Dynamics of Ca2+-saturated calmodulin D129N mutant studied by multiple molecular dynamics simulations

Fifteen independent 1-nsec MD simulations of fully solvated Ca(2+) saturated calmodulin (CaM) mutant D129N were performed from different initial conditions to provide a sufficient statistical basis to gauge the significance of observed dynamical properties. In all MD simulations the four Ca(2+) ions remained in their binding sites, and retained a single water ligand as observed in the crystal structure. The coordination of Ca(2+) ions in EF-hands I, II, and III was sevenfold. In EF-hand IV, which was perturbed by the mutation of a highly conserved Asp129, an anomalous eightfold Ca(2+) coordination was observed. The Ca(2+) binding loop in EF-hand II was observed to dynamically sample conformations related to the Ca(2+)-free form. Repeated MD simulations implicate two well-defined conformations of Ca(2+) binding loop II, whereas similar effect was not observed for loops I, III, and IV. In 8 out of 15 MD simulations Ca(2+) binding loop II adopted an alternative conformation in which the Thr62 >C=O group was displaced from the Ca(2+) coordination by a water molecule, resulting in the Ca(2+) ion ligated by two water molecules. The alternative conformation of the Ca(2+) binding loop II appears related to the "closed" state involved in conformational exchange previously detected by NMR in the N-terminal domain fragment of CaM and the C-terminal domain fragment of the mutant E140Q. MD simulations suggest that conformations involved in microsecond exchange exist partially preformed on the nanosecond time scale.     

Cation charge and size selectivity of the C2 domain of cytosolic phospholipase A(2).

C2 domains regulate numerous eukaryotic signaling proteins by docking to target membranes upon binding Ca(2+). Effective activation of the C2 domain by intracellular Ca(2+) signals requires high Ca(2+) selectivity to exclude the prevalent physiological metal ions K(+), Na(+), and Mg(2+). The cooperative binding of two Ca(2+) ions to the C2 domain of cytosolic phospholipase A(2) (cPLA(2)-alpha) induces docking to phosphatidylcholine (PC) membranes. The ionic charge and size selectivities of this C2 domain were probed with representative mono-, di-, and trivalent spherical metal cations. Physiological concentrations of monovalent cations and Mg(2+) failed to bind to the domain and to induce docking to PC membranes. Superphysiological concentrations of Mg(2+) did bind but still failed to induce membrane docking. In contrast, Ca(2+), Sr(2+), and Ba(2+) bound to the domain in the low micromolar range, induced electrophoretic mobility shifts in native polyacrylamide gels, stabilized the domain against thermal denaturation, and induced docking to PC membranes. In the absence of membranes, the degree of apparent positive cooperativity in binding of Ca(2+), Sr(2+), and Ba(2+) decreased with increasing cation size, suggesting that the C2 domain binds two Ca(2+) or Sr(2+) ions, but only one Ba(2+) ion. These stoichiometries were correlated with the abilities of the ions to drive membrane docking, such that micromolar concentrations of Ca(2+) and Sr(2+) triggered docking while even millimolar concentrations of Ba(2+) yielded poor docking efficiency. The simplest explanation is that two bound divalent cations are required for stable membrane association. The physiological Ca(2+) ion triggered membrane docking at 20-fold lower concentrations than Sr(2+), due to both the higher Ca(2+) affinity of the free domain and the higher affinity of the Ca(2+)-loaded domain for membranes. Kinetic studies indicated that Ca(2+) ions bound to the free domain are retained at least 5-fold longer than Sr(2+) ions. Moreover, the Ca(2+)-loaded domain remained bound to membranes 2-fold longer than the Sr(2+)-loaded domain. For both Ca(2+) and Sr(2+), the two bound metal ions dissociate from the protein-membrane complex in two kinetically resolvable steps. Finally, representative trivalent lanthanide ions bound to the domain with high affinity and positive cooperativity, and induced docking to PC membranes. Overall, the results demonstrate that both cation charge and size constraints contribute to the high Ca(2+) selectivity of the C2 domain and suggest that formation of a cPLA(2)-alpha C2 domain-membrane complex requires two bound multivalent metal ions. These features are proposed to stem from the unique structural features of the metal ion-binding site in the C2 domain.     

