletal muscle through its association with the ryanodine receptor (RyR1) calcium release channel, where CaM association enhances channel opening at resting calcium levels and its closing at micromolar calcium levels associated with muscle contraction. A high-affinity CaM-binding sequence (RyRp) has been identified in RyR1, which corresponds to a 30-residue sequence (i.e., K3614-N3643) located within the central portion of the primary sequence. However, it is presently unclear whether the identified CaM-binding sequence in association with CaM (a) senses calcium over the physiological range of calcium concentrations associated with RyR1 regulation or alternatively, (b) plays a structural role unrelated to the calcium-dependent modulation of RyR1 function. Therefore, we have measured the calcium-dependent activation of the individual domains of CaM in association with RyRp and their relationship to the CaM-dependent regulation of RyR1. These measurements utilize an engineered CaM, permitting the site-specific incorporation of N-(1-pyrene)maleimide at either T34C (PyN-CaM) or T110C (PyC-CaM) in the N- and C-domains, respectively. Consistent with prior measurements, we observe a high-affinity association of both apo-CaM and calcium-activated CaM with RyRp. Upon association with RyRp, fluorescence changes in PyN-CaM or PyC-CaM permit the measurement of the calcium-dependent activation of these individual domains. Fluorescence changes upon calcium activation of PyC-CaM in association with RyRp are indicative of high-affinity calcium-dependent activation of the C-terminal domain of CaM at resting calcium levels; at calcium levels associated with muscle contraction, activation of the N-terminal domain occurs with concomitant increases in the fluorescence intensity of PyC-CaM that is associated with structural changes within the CaM-binding sequence of RyR1. Occupancy of calcium-binding sites in the N-domain of CaM mirrors the calcium dependence of RyR1 inhibition observed at activating calcium levels, where [Ca]1/2 = 4.3 +/- 0.4 microM, suggesting a direct regulation of RyR1 function upon the calcium-dependent activation of CaM. These results indicate that occupancy of the N-terminal domain calcium binding sites in CaM bound to the identified CaM-binding sequence K3614-N3643 induces conformational rearrangements within the complex between CaM and RyR1 responsible for the CaM-dependent modulation of the RyR1 calcium release channel.     

Disruption of interdomain interactions via partial calcium occupancy of calmodulin

Binding of calcium to CaM exposes clefts in both N- and C-domains to promote their cooperative association with a diverse array of target proteins, functioning to relay the calcium signal regulating cellular metabolism. To clarify relationships between the calcium-dependent activation of individual domains and interdomain structural transitions associated with productive binding to target proteins, we have utilized three engineered CaM mutants that were covalently labeled with N-(1-pyrene) maleimide at introduced cysteines in the C- and N-domains, i.e., T110C (PyC-CaM), T34C (PyN-CaM), and T34C/T110C (Py2-CaM). These sites were designed to detect known conformers of CaM such that upon association with classical CaM-binding sequences, the pyrenes in Py2-CaM are brought close together, resulting in excimer formation. Complementary measurements of calcium-dependent enhancements of monomer fluorescence of PyC-CaM and PyN-CaM permit a determination of the calcium-dependent activation of individual domains and indicate the sequential calcium occupancy of the C- and N-terminal domains, with full saturation at 7.0 and 300 microM calcium, respectively. Substantial amounts of excimer formation are observed for apo-CaM prior to peptide association, indicating that interdomain interactions occur in solution. Calcium binding results in a large and highly cooperative reduction in the level of excimer formation; its calcium dependence coincides with the occupancy of C-terminal sites. These results indicate that interdomain interactions between the opposing domains of CaM occur in solution and that the occupancy of C-terminal calcium binding sites is necessary for the structural coupling between the opposing domains associated with the stabilization of the interdomain linker to enhance target protein binding.     

