Crystal structure determination and refinement of pike 4.10 parvalbumin (minor component from Esox lucius)

Coordination to divalent cations by calcium-binding proteins studied by FTIR spectroscopy

We review the Fourier-transform infrared (FTIR) spectroscopy of side-chain COO(-) groups of Ca(2+)-binding proteins: parvalbumins, bovine calmodulin, akazara scallop troponin C and related calcium binding proteins and peptide analogues. The COO(-) stretching vibration modes can be used to identify the coordination modes of COO(-) groups of Ca(2+)-binding proteins to metal ions: bidentate, unidentate, and pseudo-bridging. FTIR spectroscopy demonstrates that the coordination structure of Mg(2+) is distinctly different from that of Ca(2+) in the Ca(2+)-binding site in solution. The interpretation of COO(-) stretches is ensured on the basis of the spectra of calcium-binding peptide analogues. The implication of COO(-) stretches is discussed for Ca(2+)-binding proteins. This article is part of a Special Issue entitled: FTIR in membrane proteins and peptide studies.

Metal-specific structural changes in parvalbumin

Parvalbumin is a small protein of EF-hand family whose main role is considered to be metal buffering. Recent evidences indicate that parvalbumin also fulfills more complicated functions, which may be determined by the diversity in structural changes in response to the binding of different metal cations. In the present work the conformations of α and β isoforms of pike parvalbumin in the Ca(2+)- and Mg(2+)-loaded state were studied by intrinsic fluorescence, circular dichroism and bis-ANS extrinsic fluorescence. We have determined the structural region causing different spectral response on the binding of Mg(2+)- and Ca(2+) ions in pike β-parvalbumin. Our data reveal similarity of the metal-bound forms of α-parvalbumin. In contrast, those of β isoform differ significantly in the tyrosine spectral range. We also discuss the possible physiological consequences of the structural rearrangements accompanied Mg(2+)/Ca(2+) exchange in pike β-parvalbumin.

Identification and analysis of muscle-related protein isoforms expressed in the white muscle of the mandarin fish (Siniperca chuatsi)

To identify muscle-related protein isoforms expressed in the white muscle of the mandarin fish Siniperca chuatsi, we analyzed 5,063 high-quality expressed sequence tags (ESTs) from white muscle cDNA library and predicted the integrity of the clusters annotated to these genes and the physiochemical properties of the putative polypeptides with full length. Up to about 33% of total ESTs were annotated to muscle-related proteins: myosin, actin, tropomyosin/troponin complex, parvalbumin, and Sarcoplasmic/endoplasmic reticulum calcium ATPase (SERCa). Thirty-two isoforms were identified and more than one isoform existed in each of these proteins. Among these isoforms, 14 putative polypeptides were with full length. In addition, about 2% of total ESTs were significantly homologous to "glue" molecules such as alpha-actinins, myosin-binding proteins, myomesin, tropomodulin, cofilin, profilin, twinfilins, coronin-1, and nebulin, which were required for the integrity and maintenance of the muscle sarcomere. The results demonstrated that multiple isoforms of major muscle-related proteins were expressed in S. chuatsi white muscle. The analysis on these isoforms and other proteins sequences will greatly aid our systematic understanding of the high flexibility of mandarin fish white muscle at molecular level and expand the utility of fish systems as models for the muscle genetic control and function.

Metal-controlled interdomain cooperativity in parvalbumins

Conformational behavior of five homologous proteins, parvalbumins (PAs) from northern pike (alpha and beta isoforms), Baltic cod, and rat (alpha and beta isoforms), was studied by scanning calorimetry, circular dichroism, and bis-ANS fluorescence. The mechanism of the temperature-induced denaturation of these proteins depends dramatically on both the peculiarities of their amino acid sequences and on their interaction with metal ions. For example, the pike alpha-PA melting can be described by two successive two-state transitions with mid-temperatures of 90 and 120 degrees C, suggesting the presence of two thermodynamic domains. The intermediate state populated at the end of the first transition was shown to bind Ca(2+) ions, and was characterized by the largely preserved secondary structure and increased solvent exposure of hydrophobic groups. Mg(2+)- and Na(+)-loaded forms of pike alpha-PA demonstrated a single two-state transition. Therefore, the mechanism of the PA thermal denaturation is controlled by metal binding. It ranged from the absence of detectable first-order transition (apo-form of pike PA), to the two-state transition (e.g., Mg(2+)- and Na(+)-loaded forms of pike alpha-PA), to the more complex mechanisms (Ca(2+)-loaded PAs) involving at least one partially folded intermediate. Analysis of isolated cavities in the protein structures revealed that the interface between the CD and EF subdomains of Ca(2+)-loaded pike alpha-PA is much more loosely packed compared with PAs manifesting single heat-sorption peak. The impairment of interactions between CD and EF subdomains may cause a loss of structural cooperativity and appearance of two separate thermodynamic domains. One more peculiar feature of pike alpha-PA is that depending on its interactions with metal ions, it can be an intrinsically disordered protein (apo-form), an ordered protein of mesophilic (Na(+)-bound state), thermophilic (Mg(2+)-form), or even of the hyperthermophilic origin (Ca(2+)-form).