The second Ca(2+)-binding domain of NCX1 binds Mg2+ with high affinity

We report the effects of binding of Mg(2+) to the second Ca(2+)-binding domain (CBD2) of the sodium-calcium exchanger. CBD2 is known to bind two Ca(2+) ions using its Ca(2+)-binding sites I and II. Here, we show by nuclear magnetic resonance (NMR), circular dichroism, isothermal titration calorimetry, and mutagenesis that CBD2 also binds Mg(2+) at both sites, but with significantly different affinities. The results from Mg(2+)-Ca(2+) competition experiments show that Ca(2+) can replace Mg(2+) from site I, but not site II, and that Mg(2+) binding affects the affinity for Ca(2+). Furthermore, thermal unfolding circular dichroism data demonstrate that Mg(2+) binding stabilizes the domain. NMR chemical shift perturbations and (15)N relaxation data reveal that Mg(2+)-bound CBD2 adopts a state intermediate between the apo and fully Ca(2+)-loaded forms. Together, the data show that at physiological Mg(2+) concentrations CBD2 is loaded with Mg(2+) preferentially at site II, thereby stabilizing and structuring the domain and altering its affinity for Ca(2+).     

Mapping the BKCa channel's "Ca2+ bowl": side-chains essential for Ca2+ sensing

There is controversy over whether Ca(2+) binds to the BK(Ca) channel's intracellular domain or its integral-membrane domain and over whether or not mutations that reduce the channel's Ca(2+) sensitivity act at the point of Ca(2+) coordination. One region in the intracellular domain that has been implicated in Ca(2+) sensing is the "Ca(2+) bowl". This region contains many acidic residues, and large Ca(2+)-bowl mutations eliminate Ca(2+) sensing through what appears to be one type of high-affinity Ca(2+)-binding site. Here, through site-directed mutagenesis we have mapped the residues in the Ca(2+) bowl that are most important for Ca(2+) sensing. We find acidic residues, D898 and D900, to be essential, and we find them essential as well for Ca(2+) binding to a fusion protein that contains a portion of the BK(Ca) channel's intracellular domain. Thus, much of our data supports the conclusion that Ca(2+) binds to the BK(Ca) channel's intracellular domain, and they define the Ca(2+) bowl's essential Ca(2+)-sensing motif. Overall, however, we have found that the relationship between mutations that disrupt Ca(2+) sensing and those that disrupt Ca(2+) binding is not as strong as we had expected, a result that raises the possibility that, when examined by gel-overlay, the Ca(2+) bowl may be in a nonnative conformation.     

Conformational and hydration effects of site-selective sodium,calcium and strontium ion binding to the DNA Holliday junction structure d(TCGGTACCGA)(4)

The role of metal ions in determining the solution conformation of the Holliday junction is well established, but to date the picture of metal ion binding from structural studies of the four-way DNA junction is very incomplete. Here we present two refined structures of the Holliday junction formed by the sequence d(TCGGTACCGA) in the presence of Na(+) and Ca(2+), and separately with Sr(2+) to resolutions of 1.85A and 1.65A, respectively. This sequence includes the ACC core found to promote spontaneous junction formation, but its structure has not previously been reported. Almost complete hydration spheres can be defined for each metal cation. The Na(+) sites, the most convincing observation of such sites in junctions to date, are one on either face of the junction crossover region, and stabilise the ordered hydration inside the junction arms. The four Ca(2+) sites in the same structure are at the CG/CG steps in the minor groove. The Sr(2+) ions occupy the TC/AG, GG/CC, and TA/TA sites in the minor groove, giving ten positions forming two spines of ions, spiralling through the minor grooves within each arm of the stacked-X structure. The two structures were solved in the two different C2 lattices previously observed, with the Sr(2+) derivative crystallising in the more highly symmetrical form with two-fold symmetry at its centre. Both structures show an opening of the minor groove face of the junction of 8.4 degrees in the Ca(2+) and Na(+) containing structure, and 13.4 degrees in the Sr(2+) containing structure. The crossover angles at the junction are 39.3 degrees and 43.3 degrees, respectively. In addition to this, a relative shift in the base pair stack alignment of the arms of 2.3A is observed for the Sr(2+) containing structure only. Overall these results provide an insight into the so-far elusive stabilising ion structure for the DNA Holliday junction.     

