Derivatives of blood coagulation factor IX contain a high affinity Ca2+-binding site that lacks gamma-carboxyglutamic acid

We have examined the calcium-binding properties and metal ion-dependent conformational changes of proteolytically modified derivatives of factor IX that lack gamma-carboxyglutamic acid (Gla) residues. Equilibrium dialysis experiments demonstrated that a Gla-domainless factor IX species retained a single high affinity calcium ion-binding site (Kd = 85 +/- 5 microM). Ca2+ binding to this site was accompanied by a decrease in intrinsic fluorescence emission intensity (Kd = 63 +/- 15 microM). These spectral changes were reversed upon the addition of EDTA. Titration with Sr2+ resulted in little change in fluorescence intensity below 1 mM, while titration with Tb3+ caused fluorescence changes similar to those observed with Ca2+. Tb3+ and Ca2+ appear to bind to the same site because tryptophan-dependent terbium emission was reduced by the addition of Ca2+. Similar results were obtained with a Gla-domainless factor IX species lacking the activation peptide. Gla domain-containing factor IX species exhibited fluorescence changes similar to those of the Gla-domainless proteins at low Ca2+, but an additional structural transition was found at higher Ca2+ concentrations (apparent Kd greater than 0.8 mM). Thus, the conformations of factor IX proteins are nucleated and/or stabilized by calcium binding to a high affinity site which does not contain Gla residues. The binding of Ca2+ to lower affinity Gla domain-dependent metal ion-binding sites elicits an additional conformational change. The strong similarities between these results and those obtained with protein C (Johnson, A. E., Esmon, N. L., Laue, T. M. & Esmon, C. T. (1983) J. Biol. Chem. 258, 5554-5560), coupled with the remarkable sequence homologies of the vitamin K-dependent proteins, suggest that the high affinity Gla-independent Ca2+-binding site may be a common feature of vitamin K-dependent proteins.     

Chemical modification of bovine prothrombin fragment 1 in the presence of Tb3+ ions. Sequence studies on 3-gamma-MGlu-fragment

Chemical modification of the gamma-carboxyglutamyl (Gla) residues of bovine prothrombin fragment 1 using the formaldehyde-morpholine method in the presence of 100 Kappm Tb3+ ions at pH 5.0 provided a modified protein containing 3 gamma-methyleneglutamyl residues (gamma-MGlu) and 7 Gla residues (bovine 3-gamma-MGlu-fragment 1). The modified protein bound the same number of Ca2+ ions as the native protein (six to seven), exhibited 28Mg2+-binding properties identical to native fragment 1 (five Mg2+ ions bound), exhibited the metal ion-promoted quenching of the intrinsic fluorescence in a manner similar to the native protein, but did not bind to phosphatidylserine (PS)/phosphatidylcholine (PC) vesicles in the presence of Ca2+ ions. Modification of the bovine protein using [14C]formaldehyde-morpholine provided a 14C-labeled 3-gamma-MGlu-fragment 1 suitable for sequence analysis. Edman sequencing of the peptides released by a tryptic digest of the reduced and carboxymethylated bovine [14C]3-gamma-MGlu-fragment 1 indicated that Gla residues at positions 7, 8, and 33 had been converted to [14C]gamma-methyleneglutamyl residues. In addition Lys97 was found to contain a 14C label. Similar analysis of the human [14C]3-gamma-MGlu-fragment 1 indicated that Gla residues at positions 7 and 32 were major modification sites and that Gla residues at positions 6 and 14 were partially modified. Lysine 96 was also modified in the human protein. The incorporation of a 14C label at Lys97 in bovine 3-gamma-MGlu-fragment 1 protein is not responsible for the loss of Ca2+-promoted binding to PS/PC vesicles. We suggest that Gla residues 7, 8, and 33 are elements of the first Ca2+-binding site; occupancy of this site establishes the Ca2+-specific conformation which is essential for the Ca2+-promoted interaction of the bovine protein with PS/PC vesicles. These studies also suggest that the loss of Gla residues at positions 7 and 32 prevents the formation of the initial Ca2+-binding site in the human protein.     