Sequence microheterogeneity of parvalbumin pI 5.0 of pike: a mass spectrometric study

Parvalbumin (PA) is a muscle and neuronal calcium-binding protein, the major fish and frog allergen. Its characteristic feature is the presence of multiple isoforms with significantly different amino acid sequences. Here we show that the major isoform of northern pike muscle PA (pI 5.0, alpha-PA) exhibits microheterogeneity of amino acid sequence. ESI Q-TOF mass-spectrometry (MS) analysis of alpha-PA sample showed the presence of two components with mass difference of 71 Da. Analysis of tryptic and endoproteinase Asp-N digests of alpha-PA by MALDI-TOF MS revealed peptides, corresponding to two different amino acid sequences. The sequence differences between variant proteins are limited to AB-domain and include substitutions K27A and L31K, and an extra Leu residue between K11 and K12. Since the affected residues comprise a cluster on the surface of PA, an involvement of the identified region into target recognition is suggested. The substitutions at positions 27 and 31 are located in the region of previously identified epitopes of parvalbumin relevant for PA-specific IgE and IgG binding, which suggests different immunoactivities of the variants. The found microheterogeneity of PA is suggested to be of importance for physiological adaptation of the propulsive musculature to developmental and/or environmental requirements and may contribute to PA allergenicity.

Apo-parvalbumin as an intrinsically disordered protein

Recently defined family of intrinsically disordered proteins (IDP) includes proteins lacking rigid tertiary structure meanwhile fulfilling essential biological functions. Here we show that apo-state of pike parvalbumin (alpha- and beta-isoforms, pI 5.0 and 4.2, respectively) belongs to the family of IDP, which is in accord with theoretical predictions. Parvalbumin (PA) is a 12-kDa calcium-binding protein involved into regulation of relaxation of fast muscles. Differential scanning calorimetry measurements of metal-depleted form of PA revealed the absence of any thermally induced transitions with measurable denaturation enthalpy along with elevated specific heat capacity, implying the lack of rigid tertiary structure and exposure of hydrophobic protein groups to the solvent. Calcium removal from the PAs causes more than 10-fold increase in fluorescence intensity of hydrophobic probe bis-ANS and is accompanied by a decrease in alpha-helical content and a marked increase in mobility of aromatic residues environment, as judged by circular dichroism spectroscopy (CD). Guanidinium chloride-induced unfolding of the apo-parvalbumins monitored by CD showed the lack of fixed tertiary structure. Theoretical estimation of energetics of the charge-charge interactions in the PAs indicated their pronounced destabilization upon calcium removal, which is in line with sequence-based predictions of disordered protein chain regions. Far-UV CD studies of apo-alpha-PA revealed hallmarks of cold denaturation of the protein at temperatures below 20 degrees C. Moreover, a cooperative thermal denaturation transition with mid-temperature at 10-15 degrees C is revealed by near-UV CD for both PAs. The absence of detectable enthalpy change in this temperature region suggests continuous nature of the transition. Overall, the theoretical and experimental data obtained show that PA in apo-state is essentially disordered nevertheless demonstrates complex denaturation behavior. The native rigid tertiary structure of PA is attained upon association of one (alpha-PA) or two (beta-PA) calcium ions per protein molecule, as follows from calorimetric and calcium titration data.

Infrared spectroscopic study of the metal-coordination structures of calcium-binding proteins

Carboxylate (COO(-)) groups can coordinate to metal ions in of the following four modes: 'unidentate', 'bidentate', 'bridging' and 'pseudo-bridging' modes. COO(-) stretching frequencies provide information about the coordination modes of COO(-) groups to metal ions. We review the Fourier-transform infrared spectroscopy (FTIR) of side-chain COO(-) groups of Ca(2+)-binding proteins: pike parvalbumin pI 4.10, bovine calmodulin and Akazara scallop troponin C. FTIR spectroscopy of Akazara scallop troponin C has demonstrated that the coordination structure of Mg(2+) is distinctly different from that of Ca(2+) in the Ca(2+)-binding site. The assignments of the COO(-) antisymmetric stretch have been ensured on the basis of the spectra of calcium-binding peptide analogues. The downshift of the COO(-) antisymmetric stretching mode from 1565 cm(-1) to 1555-1540 cm(-1) upon Ca(2+) binding is a commonly observed feature of FTIR spectra for EF-hand proteins.

Estimation of parvalbumin Ca(2+)- and Mg(2+)-binding constants by global least-squares analysis of isothermal titration calorimetry data

The use of competitive isothermal titration calorimetry (ITC) to measure high-affinity binding constants has been largely restricted to systems with a single binding site or multiple identical sites. This study demonstrates the extension of this approach to proteins with two nonequivalent EF-hand Ca(2+)-binding sites--rat beta parvalbumin and the S55D/E59D variant of rat alpha parvalbumin. The method involves simultaneous (global) least-squares analysis of titrations with Ca(2+), with Mg(2+), with Ca(2+) in the presence of Mg(2+), and with Ca(2+) or Mg(2+) in the presence of a competitive chelator (EDTA or EGTA). The Ca(2+) and Mg(2+) binding constants obtained for rat beta agree well with estimates obtained by flow dialysis. Although the Ca(2+) affinity of alpha S55D/E59D is too high to measure by flow dialysis, it was amenable to analysis using the ITC-based approach. The combined S55D and E59D mutations increase the Ca(2+) and Mg(2+) affinities of the mutated binding site by factors of 14 and 26, respectively. This behavior is consistent with that seen previously for the rat beta S55D variant.