Deamidation and disulfide bridge formation in human calbindin D28k with effects on calcium binding

Calbindin D(28k) (calbindin) is a cytoplasmic protein expressed in the central nervous system, which is implied in Ca(2+) homeostasis and enzyme regulation. A combination of biochemical methods and mass spectrometry has been used to identify post-translational modifications of human calbindin. The protein was studied at 37 degrees C or 50 degrees C in the presence or absence of Ca(2+). One deamidation site was identified at position 203 (Asn) under all conditions. Kinetic experiments show that deamidation of Asn 203 occurs at a rate of 0.023 h(-1) at 50 degrees C for Ca(2+)-free calbindin. Deamidation is slower for the Ca(2+)-saturated protein. The deamidation process leads to two Asp iso-forms, regular Asp and iso-Asp. The form with regular Asp 203 binds four Ca(2+) ions with high affinity and positive cooperativity, i.e., in a very similar manner to non-deamidated protein. The form with beta-aspartic acid (or iso-Asp 203) has reduced affinity for two or three sites leading to sequential Ca(2+) binding, i.e., the Ca(2+)-binding properties are significantly perturbed. The status of the cysteine residues was also assessed. Under nonreducing conditions, cysteines 94 and 100 were found both in reduced and oxidized form, in the latter case in an intramolecular disulfide bond. In contrast, cysteines 187, 219, and 257 were not involved in any disulfide bonds. Both the reduced and oxidized forms of the protein bind four Ca(2+) ions with high affinity in a parallel manner and with positive cooperativity.     

Point amino acid substitutions in the Ca2+-binding centers of recoverin. I. Mechanism of successive filling of Ca2+-binding centers

The molecule of photoreceptor Ca(2+)-binding protein recoverin contains four potential Ca(2+)-binding sites of the EF-hand type, but only two of them (the second and the third) can actually bind calcium ions. We studied the interaction of Ca2+ with recoverin and its mutant forms containing point amino acid substitutions at the working Ca(2+)-binding sites by measuring the intrinsic protein fluorescence and found that the substitution of Gln for Glu residues chelating Ca2+ in one (the second or the third) or simultaneously in both (the second and the third) Ca(2+)-binding sites changes the affinity of the protein to Ca2+ ions in different ways. The Gln for Glu121 substitution in the third site and the simultaneous Gln substitutions in the second (for Glu85) and in the third (for Glu121) sites result in the complete loss of the capability of recoverin for a strong binding of Ca(2+)-ions. On the other hand, the Gln for Glu85 substitution only in the second site moderately affects its affinity to the cation. Hence, we assumed that recoverin successively binds Ca(2+)-ions: the second site is filled with the cation only after the third site has been filled. The binding constants for the third and the second Ca(2+)-binding sites of recoverin determined by spectrofluorimetric titration are 3.7 x 10(6) and 3.1 x 10(5) M-1, respectively.     

High resolution structures of p-aminobenzamidine- and benzamidine-VIIa/soluble tissue factor: unpredicted conformation of the 192-193 peptide bond and mapping of Ca2+, Mg2+, Na+, and Zn2+ sites in factor VIIa

Factor VIIa (FVIIa) consists of a gamma-carboxyglutamic acid (Gla) domain, two epidermal growth factor-like domains, and a protease domain. FVIIa binds seven Ca(2+) ions in the Gla, one in the EGF1, and one in the protease domain. However, blood contains both Ca(2+) and Mg(2+), and the Ca(2+) sites in FVIIa that could be specifically occupied by Mg(2+) are unknown. Furthermore, FVIIa contains a Na(+) and two Zn(2+) sites, but ligands for these cations are undefined. We obtained p-aminobenzamidine-VIIa/soluble tissue factor (sTF) crystals under conditions containing Ca(2+), Mg(2+), Na(+), and Zn(2+). The crystal diffracted to 1.8A resolution, and the final structure has an R-factor of 19.8%. In this structure, the Gla domain has four Ca(2+) and three bound Mg(2+). The EGF1 domain contains one Ca(2+) site, and the protease domain contains one Ca(2+), one Na(+), and two Zn(2+) sites. (45)Ca(2+) binding in the presence/absence of Mg(2+) to FVIIa, Gla-domainless FVIIa, and prothrombin fragment 1 supports the crystal data. Furthermore, unlike in other serine proteases, the amide N of Gly(193) in FVIIa points away from the oxyanion hole in this structure. Importantly, the oxyanion hole is also absent in the benzamidine-FVIIa/sTF structure at 1.87A resolution. However, soaking benzamidine-FVIIa/sTF crystals with d-Phe-Pro-Arg-chloromethyl ketone results in benzamidine displacement, d-Phe-Pro-Arg incorporation, and oxyanion hole formation by a flip of the 192-193 peptide bond in FVIIa. Thus, it is the substrate and not the TF binding that induces oxyanion hole formation and functional active site geometry in FVIIa. Absence of oxyanion hole is unusual and has biologic implications for FVIIa macromolecular substrate specificity and catalysis.     