Calcium binding to calmodulin mutants monitored by domain-specific intrinsic phenylalanine and tyrosine fluorescence

Cooperative calcium binding to the two homologous domains of calmodulin (CaM) induces conformational changes that regulate its association with and activation of numerous cellular target proteins. Calcium binding to the pair of high-affinity sites (III and IV in the C-domain) can be monitored by observing calcium-dependent changes in intrinsic tyrosine fluorescence intensity (lambda(ex)/lambda(em) of 277/320 nm). However, calcium binding to the low-affinity sites (I and II in the N-domain) is more difficult to measure with optical spectroscopy because that domain of CaM does not contain tryptophan or tyrosine. We recently demonstrated that calcium-dependent changes in intrinsic phenylalanine fluorescence (lambda(ex)/lambda(em) of 250/280 nm) of an N-domain fragment of CaM reflect occupancy of sites I and II (VanScyoc, W. S., and M. A. Shea, 2001, Protein Sci. 10:1758-1768). Using steady-state and time-resolved fluorescence methods, we now show that these excitation and emission wavelength pairs for phenylalanine and tyrosine fluorescence can be used to monitor equilibrium calcium titrations of the individual domains in full-length CaM. Calcium-dependent changes in phenylalanine fluorescence specifically indicate ion occupancy of sites I and II in the N-domain because phenylalanine residues in the C-domain are nonemissive. Tyrosine emission from the C-domain does not interfere with phenylalanine fluorescence signals from the N-domain. This is the first demonstration that intrinsic fluorescence may be used to monitor calcium binding to each domain of CaM. In this way, we also evaluated how mutations of two residues (Arg74 and Arg90) located between sites II and III can alter the calcium-binding properties of each of the domains. The mutation R74A caused an increase in the calcium affinity of sites I and II in the N-domain. The mutation R90A caused an increase in calcium affinity of sites III and IV in the C-domain whereas R90G caused an increase in calcium affinity of sites in both domains. This approach holds promise for exploring the linked energetics of calcium binding and target recognition.     

Ordered and cooperative binding of opposing globular domains of calmodulin to the plasma membrane Ca-ATPase

We have investigated the mechanisms of activation of the plasma membrane (PM) Ca-ATPase by calmodulin (CaM), which result in enhanced calcium transport rates and the maintenance of low intracellular calcium levels. We have isolated the amino- or carboxyl-terminal domains of CaM (i.e. CaMN or CaMC), permitting an identification of their relative specificity for binding to sites on either the PM Ca-ATPase or a peptide (C28W) corresponding to the CaM-binding sequence. We find that either CaMN or CaMC alone is capable of productive interactions with the PM Ca-ATPase that induces enzyme activation. There are, however, large differences in the affinity and specificity of binding between CaMN and CaMC and either C28W or the PM Ca-ATPase. The initial binding interaction between CaMC and the PM Ca-ATPase is highly specific, having approximately 10,000-fold greater affinity in comparison with CaMN. However, following the initial association of either CaMC or CaMN, there is a 300-fold enhancement in the affinity of CaMN for the secondary binding site. Thus, while CaMC binds with a high affinity to the two CaM-binding sites within the PM Ca-ATPase in a sequential manner, CaMN binds cooperatively with a lower affinity to both binding sites. These large differences in the binding affinities and specificities of the amino- and carboxyl-terminal domains ensure that CaM binding to the PM Ca-ATPase normally involves the formation of a specific complex in which the initial high affinity association of the carboxyl-terminal domain promotes the association of the amino-terminal domain necessary for enzyme activation.     

Calcium-dependent stabilization of the central sequence between Met(76) and Ser(81) in vertebrate calmodulin