Metal and phospholipid binding properties of partially carboxylated human prothrombin variants

To study the specific role of gamma-carboxyglutamic acid (Gla) residues in prothrombin, we have isolated a series of partially carboxylated prothrombin variants from a patient with a hereditary defect in vitamin K-dependent carboxylation (Goldsmith, G. H., Pence, R. E., Ratnoff, O. D., Adelstein, D. A., and Furie, B. (1982) J. Clin. Invest. 69, 1253-1260). The three variant prothrombins, purified by DEAE-Sephacel, immunoaffinity chromatography, and preparative gel electrophoresis, were indistinguishable from prothrombin in molecular weight, amino acid composition, and NH2-terminal amino acid sequence, with the exception of Gla residues. Variant prothrombin 1, with 8 Gla residues, had 66% of the coagulant activity of prothrombin, one high affinity metal-binding site (Kd = 15 nM), and three lower affinity sites (Kd = 2.7 microM); prothrombin contained two high affinity (36 nM) and four lower affinity sites (Kd = 1 microM). Ca(II) induced a 23% decrease in the intrinsic fluorescence of variant prothrombin 1 fragment 1, compared to a 35% decrease in that of prothrombin fragment 1. The phospholipid binding activity of variant prothrombin 1 was 44% that of prothrombin. Variant prothrombin 2 and variant prothrombin 3, with 4 and 6 Gla residues, respectively, had about 5% of prothrombin coagulant activity and a single high affinity and two lower affinity metal-binding sites and exhibited no phospholipid binding activity. Variant prothrombin 3 fragment 1 and variant prothrombin 2 fragment 1 demonstrated 18 and 13% of Ca(II)-induced fluorescence quenching, respectively. Abnormal prothrombin, with 1 Gla residue, had 8% of prothrombin coagulant activity, a single lower affinity (1 microM) metal-binding site, and 13% Ca(II)-induced fluorescence quenching of the fragment 1 species and did not bind to phospholipid. These results indicate that Gla residues define the metal binding properties of prothrombin. Most, if not all, of the Gla residues are required for complete prothrombin function, and the prothrombin coagulant activity correlates to the phospholipid binding activity of the prothrombin species.     

Calcium-dependent alpha-helical structure in osteocalcin

Osteocalcin is an abundant Ca2+-binding protein of bone containing three residues of vitamin K dependent gamma-carboxyglutamic acid (Gla) among its 49 (human, monkey, cow) or 50 (chicken) amino acids. Gla side chains participate directly in the binding of Ca2+ ions and the adsorption of osteocalcin to hydroxylapatite (HA) surfaces in vivo and in vitro. Osteocalcin exhibits a major conformational change when Ca2+ is bound. Metal-free chicken osteocalcin is a random coil with only 8% of its residues in the alpha helix as revealed by circular dichroism. In the presence of physiological levels of Ca2+, 38% of the protein adopts the alpha-helical conformation with a transition midpoint at 0.75 mM Ca2+ in a rapid, reversible fashion which (1) requires an intact disulfide bridge, (2) is proportionally diminished when Gla residues are decarboxylated to Glu, (3) is insensitive to 1.5 m NaCl, and (4) can be mimicked by other cations. Tyr fluorescence, UV difference spectra, and Tyr reactivity to tetranitromethane corroborate the conformational change. Homologous monkey osteocalcin also exhibits Ca2+-dependent structure. Integration of predictive calculations from osteocalcin sequence has yielded a structural model for the protein, the dominant features of which include two opposing alpha-helical domains of 9-12 residues each, connected by a bea turn and stabilized by the Cys23-Cys29 disulfide bond. Cation binding permits realization of the full alph a-helical potential by partial neutralization of high anionic charge in the helical domains. Periodic Gla occurrence at positions 17, 21, and 24 has been strongly conserved throughout evolution and places all Gla side chains on the same face of one alpha helix spaced at intervals of approximately 5.4 A, closely paralleling the interatomic separation of Ca2+ in the HA lattice. Helical osteocalcin has greatly increased affinity for HA; thus, the Ca2+-induced structural transition may perform an informational role related to bone metabolism.     