Structural basis for Ca(2+)-induced activation of human PAD4

Peptidylarginine deiminase 4 (PAD4) is a Ca(2+)-dependent enzyme that catalyzes the conversion of protein arginine residues to citrulline. Its gene is a susceptibility locus for rheumatoid arthritis. Here we present the crystal structure of Ca(2+)-free wild-type PAD4, which shows that the polypeptide chain adopts an elongated fold in which the N-terminal domain forms two immunoglobulin-like subdomains, and the C-terminal domain forms an alpha/beta propeller structure. Five Ca(2+)-binding sites, none of which adopt an EF-hand motif, were identified in the structure of a Ca(2+)-bound inactive mutant with and without bound substrate. These structural data indicate that Ca(2+) binding induces conformational changes that generate the active site cleft. Our findings identify a novel mechanism for enzyme activation by Ca(2+) ions, and are important for understanding the mechanism of protein citrullination and for developing PAD-inhibiting drugs for the treatment of rheumatoid arthritis.     

The C2A-C2B linker defines the high affinity Ca(2+) binding mode of rabphilin-3A

The Ca(2+) binding properties of C2 domains are essential for the function of their host proteins. We present here the first crystal structures showing an unexpected Ca(2+) binding mode of the C2B domain of rabphilin-3A in atomic detail. Acidic residues from the linker region between the C2A and C2B domains of rabphilin-3A interact with the Ca(2+)-binding region of the C2B domain. Because of these interactions, the coordination sphere of the two bound Ca(2+) ions is almost complete. Mutation of these acidic residues to alanine resulted in a 10-fold decrease in the intrinsic Ca(2+) binding affinity of the C2B domain. Using NMR spectroscopy, we show that this interaction occurred only in the Ca(2+)-bound state of the C2B domain. In addition, this Ca(2+) binding mode was maintained in the C2 domain tandem fragment. In NMR-based liposome binding assays, the linker was not released upon phospholipid binding. Therefore, this unprecedented Ca(2+) binding mode not only shows how a C2 domain increases its intrinsic Ca(2+) affinity, but also provides the structural base for an atypical protein-Ca(2+)-phospholipid binding mode of rabphilin-3A.     

In calmodulin-IQ domain complexes, the Ca(2+)-free and Ca(2+)-bound forms of the calmodulin C-lobe direct the N-lobe to different binding sites

We have investigated the roles played by the calmodulin (CaM) N- and C-lobes in establishing the conformations of CaM-IQ domain complexes in different Ca(2+)-free and Ca(2+)-bound states. Our results indicate a dominant role for the C-lobe in these complexes. When the C-lobe is Ca(2+)-free, it directs the N-lobe to a binding site within the IQ domain consensus sequence. It appears that the N-lobe must be Ca(2+)-free to interact productively with this site. When the C-lobe is Ca(2+)-bound, it directs the N-lobe to a site upstream of the consensus sequence, and it appears that the N-lobe must be Ca(2+)-bound to interact productively with this site. A model for switching in CaM-IQ domain complexes is presented in which the N-lobe adopts bound and extended positions that depend on the status of the Ca(2+)-binding sites in each CaM lobe and the compositions of the two N-lobe binding sites. Ca(2+)-dependent changes in the conformation of the bound C-lobe that appear to be responsible for directed N-lobe binding are also identified. Changes in the equilibria between extended and bound N-lobe positions may control bridging interactions in which the extended N-lobe is bound to another CaM-binding domain. Ca(2+)-dependent control of bridging interactions with CaM has been implicated in the regulation of ion channel and unconventional myosin activities.     

