Effects of calcium binding on the structure and stability of human growth hormone

Thermodynamic analysis of calcium ions binding to human growth hormone (hGH) was done at 27 °C in NaCl solution, 50 mM, using different techniques. The binding isotherm for hGH-Ca²⁺ was obtained by two techniques of ionmetry, using a Ca²⁺-selective membrane electrode, and isothermal titration calorimetry. Results obtained by two ionmetric and calorimetric methods are in good agreement. There is a set of three identical and non-interacting binding sites for calcium ions. The intrinsic dissociation equilibrium constant and the molar enthalpy of binding are 52 μM and −17.4 kJ/mol, respectively. Temperature scanning UV–vis spectroscopy was applied to elucidate the effect of Ca²⁺ binding on the protein stability, and circular dichroism (CD) spectroscopy was used to show the structural change of hGH due to the metal ion interaction. Calcium ions binding increase the protein thermal stability by increasing of the alpha helix content as well as decreasing of both beta and random coil structures.     

Metal ion binding properties and conformational states of calcium- and integrin-binding protein

Calcium- and integrin-binding protein (CIB) is a novel member of the helix-loop-helix family of regulatory calcium-binding proteins which likely has a specific function in hemostasis through its interaction with platelet integrin alphaIIbbeta(3). The significant amino acid sequence homology between CIB and other regulatory calcium-binding proteins such as calmodulin, calcineurin B, and recoverin suggests that CIB may undergo a calcium-induced conformational change; however, the mechanism of calcium binding and the details of a structural change have not yet been investigated. Consequently, we have performed a variety of spectroscopic and microcalorimetric studies of CIB to determine its calcium binding characteristics, and the subsequent conformational changes that occur. Furthermore, we provide the first evidence for magnesium binding to CIB and determine the structural consequences of this interaction. Our results indicate that in the absence of any bound metal ions, apo-CIB adopts a folded yet highly flexible molten globule-like structure. Both calcium and magnesium binding induce conformational changes which stabilize both the secondary and tertiary structure of CIB, resulting in considerable increases in the thermal stability of the proteins. CIB was found to bind two Ca(2+) ions in a sequential manner with dissociation constants (K(d)) near 0.54 and 1.9 microM for sites EF-4 and EF-3, respectively. In contrast, CIB bound only one Mg(2+) ion to EF-3 with a K(d) near 120 microM. Together, our results suggest that CIB may exist in multiple structural and metal ion-bound states in vivo which may play a role in its regulation of target proteins such as platelet integrin.     

Thermodynamic study of the binding of calcium and magnesium ions with myelin basic protein using the extended solvation theory

The interaction of myelin basic protein (MBP) from the bovine central nervous system with Ca2+ and Mg2+ ions, named as M2+, was studied by isothermal titration calorimetry at 27 degrees C in aqueous solution. The extended solvation model was used to reproduce the enthalpies of MBP+M2+ interactions. The solvation parameters recovered from the extended solvation model were attributed to the structural change of MBP due to the metal ion interaction. It was found that there is a set of two identical and noninteracting binding sites for Ca2+ and Mg2+ ions.     

Finding a needle in the haystack: computational modeling of Mg2+ binding in the active site of protein farnesyltransferase