Spin-label electron paramagnetic resonance (EPR) provides optimal resolution of dynamic and conformational heterogeneity on the nanosecond time-scale and was used to assess the structure of the sequence between Met(76) and Ser(81) in vertebrate calmodulin (CaM). Previous fluorescence resonance energy transfer and anisotropy measurements indicate that the opposing domains of CaM are structurally coupled and the interconnecting central sequence adopts conformationally distinct structures in the apo-form and following calcium activation. In contrast, NMR data suggest that the opposing domains of CaM undergo independent rotational dynamics and that the sequence between Met(76) and Ser(81) in the central sequence functions as a flexible linker that connects two structurally independent domains. However, these latter measurements also resolve weak internuclear interactions that suggest the formation of transient helical structures that are stable on the nanosecond time-scale within the sequence between Met(76) and Asp(80) in apo-CaM (H. Kuboniwa, N. Tjandra, S. Grzekiek, H. Ren, C. B. Klee, and A. Bax, 1995, Nat. Struct. Biol. 2:768-776). This reported conformational heterogeneity was resolved using site-directed mutagenesis and spin-label EPR, which detects two component spectra for 1-oxyl-2,2,5,5-tetramethylpyrroline-3-methyl)-methanethiosulfonate spin labels (MTSSL) bound to CaM mutants T79C and S81C that include a motionally restricted component. In comparison to MTSSL bound within stable helical regions, the fractional contribution of the immobilized component at these positions is enhanced upon the addition of small amounts of the helicogenic solvent trifluoroethanol (TFE). These results suggest that the immobilized component reflects the formation of stable secondary structures. Similar spectral changes are observed upon calcium activation, suggesting a calcium-dependent stabilization of the secondary structure. No corresponding changes are observed in either the solvent accessibility to molecular oxygen or the maximal hyperfine splitting. In contrast, more complex spectral changes in the line-shape and maximal hyperfine splitting are observed for spin labels bound to sites that undergo tertiary contact interactions. These results suggest that spin labels at solvent-exposed positions within the central sequence are primarily sensitive to backbone fluctuations and that either TFE or calcium binding stabilizes the secondary structure of the sequence between Met(76) and Ser(81) and modulates the structural coupling between the opposing domains of CaM.     

Fluorescence energy transfer analysis of calmodulin-peptide complexes.

The interactions between calmodulin and the tryptophan residues of synthetic peptides corresponding to the calmodulin binding domains of skeletal muscle myosin light-chain kinase and the plasma membrane calcium pump were examined. The single tryptophan residue contained in each peptide became relatively immobilized and inaccessible to iodide ion upon binding to calmodulin, indicating that the indole side chain was inserted into a hydrophobic cleft in the surface of calmodulin. Fluorescence energy transfer from peptidyl tryptophan residues to an AEDANS moiety attached to cysteine-26 of spinach calmodulin was measured. Included in these analyses was a tryptophan-containing peptide analog of the calmodulin binding domain of neuromodulin. These data indicated that the indole ring of each peptide inserted 32-35 A away from cysteine-26 and may therefore interact with the carboxyl-terminal lobe of CaM in its "bent" conformation [Persechini & Kretsinger (1988a) J. Cardiovasc. Pharmacol. 12 (Suppl 5), S1-S12; Ikura et al. (1992) Science 256, 632-638; Vorherr et al. (1992) Eur. J. Biochem. 204, 931-937]. The interchange of tryptophan-3 and phenylalanine-21 of the calcium pump peptide increased the efficiency of energy transfer to the AEDANS-moiety approximately 12-fold, reducing the calculated distance to 20 A. These data suggest that phenylalanine-21 of the calcium pump peptide interacts with the hydrophobic cleft in the amino-terminal lobe of CaM.     

Structures of CaV2 Ca2+/CaM-IQ domain complexes reveal binding modes that underlie calcium-dependent inactivation and facilitation

Calcium influx drives two opposing voltage-activated calcium channel (Ca(V)) self-modulatory processes: calcium-dependent inactivation (CDI) and calcium-dependent facilitation (CDF). Specific Ca(2+)/calmodulin (Ca(2+)/CaM) lobes produce CDI and CDF through interactions with the Ca(V)alpha(1) subunit IQ domain. Curiously, Ca(2+)/CaM lobe modulation polarity appears inverted between Ca(V)1s and Ca(V)2s. Here, we present crystal structures of Ca(V)2.1, Ca(V)2.2, and Ca(V)2.3 Ca(2+)/CaM-IQ domain complexes. All display binding orientations opposite to Ca(V)1.2 with a physical reversal of the CaM lobe positions relative to the IQ alpha-helix. Titration calorimetry reveals lobe competition for a high-affinity site common to Ca(V)1 and Ca(V)2 IQ domains that is occupied by the CDI lobe in the structures. Electrophysiological experiments demonstrate that the N-terminal Ca(V)2 Ca(2+)/C-lobe anchors affect CDF. Together, the data unveil the remarkable structural plasticity at the heart of Ca(V) feedback modulation and indicate that Ca(V)1 and Ca(V)2 IQ domains bear a dedicated CDF site that exchanges Ca(2+)/CaM lobe occupants.     