High-capacity Ca2+ binding of human skeletal calsequestrin

Calsequestrin, the major calcium storage protein in both cardiac and skeletal muscle, binds large amounts of Ca(2+) in the sarcoplasmic reticulum and releases them during muscle contraction. For the first time, the crystal structures of Ca(2+) complexes for both human (hCASQ1) and rabbit (rCASQ1) skeletal calsequestrin were determined, clearly defining their Ca(2+) sequestration capabilities through resolution of high- and low-affinity Ca(2+)-binding sites. rCASQ1 crystallized in low CaCl(2) buffer reveals three high-affinity Ca(2+) sites with trigonal bipyramidal, octahedral, and pentagonal bipyramidal coordination geometries, along with three low-affinity Ca(2+) sites. hCASQ1 crystallized in high CaCl(2) shows 15 Ca(2+) ions, including the six Ca(2+) ions in rCASQ1. Most of the low-affinity sites, some of which are μ-carboxylate-bridged, are established by the rotation of dimer interfaces, indicating cooperative Ca(2+) binding that is consistent with our atomic absorption spectroscopic data. On the basis of these findings, we propose a mechanism for the observed in vitro and in vivo dynamic high-capacity and low-affinity Ca(2+)-binding activity of calsequestrin.     

Ca2+ activation of the cPLA2 C2 domain: ordered binding of two Ca2+ ions with positive cooperativity

During Ca(2+) activation, the Ca(2+)-binding sites of C2 domains typically bind multiple Ca(2+) ions in close proximity. These binding events exhibit positive cooperativity, despite the strong charge repulsion between the adjacent divalent cations. Using both experimental and computational approaches, the present study probes the detailed mechanisms of Ca(2+) activation and positive cooperativity for the C2 domain of cytosolic phospholipase A(2), which binds two Ca(2+) ions in sites I and II, separated by only 4.1 A. First, each of the five coordinating side chains in the Ca(2+)-binding cleft is individually mutated and the effect on Ca(2+)-binding affinity and cooperativity is measured. The results identify Asp 43 as the major contributor to Ca(2+) affinity, while the two coordinating side chains that provide bridging coordination to both Ca(2+) ions, Asp 43 and Asp 40, are observed to make the largest contributions to positive cooperativity. Electrostatic calculations reveal that Asp 43 possesses the highest pseudo-pK(a) of the coordinating acidic residues, as well as the highest general cation affinity, due to its relatively buried location within 3.5 A of seven protein oxygens with full or partial negative charges. These calculations therefore explain the greater importance of Asp 43 in defining the Ca(2+) affinity. Overall, the experimental and computational results support an activation model in which the first Ca(2+) ion binds usually to site I, thereby preordering both bridging side chains Asp 40 and 43, and partially or fully deprotonating the three coordinating Asp residues. This initial binding event prepares the conformation and protonation state of the remaining site for Ca(2+) binding, enabling the second Ca(2+) ion to bind with higher affinity than the first as required for positive cooperativity.     

Side-chain protonation and mobility in the sarcoplasmic reticulum Ca2+-ATPase: implications for proton countertransport and Ca2+ release

Protonation of acidic residues in the sarcoplasmic reticulum Ca(2+)-ATPase (SERCA 1a) was studied by multiconformation continuum electrostatic calculations in the Ca(2+)-bound state Ca(2)E1, in the Ca(2+)-free state E2(TG) with bound thapsigargin, and in the E2P (ADP-insensitive phosphoenzyme) analog state with MgF(4)(2-) E2(TG+MgF(4)(2-)). Around physiological pH, all acidic Ca(2+) ligands (Glu(309), Glu(771), Asp(800), and Glu(908)) were unprotonated in Ca(2)E1; in E2(TG) and E2(TG+MgF(4)(2-)) Glu(771), Asp(800), and Glu(908) were protonated. Glu(771) and Glu(908) had calculated pK(a) values larger than 14 in E2(TG) and E2(TG+MgF(4)(2-)), whereas Asp(800) titrated with calculated pK(a) values near 7.5. Glu(309) had very different pK(a) values in the Ca(2+)-free states: 8.4 in E2(TG+MgF(4)(2-)) and 4.7 in E2(TG) because of a different local backbone conformation. This indicates that Glu(309) can switch between a high and a low pK(a) mode, depending on the local backbone conformation. Protonated Glu(309) occupied predominantly two main, very differently orientated side-chain conformations in E2(TG+MgF(4)(2-)): one oriented inward toward the other Ca(2+) ligands and one oriented outward toward a protein channel that seems to be in contact with the cytoplasm. Upon deprotonation, Glu(309) adopted completely the outwardly orientated side-chain conformation. The contact of Glu(309) with the cytoplasm in E2(TG+MgF(4)(2-)) makes this residue unlikely to bind lumenal protons. Instead it might serve as a proton shuttle between Ca(2+)-binding site I and the cytoplasm. Glu(771), Asp(800), and Glu(908) are proposed to take part in proton countertransport.     