Cyclic peptide models of the Ca2+-binding loop of alpha-lactalbumin

A series of cyclic peptides with different linkers were designed and synthesized to model the elbow-type Ca2+-binding loop of alpha-lactalbumin (LA). All amino acids of the Ca2+-binding loop are strikingly well conserved among LAs of different species with the sequence Lys79-Phe-Leu-Asp82-Asp-Asp-Leu-Thr- Asp87-Asp88, where three carboxylates of Asp82, Asp87, and Asp88 and the amide carbonyl oxygen atoms of Lys79 and Asp84 participate in Ca2+ binding. Alanine-containing models were also prepared for monitoring the role of the binding (82, 87-88) and nonbinding Asp residues (83-84) in coordinating the cation. The structural features of synthetic peptides and their Ca2+-binding properties were investigated in solution by circular dichroism (CD) and Fourier transform infrared (FTIR) spectroscopy. In water, the CD curves show a strong negative band below 200 nm as a sign of the presence of unfolded conformers. In TFE, all cyclic peptides were found to have a CD spectrum, reflecting the presence of folded (turn) conformers. The effect of Ca2+ was dependent on the structure and concentration of the model and the Ca2+ to peptide ratio (r(cat)). A surprising time dependence of the FTIR spectra of Ca2+ complexes of the Ala-containing peptides was observed. The shape of the broad amide I band showed no more change after approximately 60 min. Contrary to this, the deprotonation of the side chain COOH group(s) and formation of the final coordination sphere of Ca2+ took more time. Infrared spectra showed that in the Ca2+ complex of model comprising the binding Asp residues of LA, the cation is coordinated to the COO- groups of all three Asps, while in the complex of model comprising nonbinding Asp residues of LA, the two neighboring Asp side chains form a bridged Ca2+-binding system.     

Laser Raman spectroscopy of calf bone Gla protein

The Raman spectra of solid calf bone Gla protein in its native state, decarboxylated, with reduced disulfide bond, and as the calcium salt have been obtained. The amide I and III bands are consistent with the presence of alpha-helical, antiparallel beta-sheet, and random-coil regions in all four forms of bone Gla protein. Random coil appears to be the prevailing conformation. The protein conformation in the calcium salt exhibits an increased alpha-helix character compared to the native protein. No significant differences in the backbone conformation are observed among the native, decarboxylated, and reduced forms of bone Gla protein. The Raman band at 504 cm-1, due to the disulfide stretching vibration in native bone Gla protein, is unchanged upon decarboxylation and binding of Ca2+ to the protein, indicating the absence of any changes in the conformation around the disulfide bond in these protein species. The tryptophan and most of the tyrosine residues appear to be 'exposed' rather than 'buried' in the native protein. The environment of at least one of the phenylalanine residues changes when Ca2+ is bound to bone Gla protein. A small change also appears to take place in the environment of at least one of the tyrosine residues upon Ca2+-binding or reduction of the disulfide bond.     

Iron binding to horse spleen apoferritin: a vanadyl ENDOR spin probe study.

