Vitamin K-dependent Plasma Protein Research Articles

The inhibition of human factor VIIa-tissue factor by antithrombin III-heparin is enhanced by factor X on a human bladder carcinoma cell line.

Previous studies have shown that antithrombin III-heparin effectively inhibited the factor VIIa-tissue factor complex. Herein, we show that the neutralization of factor VIIa in complex with the cell surface tissue factor by antithrombin III-heparin was markedly enhanced by plasma levels of factor X. Active site-mutated factor X (S376A factor X) and factor Xa previously inactivated with dansyl-Glu-Gly-Arg-chloromethyl ketone were as effective as plasma-derived factor X in this reaction, indicating that the active site serine residue of factor Xa was not involved in this mechanism. Furthermore, Gla-domainless factor X had no effect in this system, emphasizing the importance of the factor X Gladomain in this reaction. Antibody experiments revealed that this effect was not due to trace levels of a tissue factor pathway inhibitor contaminating either the factor X or antithrombin III preparations. The presence of heparin in this system was essential, as deletion of heparin resulted in a factor VIIa-tissue factor neutralization rate essentially identical to that observed for antithrombin III alone. Plasma levels of factor IX also accelerated the inhibition of factor VIIa-tissue factor by antithrombin III-heparin, although its effect was not as pronounced as that of factor X. Other vitamin K-dependent plasma proteins including protein S, protein C and prothrombin failed to augment the inhibition of factor VIIa-tissue factor by antithrombin III-heparin. Factor X did not enhance the neutralization rate of factor VIIa-tissue factor by antithrombin III-heparin when a carboxyl-terminal truncated tissue factor construct (TF1-219) was used, even in the presence of mixed phospholipids. Our collective finding suggest that antithrombin III and factor X bind to heparin at distinct sites on the heparin molecule resulting in a transient ternary complex of antithrombin III-heparin-factor X that represents the anticoagulant species. Factor X conceivably guides complex to a phosphatidylserine-rich site on the cell surface in close proximity to the factor VIIa-tissue factor complex and facilitates rapid neutralization of factor VIIa. Our findings also suggest that the effect of heparin on the regulation of the extrinsic pathway of blood coagulation may be more profound than previously recognized.

Protein Z deficiency: A new cause of bleeding tendency

Protein Z is a vitamin K-dependent plasma protein synthesized by the liver. Protein Z promotes the association of thrombin with phospholipid surfaces. So far, nothing is known about the clinical relevance of protein Z except alterations measured in patients under oral anticoagulant treatment. We propose that in protein Z deficiency a bleeding tendency might result because of the interaction of protein Z with thrombin on phospholipid endothelial surfaces. Therefore, we examined 36 patients with bleeding tendency of unknown origin, who were not under oral anticoagulant treatment and had normal liver synthesis function. Mean protein Z value of the patients with bleeding tendency was significantly diminished in comparison to the healthy control group. Twenty-one of the bleeding patients had lower protein Z levels than the lowest protein Z level of the control group. In conclusion, protein Z deficiency is described as a new type of bleeding tendency.

Protein Z, a new haemostatic factor, in liver diseases.

Protein Z is a vitamin K-dependent plasma protein, which promotes the association of thrombin with phospholipid surfaces. Deficiency states of protein Z have recently been shown in patients with a bleeding tendency of an otherwise unknown origin. In the present study severe diminutions of blood plasma protein Z were found in patients with chronic liver diseases. Protein Z levels decreased with increasing severity of liver disease. Strong correlations between protein Z and other plasma proteins of liver origin indicate that protein Z primarily originates from the liver. The cutaneous bleeding tendency in cirrhosis may in part be due to protein Z deficiency.

One-step sandwich enzyme immunoassays for human C4b-binding protein (C4BP) and protein S-C4BP complex using monoclonal antibodies

C4b-binding protein (C4BP), a regulatory component in the complement system, binds to an anticoagulant vitamin K-dependent plasma protein S (PS) which acts as a cofactor of activated protein C. We raised monoclonal antibodies against C4BP and PS, and developed two different one-step sandwich enzyme immunoassay (EIA) systems for human total C4BP (assay A) and PS-C4BP complex (assay B) by using a solid phase monoclonal antibody and a horseradish peroxidase-labeled monoclonal antibody (Fab′). The reaction time of the assay was 45 min in both EIA systems: 30 min for the immunoreaction and 15 min for the color reaction. The sensitivities were 12 and 20 mg/l in assays A and B, respectively. Linearity was obtained between 31 and 500 mg/l in both EIA systems. Assay A could detect both uncomplexed C4BP and PS-C4BP complex with equal efficiency so that totatl C4BP level was not affected by PS. The levels of total C4BP and PS-C4BP complex were found to significantly increase in sera from patients with membranous nephropathy and decrease with liver cirrhosis in comparison with the levels in normal subjects. On the other hand, a difference in the total C4BP and PS-C4BP complex levels was not shown between IgA nephropathy and normal subjects. Affinity column analysis and difference of total C4BP and PS-C4BP complex levels showed that most of C4BP in sera exists as PS-C4BP complex.