Structural analysis, identification, and design of calcium-binding sites in proteins

Assigning proteins with functions based on the 3-D structure requires high-speed techniques to make a systematic survey of protein structures. Calcium regulates many biological systems by binding numerous proteins in different biological environments. Despite the great diversity in the composition of ligand residues and bond angles and lengths of calcium-binding sites, our structural analysis of 11 calcium-binding sites in different classes of proteins has shown that common local structural parameters can be used to identify and design calcium-binding proteins. Natural calcium-binding sites in both EF-hand proteins and non-EF-hand proteins can be described with the smallest deviation from the geometry of an ideal pentagonal bipyramid. Further, two different magnesium-binding sites in parvalbumin and calbindin(D9K) can also be identified using an octahedral geometry. Using the established method, we have designed de novo calcium-binding sites into the scaffold of non-calcium-binding proteins CD2 and Rop. Our results suggest that it is possible to identify calcium- and magnesium-binding sites in proteins and design de novo metal-binding sites.

A minimized human integrin alpha(5)beta(1) that retains ligand recognition

Two isolated recombinant fragments from human integrin alpha(5)beta(1) encompassing the FG-GAP repeats III to VII of alpha(5) and the insertion-type domain from beta(1), respectively, are structurally well defined in solution, based on CD evidence. Divalent cation binding induces a conformational adaptation that is achieved by Ca(2+) or Mg(2+) (or Mn(2+)) with alpha(5) and only by Mg(2+) (or Mn(2+)) with beta(1). Mn(2+) bound to beta(1) is highly hydrated ( approximately 3 water molecules), based on water NMR relaxation, in agreement with a metal ion-dependent adhesion site-type metal coordination. Each fragment saturated with Mg(2+) (or Mn(2+)) binds a recombinant fibronectin ligand in an RGD-dependent manner. A conformational rearrangement is induced on the fibronectin ligand upon binding to the alpha(5), but not to the beta(1) fragment, based on CD. Ligand binding results in metal ion displacement from beta(1). Both alpha(5) and beta(1) fragments form a stable heterodimer (alpha(5)beta(1) mini-integrin) that retains ligand recognition to form a 1:1:1 ternary complex, in the presence of Mg(2+), and induces a specific conformational adaptation of the fibronectin ligand. A two-site model for RGD binding to both alpha and beta integrin components is inferred from our data using low molecular weight RGD mimetics.

X-Ray crystal structure and molecular dynamics simulations of silver hake parvalbumin (Isoform B)

Parvalbumins constitute a class of calcium-binding proteins characterized by the presence of several helix-loop-helix (EF-hand) motifs. In a previous study (Revett SP, King G, Shabanowitz J, Hunt DF, Hartman KL, Laue TM, Nelson DJ, 1997, Protein Sci 7:2397-2408), we presented the sequence of the major parvalbumin isoform from the silver hake (Merluccius bilinearis) and presented spectroscopic and structural information on the excised "EF-hand" portion of the protein. In this study, the X-ray crystal structure of the silver hake major parvalbumin has been determined to high resolution, in the frozen state, using the molecular replacement method with the carp parvalbumin structure as a starting model. The crystals are orthorhombic, space group C2221, with a = 75.7 A, b = 80.7 A, and c = 42.1 A. Data were collected from a single crystal grown in 15% glycerol, which served as a cryoprotectant for flash freezing at -188 degrees C. The structure refined to a conventional R-value of 21% (free R 25%) for observed reflections in the range 8 to 1.65 A [1 > 2sigma(I)]. The refined model includes an acetylated amino terminus, 108 residues (characteristic of a beta parvalbumin lineage), 2 calcium ions, and 114 water molecules per protein molecule. The resulting structure was used in molecular dynamics (MD) simulations focused primarily on the dynamics of the ligands coordinating the Ca2+ ions in the CD and EF sites. MD simulations were performed on both the fully Ca2+ loaded protein and on a Ca2+ deficient variant, with Ca2+ only in the CD site. There was substantial agreement between the MD and X-ray results in addressing the issue of mobility of key residues in the calcium-binding sites, especially with regard to the side chain of Ser55 in the CD site and Asp92 in the EF site.

Crystal structure of the EF-hand parvalbumin at atomic resolution (0.91 A) and at low temperature (100 K). Evidence for conformational multistates within the hydrophobic core

Several crystal structures of parvalbumin (Parv), a typical EF-hand protein, have been reported so far for different species with the best resolution achieving 1.5 A. Using a crystal grown under microgravity conditions, cryotechniques (100 K), and synchrotron radiation, it has now been possible to determine the crystal structure of the fully Ca2+-loaded form of pike (component pI 4.10) Parv.Ca2 at atomic resolution (0.91 A). The availability of such a high quality structure offers the opportunity to contribute to the definition of the validation tools useful for the refinement of protein crystal structures determined to lower resolution. Besides a better definition of most of the elements in the protein three-dimensional structure than in previous studies, the high accuracy thus achieved allows the detection of well-defined alternate conformations, which are observed for 16 residues out of 107 in total. Among them, six occupy an internal position within the hydrophobic core and converge toward two small buried cavities with a total volume of about 60 A3. There is no indication of any water molecule present in these cavities. It is probable that at temperatures of physiological conditions there is a dynamic interconversion between these alternate conformations in an energy-barrier dependent manner. Such motions for which the amplitudes are provided by the present study will be associated with a time-dependent remodeling of the void internal space as part of a slow dynamics regime (millisecond timescales) of the parvalbumin molecule. The relevance of such internal dynamics to function is discussed.