The role of the protein shell in the formation of the hydrous ferric oxide core of ferritin is poorly understood. A VO2+ spin probe study was undertaken to characterize the initial complex of Fe2+ with horse spleen apoferritin (96% L-subunits). A competitive binding study of VO2+ and Fe2+ showed that the two metals compete 1:1 for binding at the same site or region of the protein. Curve fitting of the binding data showed that the affinity of VO2+ for the protein was 15 times that of Fe2+. Electron nuclear double resonance (ENDOR) measurements on the VO(2+)-apoferritin complex showed couplings from two nitrogen nuclei, tentatively ascribed to the N1 and N3 nitrogens of the imidazole ligand of histidine. The possibility that the observed nitrogen couplings are from two different ligands is not precluded by the data, however. A pair of exchangeable proton lines with a coupling of approximately 1 MHz is tentatively assigned to the NH proton of the coordinated nitrogen. A 30-40% reduction in the intensity of the 1H matrix ENDOR line upon D2O-H2O exchange indicates that the metal-binding site is accessible to solvent and, therefore, to molecular oxygen as well. The ENDOR data provide the first evidence for a principle iron(II)-binding site with nitrogen coordination in an L-subunit ferritin. The site may be important in Fe2+ oxidation during the beginning stages of core formation.     

Characterization of calcium binding properties of lithostathine

The pancreas secretes primarily two types of metabolically important proteins: digestive enzymes and hormones. Lithostathine (LIT) is the only protein excreted from the pancreas that has no known digestive or hormonal activity. Human lithostathine is a 144-amino acid glycoprotein synthesized by the exocrine pancreas that has been implicated in various physiological functions, including inhibition of pancreatic stone formation. To better understand the physiological function of LIT, we expressed the recombinant LIT protein in Escherichia coli and measured its calcium binding properties by equilibrium dialysis and electron paramagnetic resonance (EPR) spectroscopy. Equilibrium dialysis with (45)Ca(2+) showed that LIT binds Ca(2+) with 1:1 stoichiometry. EPR studies using the divalent vanadyl (VO(2+)) ion as a paramagnetic substitute for Ca(2+) also showed that VO(2+) binds to LIT with a metal:protein binding stoichiometry of 1:1 and that VO(2+) competes with Ca(2+) in binding to LIT. Mutations of a cluster of acidic residues on the molecular surface (E30A, D31A, E33A, D37A, D72A, and D73A) resulted in almost complete loss (95-100%) of binding of Ca(2+) and VO(2+), showing that these residues are critical for calcium binding by LIT.     

Oxo-vanadium as a spin probe for the investigation of the metal coordination environment of imidazole glycerol phosphate dehydratase

Imidazole glycerol phosphate dehydratase (IGPD) catalyses the dehydration of imidazole glycerol phosphate to imidazole acetol phosphate, an important late step in the biosynthesis of histidine. IGPD, isolated as a low molecular weight and inactive apo-form, assembles with specific divalent metal cations to form a catalytically active high molecular weight metalloenzyme. Oxo-vanadium ions also assemble the protein into, apparently, the same high molecular weight form but, uniquely, yield a protein without catalytic activity. The VO2+ derivative of IGPD has been investigated by electron paramagnetic resonance (EPR), electron nuclear double resonance (ENDOR) and electron spin echo envelope modulation (ESEEM) spectroscopy. The spin Hamiltonian parameters indicate the presence of multiple 14N nuclei in the inner coordination sphere of VO2+ which is corroborated by ENDOR and ESEEM spectra showing resonances attributable to interactions with 14N nuclei. The isotropic superhyperfine coupling component of about 7 MHz determined by ENDOR is consistent with a nitrogen of coordinated histidine imidazole(s). The ESEEM Fourier-transform spectra further support the notion that the VO2+ substituted enzyme contains inner-sphere nitrogen ligands. The isotropic and anisotropic 14N superhyperfine coupling components are similar to those reported for other equatorially coordinated enzymatic histidine imidazole systems. ESEEM resonances from axial 14N ligands are discussed.     