Nonessential role for methionines in the productive association between calmodulin and the plasma membrane Ca-ATPase.

To investigate the role of hydrophobic interactions involving methionine side chains in facilitating the productive association between calmodulin (CaM) and the plasma membrane (PM) Ca-ATPase, we have substituted the polar amino acid Gln for Met at multiple positions in both the amino- and carboxyl-terminal domains of CaM. Conformationally sensitive fluorescence signals indicate that these mutations have little effect on the backbone fold of the carboxyl-terminal domain of CaM. The insertion of multiple Gln in either globular domain results in a decrease in the apparent affinity of CaM for the PM-Ca-ATPase. However, despite the multiple substitution of Gln for four methionines at positions 36, 51, 71, and 72 in the amino-terminal domain or for three methionines at positions 124, 144, and 145 in the carboxyl-terminal domain, these mutant CaMs are able to fully activate the PM-Ca-ATPase. Thus, although these CaM mutants have a decreased affinity for the CaM-binding site on the Ca-ATPase, they retain the ability to fully activate the Ca-ATPase at saturating concentrations of CaM. The role of individual methionines in modulating the affinity between the carboxyl terminus and the PM-Ca-ATPase was further investigated through the substitution of individual Met with Gln. Upon substitution of Met(124) and Met(144) with Gln, there is a 5- and 10-fold increase in the amount of CaM necessary to obtain half-maximal activation of the PM-Ca-ATPase, indicating that these methionine side chains participate in the high-affinity association between CaM and the PM-Ca-ATPase. However, substitution of Gln for Met(145) results in no change in the apparent affinity between CaM and the PM-Ca-ATPase, indicating that in contrast to all other known CaM targets, Met(145) does not participate in the interaction between CaM and the PM-Ca-ATPase. These results emphasize differences in the binding interactions between individual methionines in CaM and different target enzymes, and suggest that hydrophobic interactions between methionines in CaM and the binding site on the PM-Ca-ATPase are not necessary for enzyme activation. Calculation of the binding affinities of individual CaM domains associated with activation of the PM-Ca-ATPase suggests that mutations of methionines located in either domain of CaM can decrease the initial high-affinity association between CaM and the PM-Ca-ATPase, but have little effect upon the subsequent binding of the opposing globular domain. These results suggest that the initial associations between CaM and the CaM-binding sequence in the PM-Ca-ATPase are guided by nonspecific hydrophobic interactions involving both domains of CaM.     

The secondary structure of calcineurin regulatory region and conformational change induced by calcium/calmodulin binding

The protein serine/threonine phosphatase calcineurin (CN) is activated by calmodulin (CaM) in response to intracellular calcium mobilization. A widely accepted model for CN activation involves displacement of the CN autoinhibitory peptide (CN(467-486)) from the active site upon binding of CaM. However, CN activation requires calcium binding both to the low affinity sites of CNB and to CaM, and previous studies did not dissect the individual contributions of CNB and CaM to displacement of the autoinhibitory peptide from the active site. In this work we have produced separate CN fragments corresponding to the CNA regulatory region (CNRR(381-521), residues 381-521), the CNA catalytic domain truncated at residue 341, and the CNA-CNB heterodimer with CNA truncated at residue 380 immediately after the CNB binding helix. We show that the separately expressed regulatory region retains its ability to inhibit CN phosphatase activity of the truncated CN341 and CN380 and that the inhibition can be reversed by calcium/CaM binding. Tryptophan fluorescence quenching measurements further indicate that the isolated regulatory region inhibits CN activity by occluding the catalytic site and that CaM binding exposes the catalytic site. The results provide new support for a model in which calcium binding to CNB enables CaM binding to the CNA regulatory region, and CaM binding then instructs an activating conformational change of the regulatory region that does not depend further on CNB. Moreover, the secondary structural content of the CNRR(381-521) was tentatively addressed by Fourier transform infrared spectroscopy. The results indicate that the secondary structure of CNRR(381-521) fragment is predominantly random coil, but with significant amount of beta-strand and alpha-helix structures.     