Ca2+/Mg2+ exchange in parvalbumin and other EF-hand proteins. A theoretical study

A remarkable conformational rearrangement occurs upon Ca2+/Mg2+ exchange in the C-terminal EF-hand site (labelled site EF or EF-4) of parvalbumin, as initially established by X-ray crystallography. Such a conformational rearrangement is characterised as follows: (i) the co-ordination number decreases from seven oxygen atoms in the Ca-loaded form to six oxygen atoms in the Mg-loaded form, the heptaco-ordination of Ca2+ corresponding with a skewed pentagonal bipyramid configuration of the seven oxygen atoms, whereas the hexaco-ordination of Mg2+ corresponds with a regular octahedral configuration of the six oxygen atoms; and (ii) Glu101, at the relative position 12 in the EF-hand loop sequence (labelled "Glu12"), acts as a bidentate ligand in the Ca-loaded form and as a monodentate ligand in the Mg-loaded form. As part of the conformational rearrangement, the chi1 dihedral angle undergoes a gauche(+) to gauche(-) transition upon substitution of Ca2+ by Mg2+, whereas the chi2 angle remains practically unchanged and the chi3 angles in both forms adopt a nearly mirror image relationship. In order to understand the molecular mechanisms underlying such a conformational rearrangement, we undertook a theoretical study using the free energy perturbation (FEP) method, starting from high-resolution crystal structures of the same parvalbumin (pike 4. 10 isoform) differing by the substitution of their two cationic sites EF-3 (or CD) and EF-4 (or EF), i.e. the 1pal structure with EF-3(Ca2+) and EF-4(Ca2+), the 4pal structure with EF-3(Ca2+) and EF-4(Mg2+). When Mg2+ is "alchemically" transformed into Ca2+ within the EF-4 site of 4pal, the conformational rearrangement of Glu12 is correctly predicted by the FEP calculation. When Ca2+ is transformed into Mg2+ within the EF-3 site of 4pal, the FEP calculation predicts the topology of the fully Mg-loaded form for which no crystallographic data is presently available. As expected, Glu62 (at the relative position 12 in EF-3 loop) is predicted to be a monodentate residue within a regular octahedral arrangement of six oxygen atoms around Mg2+. We also investigated the behaviour during Ca2+/Mg2+ exchange of two other typical EF-hand proteins, troponin C (TnC) and calmodulin (CaM), for which no three-dimensional structure of their Mg-loaded forms is available so far. It is also predicted that the EF-3 site of TnC and the EF-1 site of CaM have their invariant Glu12 residues switching from the bidentate to the monodentate configuration when Ca2+ is substituted by Mg2+, with six oxygen atoms being observed in the co-ordination sphere of the alchemically generated Mg2+ cation.

15N NMR relaxation studies of calcium-loaded parvalbumin show tight dynamics compared to those of other EF-hand proteins

Dynamics of the rat alpha-parvalbumin calcium-loaded form have been determined by measurement of 15N nuclear relaxation using proton-detected heteronuclear NMR spectroscopy. The relaxation data were analyzed using spectral density functions and the Lipari-Szabo formalism. The major dynamic features for the rat alpha-parvalbumin calcium-loaded form are (1) the extreme rigidity of the helix-loop-helix EF-hand motifs and the linker segment connecting them, (2) the N and C termini of the protein being restricted in their mobility, (3) a conformational exchange occurring at the kink of helix D, and (4) the residue at relative position 2 in the Ca2+-binding sites having an enhanced mobility. Comparison of the Ca2+-binding EF-hand domains of alpha-parvalbumin-Ca2+, calbindin-Ca2+, and calmodulin-Ca2+ shows that parvalbumin is probably the most rigid of the EF-hand proteins. It also illustrates the dynamical properties which are conserved in the EF-hand domains from different members of this superfamily: (1) a tendency toward higher mobility of NH vectors at relative position 2 in the Ca2+-binding loop, (2) a restricted mobility for the other residues in the binding loop, and (3) an overall rigidity for the helices of EF-hand motifs. The differences in mobility between parvalbumin and the two EF-hand proteins occur mainly at the linker connecting the pair of EF hands and also at the C terminus of the last helix. In parvalbumin-Ca2+, these two regions are characterized by a pronounced rigidity compared to the corresponding more mobile regions in calbindin-Ca2+ and calmodulin-Ca2+.

Oncomodulin is abundant in the organ of Corti

A small, acidic Ca(2+)-binding protein (CBP-15) was recently detected in extracts of the mammalian auditory receptor organ, the organ of Corti [Senarita et al. (1995) Hear. Res. 90, 169-175]. N-terminal sequence data for CBP-15 [Thalmann et al. (1995) Biochem. Biophys. Res. Commun. 215, 142-147] implied membership in the parvalbumin family and possible identity with the mammalian beta-parvalbumin oncomodulin. As shown herein, the latter conclusion is supported by strong cross-reactivity between CBP-15 and isoform-specific antibodies to oncomodulin. Moreover, we have succeeded in amplifying the guinea pig CBP-15 coding sequence from organ of Corti cDNA using degenerate oligonucleotide primers based on the rat oncomodulin sequence. The deduced amino acid sequence of guinea pig CBP-15 displays 90%, 92%, and 98% identity with mouse, rat, and human oncomodulin isoforms. Demonstration of the presence of oncomodulin in the organ of Corti is the first documentation of this substance in a postnatal mammalian tissue.

Comparative modeling of the three-dimensional structure of the calmodulin-related TCH2 protein from Arabidopsis

Plants adapt to various stresses by developmental alterations that render them less easily damaged. Expression of the TCH2 gene of Arabidopsis is strongly induced by stimuli such as touch and wind. The gene product, TCH2, belongs to the calmodulin (CaM) family of proteins and contains four highly conserved Ca(2+)-binding EF-hands. We describe here the structure of TCH2 in the fully Ca(2+)-saturated form, constructed using comparative molecular modeling, based on the x-ray structure of paramecium CaM. Like known CaMs, the overall structure consists of two globular domains separated by a linker helix. However, the linker region has added flexibility due to the presence of 5 glycines within a span of 6 residues. In addition, TCH2 is enriched in Lys and Arg residues relative to other CaMs, suggesting a preference for targets which are more negatively charged. Finally, a pair of Cys residues in the C-terminal domain, Cys126 and Cys131, are sufficiently close in space to form a disulfide bridge. These predictions serve to direct future biochemical and structural studies with the overall aim of understanding the role of TCH2 in the cellular response of Arabidopsis to environmental stimuli.