Metal ion blockage of tritium incorporation into gamma-carboxyglutamic acid of prothrombin. Stoichiometry of gamma-carboxyglutamic acid to Gd3+ for the high affinity sites

Prothrombin possesses two high affinity and four low affinity gamma-carboxyglutamic acid (Gla)-dependent gadolinium binding sites. Earlier work (Price, P. A., Williamson, M. K., and Epstein, D. J. (1981) J. Biol. Chem. 256, 1172-1176) has shown that tritium can be specifically incorporated at the gamma-carbon of Gla in proteins at pH 5. In the present work we show that inclusion of saturating concentrations of Ca2+ in nondenaturing buffer systems ranging from pH 5.5 to 8.5 prevents the exchange of tritium into all 10 Gla residues of prothrombin. Similarly, saturating concentrations of Gd3+ prevent tritium incorporation into Gla at pH 5.5. Positive cooperativity was observed for the binding of Gd3+ to human prothrombin (at pH 5.5) for the two high affinity sites (Kd congruent to 35 nM). The four low affinity sites bind Gd3+ with a Kd congruent to 5 microM. Incubation of prothrombin ranging in concentrations from 10 to 40 microM with 2 eq of Gd3+ at pH 5.5 prevents 5.7 (average of seven determinations) Gla residues from tritium incorporation. Sedimentation velocity experiments conducted at pH 5.5 indicate that prothrombin in the presence of saturating concentrations of Gd3+ polymerizes, most likely, to a trimer. Further, in the presence of 2 eq of Gd3+, calculated percent weight average concentration of monomer prothrombin is congruent to 100% at 10 microM, approximately equal to 95% at 20 microM, and congruento to 80% at 40 microM protein concentration. Thus, it appears that under conditions in which prothrombin primarily exists as a monomer, occupancy of the initial two metal binding sites by Gd3+ involves six Gla residues.     

Investigation of the binding of Ca2+, Mg2+, Mn2+ and K+ to the vitamin D-dependent Ca2+-binding protein from pig duodenum.

The cation-binding properties of the vitamin D-dependent Ca2+-binding protein from pig duodenum were investigated, mainly by flow dialysis. The protein bound two Ca2+ ions with high affinity, and Mg2+, Mn2+ and K+ were all bound competitively with Ca2+ at both sites. The sites were distinguished by their different affinities for Mn2+, the one with the higher affinity being designated A (Kd 0.61 +/- 0.02 microM) and the other B (Kd 50 +/- 6 microM). Competitive binding studies allied to fluorimetric titration with Mg2+ showed that site A bound Ca2+, Mg2+ and K+ with Kd values of 4.7 +/- 0.8 nM, 94 +/- 18 microM and 1.6 +/- 0.3 mM respectively, and site B bound the same three cations with Kd values of 6.3 +/- 1.8 nM, 127 +/- 38 microM and 2.1 +/- 0.6 mM. For the binding of these cations, therefore, there was no significant difference between the two sites. In the presence of 1 mM-Mg2+ and 150 mM-K+, both sites bound Ca2+ with an apparent Kd of 0.5 microM. The cation-binding properties were discussed relative to those of parvalbumin, troponin C and the vitamin D-dependent Ca2+-binding protein from chick duodenum.     

The differences in microenvironments and functions of tyrosine radicals YZ and YD in photosystem II studied by EPR

Electron paramagnetic resonance (EPR) and electron nuclear double resonance (ENDOR) were performed to investigate the difference in microenvironments and functions between tyrosine Z (Y(Z)) and tyrosine D (Y(D)). Mn-depletion or Ca(2+)-depletion causes extension of the lifetime of tyrosine radical Y(Z)(*), which can be trapped by rapid freezing after illumination at about 250 K. Above pH 6.5, Y(Z)(*) radical in Mn-depleted PS II shows similar EPR and ENDOR spectra similar to that of Y(D)(*) radical, which are ascribed to a typical neutral tyrosine radical. Below pH 6.5, Y(Z)(*) radical shows quite different EPR and ENDOR spectra. ENDOR spectra show the spin density distribution of the low-pH form of Y(Z)(*) that has been quite different from the high-pH form of Y(Z)(*). The spin density distribution of the low-pH Y(Z)(*) can be explained by a cation radical or the neutral radical induced by strong electrostatic interaction. The pH dependence of the activation energy of the recombination rate between Y(Z)(*) and Q(A)(-) shows a gap of 4.4 kJ/mol at pH 6.0-6.5. In the Ca(2+)-depleted PS II, Y(Z)(*) signal was the mixture of the cation-like and normal neutral radicals, and the pH dependence of Y(Z)(*) spectrum in Ca(2+)-depleted PS II is considerably different from the neutral radical found in Mn-depleted PS II. Based on the recent structure data of cyanobacterial PS II, the pH dependence of Y(Z)(*) could be ascribed to the modification of the local structure and hydrogen-bonding network induced by the dissociation of ASP170 near Y(Z).     