Studies aimed at elucidating the unknown Mg2+ binding site in protein farnesyltransferase (FTase) are reported. FTase catalyzes the transfer of a farnesyl group to a conserved cysteine residue (Cys1p) on a target protein, an important step for proteins in the signal transduction pathways (e.g., Ras). Mg2+ ions accelerate the protein farnesylation reaction by up to 700-fold. The exact function of Mg2+ in catalysis and the structural characteristics of its binding remain unresolved to date. Molecular dynamics (MD) simulations addressing the role of magnesium ions in FTase are presented, and relevant octahedral binding motifs for Mg2+ in wild-type (WT) FTase and the Dβ352A mutant are explored. Our simulations suggest that the addition of Mg2+ ions causes a conformational change to occur in the FTase active site, breaking interactions known to keep FPP in its inactive conformation. Two relevant Mg2+ ion binding motifs were determined in WT FTase. In the first binding motif, WT1, the Mg2+ ion is coordinated to D352β, zinc-bound D297β, two water molecules, and one oxygen atom from the α- and β-phosphates of farnesyl diphosphate (FPP). The second binding motif, WT2, is identical with the exception of the zinc-bound D297β being replaced by a water molecule in the Mg2+ coordination complex. In the Dβ352A mutant Mg2+ binding motif, D297β, three water molecules, and one oxygen atom from the α- and β-phosphates of FPP complete the octahedral coordination sphere of Mg2+. Simulations of WT FTase, in which Mg2+ was replaced by water in the active site, recreated the salt bridges and hydrogen-bonding patterns around FPP, validating these simulations. In all Mg2+ binding motifs, a key hydrogen bond was identified between a magnesium-bound water and Cys1p, bridging the two metallic binding sites and, thereby, reducing the equilibrium distance between the reacting atoms of FPP Cys1p. The free energy profiles calculated for these systems provide a qualitative understanding of experimental results. They demonstrate that the two reactive atoms approach each other more readily in the presence of Mg2+ in WT FTase and mutant. The flexible WT2 model was found to possess the lowest barrier toward the conformational change, suggesting it is the preferred Mg2+ binding motif in WT FTase. In the mutant, the absence of D352β makes the transition toward a conformational change harder. Our calculations find support for the proposal that D352β performs a critical role in Mg2+ binding and Mg2+ plays an important role in the conformational transition step.     

Direct fluorescence measurements of Mg2+ binding to sarcoplasmic reticulum ATPase

In the absence of calcium, interaction of magnesium with SR-ATPase induced a blue shift in intrinsic fluorescence emission. This Mg2+-induced fluorescence change was pH-dependent and an apparent Mg dissociation constant of 5 mM was found at pH 7. Equilibrium studies showed that magnesium competes for the high affinity Ca2+ binding sites and stopped flow measurements of the transient kinetics indicated a multistep interaction between magnesium and the calcium pump. These results suggest that magnesium drives the sarcoplasmic reticulum atpase toward an E.Mg species which might be a dead-end complex.     

Regulation of free and bound magnesium in rat hepatocytes and isolated mitochondria

Null point titration techniques have been developed for measurements of cytosolic free Mg2+ in isolated cells and matrix free Mg2+ in isolated mitochondria using antipyrylazo III as a spectrophotometric Mg2+ indicator. A cytosolic free Mg2+ of 0.37 +/- 0.02 mM was obtained with hepatocytes. This represented about 6% of the total cytosolic magnesium content (activity coefficient of 5.8 X 10(-2). Nondiffusable Mg2+-binding sites in the cytosol were equal to 11.1 nmol/mg cell dry weight with an apparent dissociation constant of 0.71 mM and accounted for binding of 32% of the cytosolic magnesium. The null point method gave a value of 0.35 +/- 0.01 mM for the mitochondrial matrix free Mg2+ concentration (activity coefficient of 8.8 X 10(-3). Nondiffusable Mg2+ binding sites in the mitochondria were estimated at 25.7 nmol/mg mitochondrial protein with an apparent dissociation constant of 0.22 mM, compared with an apparent dissociation constant of 1.66 microM for bound calcium. These data demonstrate the absence of a significant gradient of free Mg2+ between the cytosolic and mitochondrial compartments. They also demonstrate a high ligand binding capacity for magnesium in both compartments with relatively low affinity resulting in a constant value for free Mg2+ when total cell magnesium is constant. This maintains a ratio between free Mg2+ and free Ca2+ of about 2000 in the cytosol and 100 in the mitochondria. The high concentration and low affinity of Mg2+ binding sites results in rather large changes of free Mg2+ with small variations in total cell magnesium. This is apparent in hepatocytes isolated from streptozotocin diabetic rats which had a decreased total magnesium content and a cytosolic free Mg2+ of 0.16 +/- 0.02 mM.     