NMR solution structure of a synthetic troponin C heterodimeric domain

The C-terminal domain from the muscle protein troponin C (TnC) comprises two helix-loop-helix calcium-binding sites (residues 90-162). The assembly of these two sites is governed by calcium binding enabling a synthetic C-terminal domain to be preferentially and stoichiometrically assembled from two synthetic peptides (residues 93-126, SCIII, and 129-162, SCIV) in the presence of calcium only. It is therefore of great interest to know how closely the structure of this heterodimeric domain is to the intact protein domain. Analysis of such a structure has important implications in protein engineering and in understanding the stability of calcium-binding proteins in terms of biological function. The solution structure of this heterodimeric protein was determined by 1H NMR spectroscopy using 802 NOE derived distance restraints and 23 phi and 22 chi angle restraints. Distance geometry-simulated annealing calculations yielded a family of 42 converged structures (rmsd 0.86 +/- 0.17 A) showing an arrangement of four alpha-helices similar in fold to the C-terminal of troponin C. The dimer interface has several important interactions between helix pairs E/H and F/G responsible for the association of the two peptides. However, neither the peptide complex nor the solution NMR structure of TnC pack as tightly as that observed in the TnC X-ray structure. The interhelical distance between the F/G helix is about 1.4 A greater in solution than in the crystal. A comparison of the exposed surface area of the hydrophobic residues in the SCIII/SCIV heterodimer revealed that residues 1104, Y112, and 1121 are more exposed than in the previously determined solution structure of the SCIII homodimer. These residues are important for the interaction with the inhibitory region of TnI and provide evidence for their involvement in the regulation of muscle contraction.

Oligomerization of an avian thymic parvalbumin. Chemical evidence for a Ca(2+)-specific conformation

CPV3, the third parvalbumin isoform to be identified in the chicken, is produced exclusively in the thymus gland. Although parvalbumins are typically cysteine-deficient, CPV3 contains two cysteine residues, at positions 18 and 72. The reported three-dimensional parvalbumin structures suggest that the side chain of cysteine-72 should be solvent-accessible. Accordingly, we find that CPV3 readily forms disulfide-linked oligomers in the absence of reducing agents. The reaction, employing either O2 or ferricyanide ion as the oxidant, is apparently restricted to the Ca(2+)-bound form of the protein. The differing reactivity of the Ca2+, Mg2+, and apo-forms has significant structural implications.

Infrared studies of interaction between metal ions and Ca(2+)-binding proteins. Marker bands for identifying the types of coordination of the side-chain COO- groups to metal ions in pike parvalbumin (pI = 4.10)

Metal-ligand interactions in the Ca(2+)-binding sites of pike parvalbumin (pI = 4.10) have been examined by Fourier-transform infrared spectroscopy. The region of the COO- antisymmetric stretch provides useful information on the types of coordination of the COO- groups to the metal ions in the Mg(2+)-, Mn(2+)-, and Ca(2+)-bound forms. In the spectrum of the Ca(2+)-bound form, two bands are observed at 1,582 and 1,553 cm-1, whereas, in the spectra of the Mg(2+)- and Mn(2+)-bound forms, bands are observed only in the region around 1,582 cm-1 and no band is found in the region around 1,553 cm-1. The 1,553-cm-1 band of the Ca(2+)-bound form reflects the bidentate coordination of the COO- groups of both Glu-62 in the CD site and Glu-101 in the EF site to the Ca2+ ions, which has been made clear by X-ray analysis as a feature of the Ca(2+)-bound form. Absence of such a band in the spectrum of the Mn(2+)-bound form is consistent with the X-ray structure of this form where both of the two COO- groups are unidentate. These unidentate COO- groups of Glu-62 and Glu-101 in the Mn(2+)-bound form seem to give rise to a band at 1,577-1,574 cm-1. The spectrum of the Mg(2+)-bound form is also consistent with the 'pseudo-bridging' coordination of the COO- group of Glu-101 reported in the X-ray structure of a form where the Mg2+ ion occupies only the EF site, and the same spectrum is further indicative of the 'pseudo-bridging' coordination of the COO- group of Glu-62.

Relative stabilities of synthetic peptide homo- and heterodimeric troponin-C domains

It has previously been shown that synthetic peptides corresponding to calcium-binding sites III (SCIII) and IV (SCIV) from troponin-C can undergo a calcium-induced dimerization to form the respective homodimers (Shaw GS, Hodges RS, Sykes BD, 1990, Science 249:280-283; Shaw GS et al., 1992a, J Am Chem Soc 114:6258-6259). In addition, an equimolar mixture of SCIII and SCIV has been shown to form preferentially the SCIII/SCIV heterodimer (Shaw GS et al., 1992a, J Am Chem Soc 114:6258-6259). The stabilities of these dimers have been investigated by using 1H-NMR and circular dichroism spectroscopies to follow temperature- and guanidine hydrochloride (GuHCl)-induced denaturations. It has been found that the most stable species, the SCIII/SCIV heterodimer (delta GuH2O = -64.8 kJ/mol), is about 13 kJ/mol more stable than the least stable species, the SCIV homodimer, while the SCIII homodimer is of intermediate stability. This trend of free energies agrees well with the trend of delta G0 values derived from the products of the dissociation constants for calcium binding and peptide association determined from earlier calcium-titration studies. These observations provide evidence that calcium affinity and the association of 2-calcium binding sites are tightly linked. However, it was noted that in all cases delta G0 was considerably more negative than delta GuH2O determined from GuHCl experiments. This difference increased as the stability of the peptide complex increased, providing evidence that linear extrapolation of GuHCl data for very stable proteins may significantly underestimate the value for delta G0.