Complete amino acid sequence of canine cardiac calsequestrin deduced by cDNA cloning

cDNA cloning was used to deduce the complete amino acid sequence of canine cardiac calsequestrin, the principal Ca2+-binding protein of cardiac junctional sarcoplasmic reticulum. Cardiac calsequestrin contains 391 amino acid residues plus a 19-residue amino-terminal signal sequence. The molecular weight of the mature protein, excluding carbohydrate, is 45,269. Cardiac calsequestrin is highly acidic, and a striking feature is the enrichment of acidic residues (60%) within the 63 carboxyl-terminal residues. No part of the sequence contains EF hand Ca2+-binding structures. The photo-affinity probe 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine was used to localize the Ca2+-regulated hydrophobic site to amino acid residues 192-223. The cardiac and skeletal muscle isoforms of calsequestrin (Fliegel, L., Ohnishi, M., Carpenter, M. R., Khanna, V. K., Reithmeier, R. A. F., and MacLennan, D. H. (1987) Proc. Natl. Acad. Sci. U. S. A. 84, 1167-1171), although the products of different genes, are 65% identical, are acidic, and share one glycosylation site. However, cardiac calsequestrin has several unique features. First, it has a 31-amino acid extension at its carboxyl terminus (residues 361-391), which contains 71% acidic residues and a second glycosylation site. Second, its mRNA contains a second open reading frame with the capacity to code for a 111-amino acid protein. Third, contrary to the restricted expression of the fast skeletal isoform, cardiac calsequestrin mRNA is present in both cardiac and slow skeletal muscle, but not in fast skeletal muscle. We conclude that the deduced amino acid sequence of cardiac calsequestrin is consistent with its ability to bind large amounts of Ca2+ (40 mol of Ca2+/mol of calsequestrin). The protein probably binds Ca2+ by acting as a charged surface rather than by presenting multiple discrete Ca2+-binding sites.     

Presence of secretogranin II and high-capacity, low-affinity Ca2+ storage role in nucleoplasmic Ca2+ store vesicles

Chromogranins and secretogranins have traditionally been known as marker proteins of secretory granules that contain the highest concentrations of cellular calcium, reaching approximately 40 mM. In addition, chromogranin B was also shown to exist in the nucleus, localizing in the putative inositol 1,4,5-trisphosphate (IP3)-sensitive nucleoplasmic Ca2+ store vesicles. Chromogranins A (CGA) and B (CGB) are high-capacity, low-affinity Ca2+ binding proteins, binding 30-90 mol of Ca2+/mol with dissociation constants (Kd) of 1.5-4 mM. Yet the Ca2+-binding property of secretogranins has not been studied. Here, we show the localization of secretogranin II (SgII) in the nucleus, more specifically, in the IP3-sensitive nucleoplasmic Ca2+ store vesicles along with CGB and the IP3 receptors. We have also determined the Ca2+-binding property of SgII and found that SgII binds 61 mol of Ca2+/mol (910 nmol Ca2+/mg) with a Kd of 3.0 mM at the intragranular pH 5.5 and 30 mol of Ca2+/mol (440 nmol Ca2+/mg) with a Kd of 2.2 mM at a near-physiological pH 7.5. Chromogranin B also bound 50 mol of Ca2+/mol (670 nmol Ca2+/mg) with a Kd of 3.1 mM at pH 7.5. Given the high-capacity, low-affinity Ca2+-binding property of SgII and its presence in the IP3-sensitive nucleoplasmic Ca2+ store vesicles, these results suggest that SgII may function in the storage and control of Ca2+ in the nucleus through its interaction with CGB in the nucleoplasmic vesicles.     