Domain structure and lipid interaction in human apolipoproteins A-I and E,a general model

Detailed structural information on human exchangeable apolipoproteins (apo) is required to understand their functions in lipid transport. Using a series of deletion mutants that progressively lacked different regions along the molecule, we probed the structural organization of lipid-free human apoA-I and the role of different domains in lipid binding, making comparisons to apoE, which is a member of the same gene family and known to have two structural domains. Measurements of alpha-helix content by CD in conjunction with tryptophan and 8-anilino-1-naphthalenesulfonic acid fluorescence data demonstrated that deletion of the amino-terminal or central regions disrupts the tertiary organization, whereas deletion of the carboxyl terminus has no effect on stability and induces a more cooperative structure. These data are consistent with the lipid-free apoA-I molecule being organized into two structural domains similar to apoE; the amino-terminal and central parts form a helix bundle, whereas the carboxyl-terminal alpha-helices form a separate, less organized structure. The binding of the apoA-I variants to lipid emulsions is modulated by reorganization of the helix bundle structure, because the rate of release of heat on binding is inversely correlated with the stability of the helix bundle. Based on these observations, we propose that there is a two-step mechanism for lipid binding of apoA-I: apoA-I initially binds to a lipid surface through amphipathic alpha-helices in the carboxyl-terminal domain, followed by opening of the helix bundle in the amino-terminal domain. Because apoE behaves similarly, this mechanism is probably a general feature for lipid interaction of other exchangeable apolipoproteins, such as apoA-IV.     

Analysis of the functional coupling between calmodulin's calcium binding and peptide recognition properties

The enhancement of calmodulin's (CaM) calcium binding activity by an enzyme or a recognition site peptide and its diminution by key point mutations at the protein recognition interface (e.g., E84K-CaM), which is more than 20 A away from the nearest calcium ligation structure, can be described by an expanded version of the Adair-Klotz equation for multiligand binding. The expanded equation can accurately describe the calcium binding events and their variable linkage to protein recognition events can be extended to other CaM-regulated enzymes and can potentially be applied to a diverse array of ligand binding systems with allosteric regulation of ligand binding, whether by other ligands or protein interaction. The 1.9 A resolution X-ray crystallographic structure of the complex between E84K-CaM and RS20 peptide, the CaM recognition site peptide from vertebrate smooth muscle and nonmuscle forms of myosin light chain kinase, provides insight into the structural basis of the functional communication between CaM's calcium ligation structures and protein recognition surfaces. The structure reveals that the complex adapts to the effect of the functional mutation by discrete adjustments in the helix that contains E84. This helix is on the amino-terminal side of the helix-loop-helix structural motif that is the first to be occupied in CaM's calcium binding mechanism. The results reported here are consistent with a sequential and cooperative model of CaM's calcium binding activity in which the two globular and flexible central helix domains are functionally linked, and provide insight into how CaM's calcium binding activity and peptide recognition properties are functionally coupled.     

Lobe-specific functions of Ca2+·calmodulin in alphaCa2+·calmodulin-dependent protein kinase II activation