Protein stabilization and destabilization by guanidinium salts

Preferential interactions of bovine serum albumin were measured with guanidine sulfate, guanidine acetate, and guanidine hydrochloride. The results showed an increasing preferential hydration with increasing salt concentration for the sulfate, positive preferential salt binding for the hydrochloride, and an intermediate situation for the acetate. These results correlate well with the known effects of the three salts on protein stability, namely, the stabilizing effect of guanidine sulfate and the denaturing effect of guanidine hydrochloride. Comparison of guanidinium and magnesium salts indicated that the substitution of guanidinium ion for Mg2+ decreases the preferential hydration and increases the preferential salt binding, suggesting that the perturbation by guanidinium ion binding of the surface free energy is greater than that by Mg2+ ion. It was concluded that guanidine salts are not a special class, but their activity toward proteins is modulated by the same fine balance between hydration and salt binding to protein as in the case of other salts, with the second factor being stronger in guanidine salts.     

The role of magnesium and potassium ions in the molecular mechanism of ribosome assembly: hydrodynamic, conformational, and thermal stability studies of 16 S RNA from Escherichia coli ribosomes

In an attempt to understand the role of magnesium ion in ribosome assembly in vitro, the hydrodynamic shape, conformation, and thermal stability of ribosomal 16 S RNA were studied systematically as a function of Mg2+ concentration by sedimentation velocity, intrinsic viscosity, circular dichroism, and difference ultraviolet absorption spectroscopy. These results were then compared with the corresponding parameters obtained for 16 S RNA under the optimal conditions of reconstitution, i.e., at 37 degrees C, 20 mM Mg2+, an ionic strength equal to 0.37, and pH 7.8 [S. H. Allen, and K.-P. Wong (1978) J. Biol. Chem. 253, 8759-8766]. When the 360 mM KCl required for reconstitution of 30 S ribosomes is added to the medium, only subtle conformational changes are observed, consistent with the destabilization of the conformation, thus making the RNA molecule more "open" and accessible to protein binding. However, when the concentration of Mg2+ is lowered from 20 to 1 mM, the hydrodynamic parameters indicate that the 16 S RNA is partially unfolded, while thermal denaturation studies suggest that the amount of base-stacking and base-pairing is not concomitantly altered. Further removal of the Mg2+ by dialysis against a pH 7.8 buffer containing no Mg2+ results in a drastic decrease of secondary structure and indicates that the Mg2+ is required for maintenance of the pairing, stacking, and stability of the nucleotide bases, in addition to the long range interactions which result in a compact structure. The results suggest that the 20 mM Mg2+ is required for the 16 S RNA molecules to assume the proper secondary and tertiary structure containing the protein-binding sites, while the high K+ concentration (360 mM KCl) is needed for "loosening up" the RNA, making the protein binding sites more accessible to the ribosomal proteins for molecular recognition and binding as well as for the conformational changes that occur during ribosome assembly.     

Solution structure and thermodynamics of a divalent metal ion binding site in an RNA pseudoknot.

Identification and characterization of a metal ion binding site in an RNA pseudoknot was accomplished using cobalt (III) hexammine, Co(NH3)63+, as a probe for magnesium (II) hexahydrate, Mg(H2O)62+, in nuclear magnetic resonance (NMR) structural studies. The pseudoknot causes efficient -1 ribosomal frameshifting in mouse mammary tumor virus. Divalent metal ions, such as Mg2+, are critical for RNA structure and function; Mg2+preferentially stabilizes the pseudoknot relative to its constituent hairpins. The use of Co(NH3)63+as a substitute for Mg2+was investigated by ultraviolet absorbance melting curves, NMR titrations of the imino protons, and analysis of NMR spectra in the presence of Mg2+or Co (NH3)63+. The structure of the pseudoknot-Co(NH3)63+complex reveals an ion-binding pocket formed by a short, two-nucleotide loop and the major groove of a stem. Co(NH3)63+stabilizes the sharp loop-to-stem turn and reduces the electrostatic repulsion of the phosphates in three proximal strands. Hydrogen bonds are identified between the Co(NH3)63+protons and non-bridging phosphate oxygen atoms, 2' hydroxyl groups, and nitrogen and oxygen acceptors on the bases. The binding site is significantly different from that previously characterized in the major groove surface of tandem G.U base-pairs, but is similar to those observed in crystal structures of a fragment of the 5 S rRNA and the P5c helix of the Tetrahymena thermophila group I intron. Changes in chemical shifts occurred at the same pseudoknot protons on addition of Mg2+as on addition of Co(NH3)63+, indicating that both ions bind at the same site. Ion binding dissociation constants of approximately 0.6 mM and 5 mM (in 200 mM Na+and a temperature of 15 degrees C) were obtained for Co(NH3)63+and Mg2+, respectively, from the change in chemical shift as a function of metal ion concentration. An extensive array of non-sequence-specific hydrogen bond acceptors coupled with conserved structural elements within the binding pocket suggest a general mode of divalent metal ion stabilization of this type of frameshifter pseudoknot. These results provide new thermodynamic and structural insights into the role divalent metal ions play in stabilizing RNA tertiary structural motifs such as pseudoknots.     