Calcium and magnesium binding to rat parvalbumin

Ca2+ and Mg2+ binding to rat parvalbumin was measured by means of the fluorescent Ca2+ indicator fluo-3 using a method developed earlier [Eberhard, M. & Erne, P. (1991) Eur. J. Biochem. 202, 1333-1338]. We demonstrate that rat parvalbumin contains two equivalent Ca2+/Mg2+ binding sites and that Ca2+ and Mg2+ compete for the same sites. Dissociation constants (Kd) for Ca2+ and Mg2+ in Hepes buffer containing 150 mM K+ at 35 degrees C and pH 7.2 are 11.0 +/- 1.8 nM and 41 +/- 8 microM, respectively. At an ionic strength below 0.2 M, Kd values of Ca2+ binding to rat parvalbumin are approximately proportional to the ion concentration. Kd values of Ca2+ binding were found to be about fourfold larger in the presence of Na+ as compared with K+, indicating that Na+ distinctly influences Ca2+ binding to rat parvalbumin. Both Ca2+ and Mg2+ binding to parvalbumin are exothermic whereas Ca2+ and Mg2+ binding to fluo-3 are endothermic entropy-driven processes.

Symmetrical rearrangement of the cation-binding sites of parvalbumin upon Ca2+/Mg2+ exchange. A study by 1H 2D NMR

Two forms of parvalbumin, i.e., the fully Ca-loaded form PaCa2 and the fully Mg-loaded form PaMg2, are investigated by 2D 1H NMR in solution. A detailed analysis of the resonances, which belong to residues involved in direct coordination of Ca2+ and Mg2+, establishes that the sixth ligand, a highly conserved Glu residue at the relative position 12 in both cation-binding sites CD and EF, undergoes a conformational rearrangement through a 120 degrees rotation of its side chain about the C alpha-C beta bond with PaMg2 adopting the less energetically favored g- conformation, as inferred from scalar coupling constants and dipole-dipole contacts measured on the COSY and NOESY spectra, respectively. Similarly, chemical shift effects, which selectively involve NH and C alpha H resonances (as well as side-chain resonances) in both CD and EF sites, point to a symmetrical behavior of both cation-binding sites upon Ca2+/Mg2+ exchange.

Probing the metal-binding sites of cod parvalbumin using europium(III) ion luminescence and diffusion-enhanced energy transfer

Excitation spectroscopy of the 7F0----5D0 transition of Eu3+ and diffusion-enhanced energy transfer are used to study metal-binding characteristics of the calcium-binding protein parvalbumin from codfish. Energy is transferred from Eu3+ ions occupying the CD- and EF-binding sites to the freely-diffusing Co(III) coordination complex energy acceptors: [Co(NH3)6]3+, [Co(NH3)5H2O]3+, [CoF(NH3)5]2+, [CoCl(NH3)5]2+, [Co(NO2)3(NH3)3], and [Co(ox)3]3-. In the absence of these inorganic energy acceptors, the excited-state lifetimes of Eu3+ bound to the CD and EF sites are indistinguishable, even in D2O; however, in the presence of the positively charged energy acceptor complexes, the Eu3+ probes in the cod parvalbumin have different excited-state lifetimes due to a greater energy-transfer site from Eu3+ in the CD site than from this ion in the EF site. The observation of distinct lifetimes for Eu3+ in the two sites allows the study of the relative binding site affinities and selectivity, using other members of the lanthanide ion series. Our results indicate that during the course of a titration of the metal-free protein, Eu3+ fills the two sites simultaneously. Eu3+ is competitively displaced by other Ln3+ ions, with the CD site showing a preference for the larger Ln3+ ions while the EF site shows little, if any, competitive selectivity across the Ln3+ ion series.

Crystal structure of the unique parvalbumin component from muscle of the leopard shark (Triakis semifasciata). The first X-ray study of an alpha-parvalbumin