Inefficient processing of human protein C in the mouse mammary gland

Vitamin K-dependent plasma protein, human Protein C (HPC) has been expressed in transgenic mice, using a 4.2 kb mouse whey acidic protein (WAP) promoter, 9.0 kb HPC gene and 0.4 kb 3' flanking sequences. Expression was mammary gland-specific and the recombinant human Protein C (rHPC) was detected in milk at concentrations of 0.1 to 0.7 mg ml-1. SDS-PAGE revealed that the single, heavy and light chains of rHPC migrated with increased electrophoretic mobility, as compared to HPC. Enzymatic deglycosylation showed that these molecular weight disparities are in part due to differential glycosylation. The substantial increase observed in the amount of single chain protein, as well as the presence of the propeptide attached to 20-30% of rHPC, suggest that mouse mammary epithelial cells are not capable of efficient proteolytic processing of rHPC. The Km of purified rHPC for the S-2366 synthetic substrate was similar to that of plasma-derived HPC, while the specific activity was about 42-77%. Amino acid sequence analyses and low anticoagulant activity of purified rHPC suggest that gamma-carboxylation of rHPC is insufficient. These results show that proteolytic processing and gamma-carboxylation can be limiting events in the overexpression of fully biologically active rHPC in the mouse mammary gland.

Blood Coagulation Factor Xa Interacts with a Linear Sequence of the Kringle 2 Domain of Prothrombin

Prothrombin is a vitamin K-dependent plasma protein composed of several functional domains, which is proteolytically activated into thrombin by factor Xa in the presence of factor Va, Ca2+, and phospholipids. During the activation, prothrombin is cleaved into three fragments: fragment 1, containing a domain rich in gamma-carboxyglutamic acid residues and kringle 1 domain; fragment 2, containing the kringle 2 domain; and a protease catalytic domain, thrombin. Here we studied the interaction site for factor Xa in human prothrombin during the activation. The isolated fragment 2 inhibited the activation of prothrombin by either prothrombinase complex or factor Xa alone in a dose-dependent manner, whereas fragment 1 and diisopropylphosphate (DIP)-thrombin did not. Factor Xa directly bound to fragment 2 immobilized to microwell plates with a Kd of 9.0 x 10(-8) M, but not to fragment 1 or DIP-thrombin. Factor Xa also bound to immobilized prothrombin and prethrombin 1 with Kds of 2.0 x 10(-7) and 1.5 x 10(-7) M, respectively, suggesting that factor Xa interacts with the kringle 2 domain in these molecules. The binding of factor Xa to immobilized fragment 2 was Ca(2+)-dependent with an optimal concentration at 6 mM. In the presence of Ca2+, the interaction was enhanced by phospholipids in a concentration-dependent manner. To localize the factor Xa-binding site in the kringle 2 domain, fragment 2 was digested with lysyl endopeptidase and then trypsin after reduction and S-carboxymethylation. The resulting peptides were immobilized to microwell plates and assayed for factor Xa binding ability. The amino acid sequence of the peptide positive in the assay was determined to be residues His205 to Arg220. Factor Xa bound to a synthetic peptide corresponding to the residues His205 to Arg220 immobilized to microwell plates. The peptide inhibited factor Xa-catalyzed activation of prothrombin, but a peptide with the reversed sequence of His205 to Arg220 did not. These findings indicate that factor Xa interacts with at least a linear sequence, His205 to Arg220, in the kringle 2 domain of prothrombin during its activation into thrombin.

Protein engineering of the hydrophobic domain of human factor IX.

Vitamin K-dependent plasma proteins contain a highly conserved hydrophobic domain located between the gamma-carboxyglutamic acid (Gla) domain and the first epidermal growth factor (EGF)-like domain. Here we have used protein engineering of the hydrophobic domain in human factor IX to investigate its function in intact factor IX. Mutant proteins were generated by site-directed mutagenesis and in vitro expression in Madin-Darby canine kidney (MDCK) cells. All of our mutants, including one with a deletion of the entire hydrophobic domain, were activated by factor XIa, showing that this domain is not required for factor IX activation. The results with the mutant Phe41-->Val suggest that the hydrophobic domain interacts with the adjacent EGF-like domain. Our data for the Phe41-->Asp mutant is consistent with, but cannot prove, a role for this residue in the maintenance of a phospholipid-binding structure required for factor IX function.