DNA recognition by the homing endonuclease PI-SceI involves a divalent metal ion cofactor-induced conformational change

PI-SceI, a homing endonuclease of the LAGLIDADG family, consists of two domains involved in DNA cleavage and protein splicing, respectively. Both domains cooperate in binding the recognition sequence. Comparison of the structures of PI-SceI in the absence and presence of substrate reveals major conformational changes in both the protein and DNA. Notably, in the protein-splicing domain the loop comprising residues 53-70 and adopts a "closed" conformation, thus enabling it to interact with the DNA. We have studied the dynamics of DNA binding and subsequent loop movement by fluorescence techniques. Six amino acids in loop53-70 were individually replaced by cysteine and modified by fluorescein. The interaction of the modified PI-SceI variants with the substrate, unlabeled or labeled with tetramethylrhodamine, was analyzed in equilibrium and stopped-flow experiments. A kinetic scheme was established describing the interaction between PI-SceI and DNA. It is noteworthy that the apparent hinge-flap motion of loop53-70 is only observed in the presence of a divalent metal ion cofactor. Substitution of the major Mg2+-binding ligands in PI-SceI, Asp-218 and Asp-326, by Asn or "nicking" PI-SceI with trypsin at Arg-277, which interferes with formation of an active enzyme.substrate complex, both prevent the conformational change of loop53-70. Deletion of the loop inactivates the enzyme. We conclude that loop53-70 is an important structural element that couples DNA recognition by the splicing domain with DNA cleavage by the catalytic domain and as such "communicates" with the Mg2+ binding sites at the catalytic centers.     

Mutagenesis studies of protein farnesyltransferase implicate aspartate beta 352 as a magnesium ligand

Protein farnesyltransferase (FTase) catalyzes the addition of a farnesyl chain onto the sulfur of a C-terminal cysteine of a protein substrate. Magnesium ions enhance farnesylation catalyzed by FTase by several hundred-fold, with a KMg value of 4 mM. The magnesium ion is proposed to coordinate the diphosphate leaving group of farnesyldiphosphate (FPP) to stabilize the developing charge in the farnesylation transition state. Here we further investigate the magnesium binding site using mutagenesis and biochemical studies. Free FPP binds Mg2+ with a Kd of 120 microM. The 10-fold weaker affinity for Mg2+ observed for the FTase.FPP.peptide ternary complex is probably caused by the positive charges in the diphosphate binding pocket of FTase. Furthermore, mutation of aspartate beta 352 to alanine (D beta 352A) or lysine (D beta 352K) in FTase drastically alters the Mg2+ dependence of FTase catalysis without dramatically affecting the rate constant of farnesylation minus magnesium or the binding affinity of either substrate. In D beta 352A FTase, the KMg increases 28-fold to 110 +/- 30 mM, and the farnesylation rate constant at saturating Mg2+ decreases 27-fold to 0.30 +/- 0.05 s-1. Substitution of a lysine for Asp-beta 352 removes the magnesium activation of farnesylation catalyzed by FTase but does not significantly enhance the rate constant for farnesylation in the absence of Mg2+. In wild type FTase, Mg2+ can be replaced by Mn2+ with a 2-fold lower KMn (2 mM). These results suggest both that Mg2+ coordinates the side chain carboxylate of Asp-beta 352 and that the role of magnesium in the reaction includes positioning the FPP prior to catalysis.     