The three-dimensional structure of parvalbumin from leopard shark (Triakis semifasciata) with 109 amino acid residues (alpha-series) is described at 1.54 A resolution. Crystals were grown at 20 degrees C from 2.9 M-potassium/sodium phosphate solutions at pH 5.6. The space group is P3(1)21 and unit cell dimensions are a = b = 32.12 A and c = 149.0 A. The structure has been solved by the molecular replacement method using pike 4.10 parvalbumin as a model. The final structure refinement resulted in an R-factor of 17.3% for 11,363 independent reflections at 1.54 A resolution. The shark parvalbumin shows the main features of all parvalbumins: the folding of the chain including six alpha-helices, the salt bridge between Arg75 and Glu81, and the hydrophobic core. Compared to the structure of beta-parvalbumins from pike and carp, one main difference is observed: the chain is one residue longer and this additional residue, which extends the F helix, is involved through its C-terminal carboxylate group in a network of electrostatic contacts with two basic residues, His31 in the B helix and Lys36 in the BC segment. Furthermore, hydrogen bonds exist between the side-chains of Gln108 (F helix) and Tyr26 (B helix). There is therefore a "locking" of the tertiary structure through contacts between two sequentially distant regions in the protein and this is likely to contribute to making the stability of an alpha-parvalbumin higher in comparison to that of a beta-parvalbumin. The lengthening of the C-terminal F helix by one residue appears to be a major feature of alpha-parvalbumins in general, owing to the homologies of the amino acid sequences. Besides the lengthening of the C-terminal helix, the classification of the leopard shark parvalbumin in the alpha-series rests upon the observation of Lys13, Leu32, Glu61 and Val66. As this is the first crystal structure description of a parvalbumin from the alpha-phylogenetic lineage, it was hoped that it would clearly determine the presence or absence of a third cation binding site in parvalbumins belonging to the alpha-lineage. In beta-pike pI 4.10 parvalbumin, Asp61 participates as a direct ligand of a third site, the satellite of the CD site. In shark parvalbumin, as in nearly all alpha-parvalbumins, one finds Glu at position 61. Unfortunately, the conformation of the polar head of Glu61 cannot be inferred from the X-ray data.(ABSTRACT TRUNCATED AT 400 WORDS)

Crystallization and preliminary X-ray investigation of a sarcoplasmic calcium-binding protein from amphioxus

Crystals of a sarcoplasmic Ca(2+)-binding protein from the protochordate amphioxus have been grown from solutions of ammonium sulfate. The crystals are orthorhombic, space group C222(1), with unit cell axes a = 59.6(1) A, b = 81.3(1) A and c = 82.4(1) A. There is one molecule in the asymmetric unit. The crystals diffract beyond 2.5 A and show less than 20% decline in diffraction intensities after a three day exposure to X-rays from a laboratory rotating anode source.

Ionic interactions with parvalbumins. Crystal structure determination of pike 4.10 parvalbumin in four different ionic environments

The crystal structure of the Ca-loaded form of pike 4.10 parvalbumin (minor component from pike muscle belonging to the beta phylogenetic series), with both its primary sites CD and EF occupied by Ca2+ ions and its third site occupied by an ammonium ion, as previously determined at 1.93 A resolution, has now been refined to a resolution of 1.65 A. The crystallization of this parvalbumin in different ionic environments has allowed three novel non-isomorphous crystalline forms to be obtained: (1) a first form, crystallized in the presence of a mixture of ammonium sulphate and manganese sulphate, for which all the cation binding sites in the protein are occupied by Mn2+; (2) a second form crystallized in the presence of MgSO4 as the precipitating agent, only differs from the Ca/NH4 form by the occupation of the third site by Mg2+, whereas the primary sites remain occupied by Ca2+; (3) a third form, also crystallized in the presence of MgSO4, corresponds to a well-defined molecular species with both the primary EF site and the third site occupied by Mg2+, whereas the primary CD site remains occupied by CA2+. The corresponding molecular structures reported here have been determined at resolutions between 1.8 and 2.4 A. The comparison of the different crystal structures allows the structural modifications accompanying the substitution of the primary sites by cations differing significantly in their ionic radii (Ca2+, Mn2+, Mg2+) to be investigated in detail, and it also leads to a precise description of the third site in a typical beta parvalbumin. The substitution Ca2+ by Mg2+ within the primary site EF is characterized by a "contraction" of the co-ordination sphere, with a decrease of the mean oxygen-metal distance by a value of 0.25 A and a decrease of the co-ordination number from 7 to 6, as a consequence of the loss of a bidentate ligand (Glu101), which becomes a monodentate one. Such an adaptation of the co-ordination sphere around a cation of smaller size involves, among others, the transformation of the Glu101 side-chain from the stable gauche(+) form to the less stable gauche(-) form. The third site is clearly described as a satellite of the CD primary site, since both sites possess common protein ligands, such as Asp53 and Glu59. Furthermore, Asp61 appears as a specific ligand of the third site in the different environments investigated in this work. We finally discuss the relevance of the third site to parvalbumin phylogeny.

The crystal and molecular structure of human annexin V, an anticoagulant protein that binds to calcium and membranes

Human annexin V (PP4), a member of the family of calcium, membrane binding proteins, has been crystallized in the presence of calcium and analysed by crystallography by multiple isomorphic replacement at 3 A and preliminarily refined at 2.5 A resolution. The molecule has dimensions of 64 x 40 x 30 A3 and is folded into four domains of similar structure. Each domain consists of five alpha-helices wound into a right-handed superhelix yielding a globular structure of approximately 18 A diameter. The domains have hydrophobic cores whose amino acid sequences are conserved between the domains and within the annexin family of proteins. The four domains are folded into an almost planar array by tight (hydrophobic) pair-wise packing of domains II and III and I and IV to generate modules (II-III) and (I-IV), respectively. The assembly is symmetric with three parallel approximate diads relating II to III, I to IV and the module (II-III) to (I-IV), respectively. The latter diad marks a channel through the centre of the molecule coated with charged amino acid residues. The protein has structural features of channel forming membrane proteins and a polar surface characteristic of soluble proteins. It is a member of the third class of amphipathic proteins different from soluble and membrane proteins.