N-methyl-D-aspartic acid receptor-dependent long term potentiation (LTP), a model of memory formation, requires Ca2+·calmodulin-dependent protein kinase II (αCaMKII) activity and Thr286 autophosphorylation via both global and local Ca2+ signaling, but the mechanisms of signal transduction are not understood. We tested the hypothesis that the Ca2+-binding activator protein calmodulin (CaM) is the primary decoder of Ca2+ signals, thereby determining the output, e.g. LTP. Thus, we investigated the function of CaM mutants, deficient in Ca2+ binding at sites 1 and 2 of the N-terminal lobe or sites 3 and 4 of the C-terminal CaM lobe, in the activation of αCaMKII. Occupancy of CaM Ca2+ binding sites 1, 3, and 4 is necessary and sufficient for full activation. Moreover, the N- and C-terminal CaM lobes have distinct functions. Ca2+ binding to N lobe Ca2+ binding site 1 increases the turnover rate of the enzyme 5-fold, whereas the C lobe plays a dual role; it is required for full activity, but in addition, via Ca2+ binding site 3, it stabilizes ATP binding to αCaMKII 4-fold. Thr286 autophosphorylation is also dependent on Ca2+ binding sites on both the N and the C lobes of CaM. As the CaM C lobe sites are populated by low amplitude/low frequency (global) Ca2+ signals, but occupancy of N lobe site 1 and thus activation of αCaMKII requires high amplitude/high frequency (local) Ca2+ signals, lobe-specific sensing of Ca2+-signaling patterns by CaM is proposed to explain the requirement for both global and local Ca2+ signaling in the induction of LTP via αCaMKII.     

Contributions of domain structure and lipid interaction to the functionality of exchangeable human apolipoproteins

Exchangeable apolipoproteins function in lipid transport as structural components of lipoprotein particles, cofactors for enzymes and ligands for cell-surface receptors. Recent findings with apoA-I and apoE suggest that the tertiary structures of these two members of the human exchangeable apolipoprotein gene family are related. Characteristically, these proteins contain a series of proline-punctuated, 11- or 22-amino acid, amphipathic alpha-helical repeats that can adopt a helix bundle conformation in the lipid-free state. The amino- and carboxyl-terminal regions form separate domains with the latter being primarily responsible for lipid binding. Interaction with lipid induces changes in the conformation of the amino-terminal domain leading to alterations in function; for example, opening of the amino-terminal four-helix bundle in apolipoprotein E upon lipid binding is associated with enhanced receptor-binding activity. The concept of a two-domain structure for the larger exchangeable apolipoproteins is providing new molecular insights into how these apolipoproteins interact with lipids and other proteins, such as receptors. The ways in which structural changes induced by lipid interaction modulate the functionality of these apolipoproteins are reviewed.     

Calcium regulates tertiary structure and enzymatic activity of human endometase/matrilysin-2 and its role in promoting human breast cancer cell invasion

Human MMP-26 (matrix metalloproteinase-26) (also known as endometase or matrilysin-2) is a putative biomarker for human carcinomas of breast, prostate and other cancers of epithelial origin. Calcium modulates protein structure and function and may act as a molecular signal or switch in cells. The relationship between MMPs and calcium has barely been studied and is absent for MMP-26. We have investigated the calcium-binding sites and the role of calcium in MMP-26. MMP-26 has one high-affinity and one low-affinity calcium binding site. High-affinity calcium binding was restored at physiologically low calcium conditions with a calcium-dissociation constant of 63 nM without inducing secondary and tertiary structural changes. High-affinity calcium binding protects MMP-26 against thermal denaturation. Mutants of this site (D165A or E191A) lose enzymatic activity. Low-affinity calcium binding was restored at relatively high calcium concentrations and showed a K(d2) (low-affinity calcium-dissociation constant) value of 120 microM, which was accompanied with the recovery of enzymatic activity reversibly and tertiary structural changes, but without secondary structural rearrangements. Mutations at the low-affinity calcium-binding site (C3 site), K189E or D114A, induced enhanced affinity for the Ca2+ ion or an irreversible loss of enzymatic activity triggered by low-affinity calcium binding respectively. Mutation at non-calcium-binding site (V184D at C2 site) showed that C2 is not a true calcium-binding site. Observations from homology-modelled mutant structures correlated with these experimental results. A human breast cancer cell line, MDA-MB-231, transfected with wild-type MMP-26 cDNA showed a calcium-dependent invasive potential when compared with controls that were transfected with an inactive form of MMP-26 (E209A). Calcium-independent high invasiveness was observed in the K189E mutant MDA-MB-231 cell line.