Fibrinogen sialic acid residues are low affinity calcium-binding sites that influence fibrin assembly

Calcium ions occupy low (n congruent to 10; Kd congruent to 1 mM) and high (n = 3; Kd congruent to 1 microM) affinity sites on fibrinogen and facilitate fibrin monomer polymerization. We have previously localized two of the three high affinity Ca2+ sites to gamma 311-gamma 336. However, optimal enhancement of fibrin monomer polymerization occurs only at physiological millimolar Ca2+ concentrations which are two orders of magnitude higher than the concentration required for occupancy of the high affinity Ca2+-binding sites. In this study, we show that removal of fibrinogen sialic acid residues results in loss of low affinity Ca2+-binding sites. Clotting of asialofibrinogen appears to be Ca2+-independent and results in fiber bundles thicker in diameter than normal fibrin bundles as determined by turbidometry and scanning and transmission electron microscopy. By using a Ca2+-sensitive electrode, free sialic acid is shown to bind Ca2+ (Kd congruent to 1 mM). These observations suggest that the high affinity fibrinogen D-domain Ca2+-binding sites may play a role in the tertiary structure of the D-domain, whereas, sialic acid residues are low affinity sites whose occupancy by Ca2+ at physiological calcium concentration facilitates fibrin polymerization.     

Different metal-binding properties of the two sites of human transferrin.

Transferrin, the serum serum iron-transport protein which can bind two metal ions at physiologic pH, binds just one Fe3+, VO2+, or Cr3+ ion at pH 6.0. Fe3+ and VO2+ appear to be bound at the same site, designated A, based on electron paramagnetic resonance (EPR) spectra of VO2+-transferrin and (Fe3+)1(VO2+)1-transferrin. The EPR spectra of (Cr3+)1(VO2+)1-transferrin and of (Cr3+), (FE3+)1-transferrin indicate that that Cr3+ is bound to site B at pH 6.0. Transferrin was labeled at site A with 59Fe at pH 6.0 and at site B with 55Fe at pH 7.5. When the pH of the resulting preparation was lowered to 6.3 and the dissociated iron was separated by gel filtration, about ten times as much 55Fe as 59Fe was lost. The same EPR and isotopic-labeling experiments showed that Fe3+ added to transferrin at pH 7.5 binds to site A with about 90% selectivity.     

Proteolytic formation and properties of a fragment of protein C containing the gamma-carboxyglutamic acid rich domain and the EGF-like region

The function of the epidermal growth factor (EGF) like domains in the vitamin K dependent plasma proteins is largely unknown. In order to elucidate the function of these domains in protein C, we have devised a method to isolate the EGF-like region from the light chain connected to the NH2-terminal region, containing the gamma-carboxyglutamic acid (Gla) residues. This was accomplished by tryptic cleavage of protein C that had been reversibly modified with citraconic anhydride to prevent cleavage at the lysine residue (in position 43) that is located between the two regions. The isolated fragment consists of residues 1-143 from the light chain of protein C connected by a disulfide bond to residues 108-131 from the heavy chain. Upon Ca2+ binding to the isolated Gla-EGF fragment from bovine protein C, the tryptophan fluorescence emission was quenched in a manner indicating binding to at least two classes of binding sites. These were presumably the Gla-independent Ca2(+)-binding site located in the EGF-like region and the lower affinity sites in the Gla region. A comparison with the tryptophan fluorescence quenching that occurred upon Ca2+ binding to the separately isolated EGF-like and Gla regions suggested that the EGF-like region influenced the structure and Ca2+ binding of the Gla region. The isolated Gla-EGF fragment functioned as an inhibitor of the anticoagulant effect of activated protein C in a clotting assay, whereas no inhibition was observed with either the Gla region or the EGF-like region.     