The calcium binding sites in human annexin V by crystal structure analysis at 2.0 A resolution. Implications for membrane binding and calcium channel activity

Crystal structure analysis and refinement at 2.0 A resolution of a rhombohedral crystal form of human annexin V at high calcium concentration revealed a domain motion compared to the previously analysed hexagonal crystal form. Five calcium ions were located on the convex face of the molecule. Three strongly bound calciums are liganded at protruding interhelical loops and Asp or Glu residues in homologous positions in repeats I, II and IV. Five proteinaceous oxygens and one solvent molecule form the coordination polyhedron in each case. The unoccupied seventh site is suggested as the phospholipid headgroup binding site. Two more weakly bound sites were identified by lanthanum labelling. The structural features suggest that annexin V attaches with its convex face to membranes by specific calcium mediated interactions with at least three phospholipids. The adjacent membrane bilayer may thus become locally disordered and permeable to allow calcium inflow through the central polar channel of the molecule.

Structure of oncomodulin refined at 1.85 A resolution. An example of extensive molecular aggregation via Ca2+

The crystal structure of oncomodulin, a 12,000 Mr protein isolated from rat tumours, has been determined by molecular replacement using the carp parvalbumin structure as a starting model. Refinement was performed by cycles of molecular fitting and restrained least-squares, using area-detector intensity data to 1.85 A resolution. For the 5770 reflections in the range 6.0 to 1.85 A, which were used in the refinement, the crystallographic R-factor is 0.166. The refined model includes residues 2 to 108, three Ca2+ and 87 water molecules per oncomodulin molecule. The oncomodulin backbone is closely related to that of parvalbumin; however, some differences are found after a least-squares fit of the two backbones, with root-mean-square (r.m.s.) deviations of 1 to 2 A in residues 2 to 6, 59 to 61 of the CD loop, 87, 90 and 108. The overall r.m.s. deviation of the backbone residues 5 to 108 is 0.62 A. Each of the two Ca2+ atoms that are bound to the CD and EF loops is co-ordinated to seven oxygen atoms, including one water molecule. The third Ca2+ is also seven-co-ordinated, to five oxygen atoms belonging to three different oncomodulin molecules and to two water molecules which form hydrogen bonds to a fourth oncomodulin; thus, this intermolecular Ca2+ and its equivalents interlink the molecules into zigzag layers normal to the b axis with a spacing of b/2 or 32.14 A. No such extensive molecular aggregation has been reported for any of the related Ca-binding regulatory proteins of the troponin-C family studied thus far. The Ca-O distances in all three polyhedra are in the range 2.07 A to 2.64 A, indicating tightly bound Ca polyhedra.

Europium(III) ion luminescence as a structural probe of parvalbumin isotypes

The 7F0----5D0 transition of Eu3+ is used to investigate the metal ion binding sites of five parvalbumin isotypes. Comparisons are based on the resolution of the Eu3+ excitation spectrum with a computer program using the Marquardt nonlinear regression algorithm. The Lorentzian-Gaussian product function provides the most effective approximation to the shape of the peaks, the positions of which were found to be related to differences in the amino acid residues at the binding sites. Below pH 6, spectra consist of two peaks near 579 nm, but as the pH is raised, the two peaks gradually diminish and two new, much broader peaks appear at 577 and 578 nm. The lower wavelength peak, at low pH, and the peak at 577 nm, at high pH, are assigned to the CD site. The two sites have nearly equal affinities for Eu3+ except in the northern pike III (pI 5.0) isotype. The excitation spectra are compared to that of the carp III (pI = 4.25) parvalbumin for which the complete crystal structure is available. This structure forms the basis for the molecular modeling studies of the altered binding sites. Preliminary results are presented regarding differences in solvent exposure of the CD and EF sites based on collision-induced energy transfer to [Co(NH3)6]3+.

Two-dimensional 1H nuclear magnetic resonance study of pike pI 5.0 parvalbumin (Esox lucius). Sequential resonance assignments and folding of the polypeptide chain

The structure of alpha pike 5.0 parvalbumin under its Ca-loaded form (or PaCa2) is studied in solution by two-dimensional 1H nuclear magnetic resonance (n.m.r.) at 360 MHz using a conventional strategy of sequential assignments, which involved correlated spectroscopy, relayed coherence transfer spectroscopy and nuclear Overhauser enhancement spectroscopy. In order to overcome the problem of spectral overlapping due to the presence of 108 residues in the protein, experiments were performed at different pH and temperature values, either in 1H2O or in 2H2O solutions. The amino acid sequence of pike 5.0 parvalbumin is thus fully characterized by nearly the totality of its NH, C alpha H and C beta H resonances originating from the different residues (421 protons assigned among 429 in total). When associated with the remaining side resonances, these sequence-specific assignments provide a basis for establishing the secondary organization and tertiary folding of the polypeptide chain. Pike 5.0 parvalbumin was selected as a characteristic representative of the alpha phylogenic series, for which no crystalline structure is presently available, in contrast with the beta series for which two crystalline structures have been determined. A parvalbumin molecule with a single polypeptide chain of 108 amino acids represents one of the highest molecular weights analyzed so far by two-dimensional n.m.r. spectroscopy. The use of a moderate magnetic field strength, with 1H nuclei resonating at 360 MHz, is justified by the fact that ring current effects are operating favorably in this globular protein with a high phenylalanine content. A three-dimensional structure has been generated by the "distance geometry" or DISGEO computational procedure on the basis of about 450 interproton nuclear Overhauser enhancement connectives (short, medium and long-range) in conjunction with a selection of phi and chi dihedral angle constraints. The coherence of the calculated structure, which displays all the features of the typical folding of a parvalbumin protein, provides a good test of reliability of the n.m.r. data collected so far. Although similar to a beta parvalbumin in the folding of its polypeptide chain, the alpha parvalbumin studied here differs markedly from a beta parvalbumin in the length of its C-terminal F-helix domain, which includes 11 residues instead of ten in the latter.(ABSTRACT TRUNCATED AT 400 WORDS)