Ca2+ occlusion and gating function of Glu309 in the ADP-fluoroaluminate analog of the Ca2+-ATPase phosphoenzyme intermediate

In the absence of ATP the sarcoplasmic reticulum ATPase (SERCA) binds two Ca(2+) with high affinity. The two bound Ca(2+) rapidly undergo reverse dissociation upon addition of EGTA, but can be distinguished by isotopic exchange indicating fast exchange at a superficial site (site II), and retardation of exchange at a deeper site (site I) by occupancy of site II. Site II mutations that allow high affinity binding to site I, but only low affinity binding to site II, show that retardation of isotopic exchange requires higher Ca(2+) concentrations with the N796A mutant, and is not observed with the E309Q mutant even at millimolar Ca(2+). Fluoroaluminate forms a complex at the catalytic site yielding stable analogs of the phosphoenzyme intermediate, with properties similar to E2-P or E1-P.Ca(2). Mutational analysis indicates that Asp(351), Lys(352), Thr(353), Asp(703), Asn(706), Asp(707), Thr(625), and Lys(684) participate in stabilization of fluoroaluminate and Mg(2+) at the phosphorylation site. In the presence of fluoroaluminate and Ca(2+), ADP (or AMP-PCP) favors formation of a stable ADP.E1-P.Ca(2) analog. This produces strong occlusion of Ca(2+) bound to both sites (I and II), whereby dissociation occurs very slowly even following addition of EGTA. Occlusion by fluoraluminate and ADP is not observed with the E309Q mutant, suggesting a gating function of Glu(309) at the mouth of a binding cavity with a single path of entry. This phenomenon corresponds to the earliest step of the catalytic cycle following utilization of ATP. Experiments on limited proteolysis reveal that a long range conformational change, involving displacement of headpiece domains and transmembrane helices, plays a mechanistic role.     

Specificity of Mg2+ binding at the Group II intron branch site

Metal ions play a crucial role in the conformation and splicing activity of Group II introns. Results from 2-aminopurine fluorescence and solution NMR studies suggest that metal ion binding within the branch site region of native D6 of the Group II intron is specific for alkaline earth metal ions and involves inner sphere coordination. Although Mg(2+) and Ca(2+) still bind to a mutant stem loop sequence from which the internal loop had been deleted, ion binding to the mutant RNA results in decreased, rather than increased, exposure of the branch site residue to solvent. These data further support the role of the internal loop in defining branch site conformation of the Group II intron. The specific bound Mg(2+) may play a bivalent role: facilitates the extrahelical conformation of the branch site and has the potential to act as a Lewis acid during splicing.     

Ca2+ binding in the active site of HincII: implications for the catalytic mechanism

The 2.8 A crystal structure of the type II restriction endonuclease HincII bound to Ca(2+) and cognate DNA containing GTCGAC is presented. The DNA is uncleaved, and one calcium ion is bound per active site, in a position previously described as site I in the related blunt cutting type II restriction endonuclease EcoRV [Horton, N. C., Newberry, K. J., and Perona, J. J. (1998) Proc. Natl. Acad. Sci. U.S.A. 95 (23), 13489-13494], as well as that found in other related enzymes. Unlike the site I metal in EcoRV, but similar to that of PvuII, NgoMIV, BamHI, BglII, and BglI, the observed calcium cation is directly ligated to the pro-S(p) oxygen of the scissile phosphate. A calcium ion-ligated water molecule is well positioned to act as the nucleophile in the phosphodiester bond cleavage reaction, and is within hydrogen bonding distance of the conserved active site lysine (Lys 129), as well as the pro-R(p) oxygen of the phosphate group 3' of the scissile phosphate, suggesting possible roles for these groups in the catalytic mechanism. Kinetic data consistent with an important role for the 3'-phosphate group in DNA cleavage by HincII are presented. The previously observed sodium ion [Horton, N. C., Dorner, L. F., and Perona, J. J. (2002) Nat. Struct. Biol. 9, 42-47] persists in the active sites of the Ca(2+)-bound structure; however, kinetic data show little effect on the single-turnover rate of DNA cleavage in the absence of Na(+) ions.     