DNA structural transitions induced by divalent metal ions in aqueous solutions

Using methods of IR spectroscopy, light scattering, gel-electrophoresis DNA structural transitions are studied under the action of Cu2+, Zn2+, Mn2+, Ca2+ and Mg2+ ions in aqueous solution. Cu2+, Zn2+, Mn2+ and Ca2+ ions bind both to DNA phosphate groups and bases while Mg2+ ions-only to phosphate groups of DNA. Upon interaction with divalent metal ions studied (except for Mg2+ ions) DNA undergoes structural transition into a compact form. DNA compaction is characterized by a drastic decrease in the volume occupied by DNA molecules with reversible formation of DNA dense particles of well-defined finite size and ordered morphology. The DNA secondary structure in condensed particles corresponds to the B-form family. The mechanism of DNA compaction under Mt2+ ion action is not dominated by electrostatics. The effectiveness of the divalent metal ions studied to induce DNA compaction correlates with the affinity of these ions for DNA nucleic bases: Cu2+>Zn2+>Mn2+>Ca2+>Mg2+. Mt2+ ion interaction with DNA bases (or Mt2+ chelation with a base and an oxygen of a phosphate group) may be responsible for DNA compaction. Mt2+ ion interaction with DNA bases can destabilize DNA causing bends and reducing its persistent length that will facilitate DNA compaction.     

Conformation and ion binding properties of peptides related to calcium binding domain III of bovine brain calmodulin

The conformational and ion binding properties of the sequences 93-104, 96-104, and 93-98 of domain III of bovine brain calmodulin (CaM) have been studied by CD and Tb3+-mediated fluorescence. In aqueous solution the interaction of all fragments with Ca2+ and Mg2+ ions is very weak and without any effect on the peptide conformation, which remains always random. In trifluoroethanol the interaction is very strong and the different fragments exhibit very distinct binding properties. In particular, the dodecapeptide fragment 93-104, and its N-terminal hexapeptide 98-104, bind calcium and magnesium with a very high binding constant (Kb greater than 10(5) M-1), undergoing a substantial conformational change. The structural rearrangement is particularly evident in the hexapeptide fragment, which tend to form a beta-bend. The C-terminal nonapeptide fragment 96-104 interacts with calcium and magnesium more weakly, and the binding process causes a decrease of ordered structure. These results suggest that, even in the entire dodecapeptide sequence corresponding to the loop of domain III of CaM, the calcium binding site is shifted toward the N-terminal hexapeptide segment. This interpretation is consistent with the results of crystallographic studies of CaM, which show that the calcium ions are located toward the amino terminal portion of the loop.     

Human flap endonuclease-1: conformational change upon binding to the flap DNA substrate and location of the Mg2+ binding site

Human flap endonuclease-1 (FEN-1) is a member of the structure-specific endonuclease family and is a key enzyme in DNA replication and repair. FEN-1 recognizes the 5'-flap DNA structure and cleaves it, a specialized endonuclease function essential for the processing of Okazaki fragments during DNA replication and for the repair of 5'-end single-stranded tails from nicked double-stranded DNA substrates. Magnesium is a cofactor required for nuclease activity. We have used Fourier transform infrared (FTIR) spectroscopy to better understand how Mg2+ and flap DNA interact with human FEN-1. FTIR spectroscopy provides three fundamentally new insights into the structural changes induced by the interaction of FEN-1 with substrate DNA and Mg2+. First, FTIR difference spectra in the amide I vibrational band (1600-1700 cm(-1)) reveal a change in the secondary structure of FEN-1 induced by substrate DNA binding. Quantitative analysis of the FTIR spectra indicates a 4% increase in helicity upon DNA binding or about 14 residues converted from disordered to helical conformations. The observation that the residues are disordered without DNA strongly implicates the flexible loop region. The conversion to helix also suggests a mechanism for locking the flexible loop region around the bound DNA. This is the first direct experimental evidence for a binding mechanism that involves a secondary structural change of the protein. Second, in contrast with DNA binding, no change is observed in the secondary structure of FEN-1 upon Mg2+ binding to the wild type or to the noncleaving D181A mutant. Third, the FTIR results provide direct evidence (via the carboxylate ligand band at 1535 cm(-1)) that not only is D181 a ligand to Mg2+ in the human enzyme but Mg2+ binding does not occur in the D181A mutant which lacks this ligand.     