The high affinity calcium-binding site involved in protein C activation is outside the first epidermal growth factor homology domain.

Binding Ca2+ to a high affinity site in protein C and 4-carboxyglutamic acid (Gla)-domainless protein C results in a conformational change that is required for activation by the thrombin-thrombomodulin complex, the natural activator of protein C. It has been hypothesized that this high affinity Ca(2+)-binding site is located in the NH2-terminal epidermal growth factor (EGF) homology region of protein C. We have expressed in human 293 cells a deletion mutant of protein C (E2-PD) which lacks the entire Gla region as well as the NH2-terminal EGF homology region of protein C. Ca2+ inhibits activation of E2-PD or Gla-domainless protein C by thrombin with half-maximal inhibition occurring at Ca2+ concentrations of 103 +/- 11 and 70 +/- 7 microM, respectively, but is required for both E2-PD and Gla-domainless protein C activation by the thrombin-thrombomodulin complex with half-maximal acceleration occurring at Ca2+ concentrations of 87 +/- 8 and 89 +/- 8 microM, respectively. Both E2-PD and Gla-domainless protein C exhibit a reversible, Ca(2+)- but not Mg(2+)-dependent decrease (6 +/- 1%) in fluorescence emission intensity with Kd = 38 +/- 3 microM Ca2+. We conclude that the high affinity Ca(2+)-binding site important for the activation of protein C is located outside of the NH2-terminal EGF homology region and that the metal-binding site in the NH2-terminal EGF homology region may not be a high affinity site in intact protein C.     

Structural basis for VO<Superscript>2+</Superscript> inhibition of nitrogenase activity (A): <Superscript>31</Superscript>P and <Superscript>23</Superscript>Na interactions with the metal at the nucleotide binding site of the nitrogenase Fe protein identified by ENDOR spectroscopy

We previously reported the vanadyl hyperfine couplings of VO(2+)-ATP and VO(2+)-ADP complexes in the presence of the nitrogenase Fe protein from Klebsiella pneumoniae (Petersen et al. in Biochemistry 41:13253-13263, 2002). It was demonstrated that different VO(2+)-nucleotide coordination environments coexist and are distinguishable by electron paramagnetic resonance (EPR) spectroscopy. Here orientation-selective continuous-wave electron-nuclear double resonance (ENDOR) spectra have been investigated especially in the low-radio-frequency range in order to identify superhyperfine interactions with nuclei other than protons. Some of these resonances have been attributed to the presence of a strong interaction with a 31P nucleus although no resolvable superhyperfine structure due to 31P or other nuclei was detected in the EPR spectra. The superhyperfine coupling component is determined to be about 25 MHz. Such a 31P coupling is consistent with an interaction of the metal with phosphorus from a directly, equatorially coordinated nucleotide phosphate group(s). Additionally, novel more prominent 31P ENDOR signals are detected in the low-frequency region. Some of these correspond to a relatively weak 31P coupling. This coupling is present with ATP for all pH forms but is absent with ADP. The ENDOR resonances of these weakly coupled 31P are likely to originate from an interaction of the metal with a nucleotide phosphate group of the nucleoside triphosphate and are attributed to a phosphorus with axial characteristics. Another set of resonances, split about the nuclear Zeeman frequency of 23Na, was detected, suggesting that a monovalent Na+ ion is closely associated with the divalent metal-nucleotide binding site. Na+ replacement by K+ unambiguously confirmed that ENDORs at radio frequencies between 3.0 and 4.5 MHz arise from an interaction with Na+ ions. In contrast to the low-frequency 31P signal, these resonances are present in spectra with both ADP and ATP, and for both low- and neutral-pH forms, although slight differences are detected, showing that these are sensitive to the nucleotide and pH.