Structural characterization of the tetrameric form of the major cat allergen Fel d 1

Felis domesticus allergen 1(Fel d 1) is a 35 kDa tetrameric glycoprotein formed by two heterodimers which elicits IgE responses in 95% of patients with allergy to cat. We have previously established in vitro conditions for the appropriate folding of recombinant Fel d 1 using a direct linkage of chain 1 to chain 2 (construct Fel d 1 (1+2)) and chain 2 to chain 1 (construct Fel d 1 (2+1)). Although the crystal structure of Fel d 1 (2+1) revealed a striking structural similarity to that of uteroglobin, a steroid-inducible cytokine-like molecule with anti-inflammatory and immunomodulatory properties, no functional tetrameric form of Fel d 1 could be identified. Here we present the crystal structure of the Fel d 1 (1+2) tetramer at 1.6 A resolution. Interestingly, the crystal structure of tetrameric Fel d 1 reveals two different calcium-binding sites. Symmetrically positioned on each side of the Fel d 1 tetramer, the external Ca(2+)-binding sites correspond to a putative Ca(2+)-binding site previously suggested for uteroglobin. The second Ca(2+)-binding site lies within the dimerization interface, stabilizing the formation of the Fel d 1 tetramer, and inducing important local conformational changes that directly govern the shape of two water-filled cavities. The crystal structure suggests a potential portal for an unknown ligand. Alternatively, the two cavities could be used by the allergen as a conditional inner space allowing for the spatial rearrangement of centrally localized side-chains, such as Asp130, without altering the overall fold of the molecule. The striking structural similarity of the major cat allergen to uteroglobin, coupled to the identification in the present study of a common Ca(2+)-binding site, let us speculate that Fel d 1 could provoke an allergic response through the modulation of phospholipase A2, by sequestering Ca ions in a similar manner as previously suggested for uteroglobin.     

Proton paths in the sarcoplasmic reticulum Ca(2+) -ATPase

The sarcoplasmic reticulum Ca(2+)-ATPase (SERCA1a) pumps Ca(2+) and countertransport protons. Proton pathways in the Ca(2+) bound and Ca(2+)-free states are suggested based on an analysis of crystal structures to which water molecules were added. The pathways are indicated by chains of water molecules that interact favorably with the protein. In the Ca(2+) bound state Ca(2)E1, one of the proposed Ca(2+) entry paths is suggested to operate additionally or alternatively as proton pathway. In analogs of the ADP-insensitive phosphoenzyme E2P and in the Ca(2+)-free state E2, the proton path leads between transmembrane helices M5 to M8 from the lumenal side of the protein to the Ca(2+) binding residues Glu-771, Asp-800 and Glu-908. The proton path is different from suggested Ca(2+) dissociation pathways. We suggest that separate proton and Ca(2+) pathways enable rapid (partial) neutralization of the empty cation binding sites. For this reason, transient protonation of empty cation binding sites and separate pathways for different ions are advantageous for P-type ATPases in general.     

Molecular dynamics simulations revealed Ca(2+)-dependent conformational change of Calmodulin

Molecular dynamics simulations were performed to simulate Ca(2+)-dependent conformational change of calmodulin (CaM). Simulations of the fully Ca(2+)-bound form of CaM (Holo-CaM) and the Ca(2+)-free form (Apo-CaM) were performed in solution for 4 ns starting from the X-ray crystal structure of Holo-CaM. A striking difference was observed between the trajectories of Holo-CaM and Apo-CaM: the central helix remained straight in the former but became largely bent in the latter. Also, the flexibility of Apo-CaM was higher than that of Holo-CaM. The results indicated that the bound Ca(2+) ions harden the structure of CaM.