Salt or ion bridges in biological systems: a study employing quantum and molecular mechanics

Equilibrium geometries and binding energies of model "salt" or "ion" bridge systems have been computed by ab initio quantum chemistry techniques (GAUSSIAN82) and by empirical force field techniques (AMBER2.0). Formate and dimethyl phosphate served as anions in the model compounds while interacting with several organic cations, including methyl ammonium, methyl guanidinium, and divalent metal ion (either Mg2+ or Ca2+) without and with an additional chloride; and a divalent metal ion (either Mg2+ or Ca2+), chloride, and four water molecules of hydration about the metal ion. The majority of the quantum chemical computations were performed using a split-valence basis set. For the model compounds studied we find that the ab initio optimized geometries are in remarkably good agreement with the molecular mechanics geometries. Several calculations were also performed using diffuse fractions. The formate anion binds these model cations more strongly than does dimethyl phosphate, while the organic cation methyl ammonium binds model anions more strongly than does methyl guanidinium. Finally, in model compounds including organic anions, Mg2+ or Ca2+ and four molecules of water, and a chloride anion, we find that the equilibrium structure of the magnesium complex involves a solvent separated ion pair (the magnesium ion is six coordinate), whereas the calcium ion complex remains seven coordinate. Molecular mechanics overestimates binding energies, but the estimates may be close enough to actual binding energies to give useful insight into the details of salt bridges in biological systems.     

Structural basis for the negative allostery between Ca(2+)- and Mg(2+)-binding in the intracellular Ca(2+)-receptor calbindin D9k.

The three-dimensional structures of the magnesium- and manganese-bound forms of calbindin D9k were determined to 1.6 A and 1.9 A resolution, respectively, using X-ray crystallography. These two structures are nearly identical but deviate significantly from both the calcium bound form and the metal ion-free (apo) form. The largest structural differences are seen in the C-terminal EF-hand, and involve changes in both metal ion coordination and helix packing. The N-terminal calcium binding site is not occupied by any metal ion in the magnesium and manganese structures, and shows little structural deviation from the apo and calcium bound forms. 1H-NMR and UV spectroscopic studies at physiological ion concentrations show that the C-terminal site of the protein is significantly populated by magnesium at resting cell calcium levels, and that there is a negative allosteric interaction between magnesium and calcium binding. Calcium binding was found to occur with positive cooperativity at physiological magnesium concentration.     

ADP, chloride ion, and metal ion binding to bovine brain glutamine synthetase

The binding of divalent cations and nucleotide to bovine brain glutamine synthetase and their effects on the activity of the enzyme were investigated. In ADP-supported gamma-glutamyl transfer at pH 7.2, kinetic analyses of saturation functions gave [S]0.5 values of approximately 1 microM for Mn2+, approximately 2 mM for Mg2+, 19 nM for ADP.Mn, and 7.2 microM for ADP.Mg. The method of continuous variation applied to the Mn2+-supported reaction indicated that all subunits of the purified enzyme express activity when 1.0 equiv of ADP is bound per subunit. Measurements of equilibrium binding of Mn2+ to the enzyme in the absence and presence of ADP were consistent with each subunit binding free Mn2+ (KA approximately equal to 1.5 X 10(5) M-1) before binding the Mn.ADP complex (KA' approximately equal to 1.1 X 10(6) M-1). The binding of the first Mn2+ or Mg2+ to each subunit produces structural perturbations in the octameric enzyme, as evidenced by UV spectral and tryptophanyl residue fluorescence changes. The enzyme, therefore, has one structural site per subunit for Mn2+ or Mg2+ and a second site per subunit for the metal ion-nucleotide complex, both of which must be filled for activity expression. Chloride binding (KA' approximately equal to 10(4) M-1) to the enzyme was found to have a specific effect on the protein conformation, producing a substantial (30%) quench of tryptophanyl fluorescence and increasing the affinity of the enzyme 2-4-fold for Mg2+ or Mn2+. Arsenate, which activates the gamma-glutamyl transfer activity by binding to an allosteric site, and L-glutamate also cause conformational changes similar to those produced by Cl- binding. Anion binding to allosteric sites and divalent metal ion binding at active sites both produce tryptophanyl residue exposure and tyrosyl residue burial without changing the quaternary enzyme structure.