Rabbit Plasma, unlike Its Human Counterpart, Contains no Complex between Protein S and C4b-Binding Protein

In human plasma, the anticoagulant vitamin K-dependent protein S exists in two molecular forms, as free protein and complexed to C4b-binding protein (C4BP), a complement regulatory protein. It has been suggested that rabbit plasma also contains two forms of protein S and that the interaction between protein S and C4BP in rabbits can be modulated by synthetic peptides corresponding to a sequence (residues 605-614) in the carboxy-terminal part of protein S. In this report, we provide results which challenge the conclusion that rabbit plasma contains the complexed form of protein S. The two forms of protein S in human plasma were separated by gel filtration chromatography on Sephacryl S-300 and the presence of protein S in the various fractions analyzed by Western blotting using a monoclonal antibody (HPS 21) directed against the gamma-carboxyglutamic acid rich module of human protein S. This antibody, which was found to cross-react with rabbit protein S on Western blotting, was used in affinity purification of protein S from rabbit plasma as well as of recombinant rabbit protein S. HPS 21 specifically recognized protein S in rabbit plasma and did not cross-react with the other vitamin K-dependent plasma proteins. To elucidate whether rabbit plasma contained two forms of protein S, rabbit plasma was subjected to gel-filtration chromatography followed by Western blotting of the fractions with monoclonal antibody HPS 21. Protein S was found only in fractions eluting at a position corresponding to that of free protein S.(ABSTRACT TRUNCATED AT 250 WORDS)

Construction and Characterization of Thrombin-resistant Variants of Recombinant Human Protein S

Protein S is a vitamin K-dependent plasma protein that functions as a cofactor of activated protein C (APC) in the inactivation of coagulation factors Va and VIIIa. Protein S, migrates as a doublet on reduced SDS polyacrylamide gel electrophoresis. This heterogeneity in molecular weight has been explained by limited proteolysis of protein S. Human protein S contains at Arg-49, Arg-60 and Arg-70 three potential cleavage sites. Whether cleavage occurs at all three sites is not known. To study the role of these arginine residues in human protein S, we have replaced them by leucine or isoleucine. All seven possible variants were constructed: three variants with single mutations (R49L, R60L, R70I), three variants with double mutations (R49L/R60L, R60L/R70I, R49L/R70I) and one variant with a triple mutation (R49L/R60L/R70I). On reduced SDS polyacrylamide gels the single and double variants migrate as a doublet just like the wild type protein S. The triple variant migrates as a single band at a molecular weight corresponding to the upper band of the doublet. The upper band of the single and double variants but not of the triple variant could be converted into the lower band by thrombin treatment. All variants showed cofactor activity to APC in a clotting assay. After thrombin treatment, this cofactor activity was abolished for the single (R49L, R60L, R70I) and double variants (R49L/R60L, R60L/R70I, R49L/R70I), while the triple variant (R49L/R60L/R70I) tested at several concentrations, retained its cofactor activity completely, suggesting resistance to thrombin. This shows that thrombin can cleave at all three arginine sites and that cleavage at each of these sites results in the loss of APC cofactor activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Homozygous Type I Protein C Deficiency in Two Unrelated Families Exhibiting Thrombophilia Related to Ala136→Pro or Arg286→His Mutations

Separate single nucleotide mutations have been identified in two unrelated homozygous type I protein C deficient individuals suffering from thrombophilia. Each mutation, initially established by direct DNA sequencing of polymerase chain reaction amplification products, results in an amino acid substitution. The first mutation (PCClamart) results in an Ala136 to Pro substitution in the protein's second epidermal growth factor-like domain. The second mutation (PCMünchen) results in an Arg286 to His substitution in the serine protease domain. Comparison of the location of these two mutations and the relative conservation of the two regions in homologous vitamin K-dependent plasma proteins is consistent with the difference in severity of protein C deficiency and disease in the two individuals. Both mutations result in the abolition of a naturally occurring restriction endonuclease site, thereby allowing independent confirmation of the mutations and rapid and unambiguous genetic analysis of protein C deficiency in family members. In both families, the genetic analysis has proven useful in cases where an assignment of the protein C status based upon clinical laboratory measurements was either ambiguous or incorrect.

Autoimmune Protein S Deficiency in a Boy with Severe Thromboembolic Disease

Protein S is a vitamin K-dependent plasma protein involved in the regulation of the protein C anticoagulant pathway,1 the system responsible for the inactivation of factors Va and VIIIa2. Protein S functions as a cofactor for activated protein C by increasing its affinity for the cell surface3 and by blocking the capacity of factor Xa to protect factor Va from inactivation by activated protein C4; it also enhances the profibrinolytic effects of activated protein C5–7. The congenital deficiency of protein S is associated with an increased risk of recurrent juvenile venous and arterial thromboembolism8–10. . . .

Treatment of Coumarin-Induced Skin Necrosis With a Monoclonal Antibody Purified Protein C Concentrate

BACKGROUND AND DESIGN--Protein C is a vitamin K-dependent plasma protein that is converted to the serine protease activated protein C by the thrombin-thrombomodulin complex. Activated protein C functions as a natural anticoagulant by inactivating the cofactors of the coagulation cascade, factors Va and VIIIa. Coumarin (warfarin)-induced skin necrosis is thought to be due to a rapid elimination of protein C relative to other vitamin K-dependent factors during the initial phase of oral anticoagulation. We have used a highly purified protein C concentrate to treat a patient with acquired protein C deficiency who developed skin necrosis during the initial phase of oral anticoagulant therapy. OBSERVATIONS AND CONCLUSIONS--During protein C concentrate therapy, no further skin lesions appeared, and the healing process of necrotic areas was facilitated. Replacement therapy with protein C concentrate appears to be safe and effective as an adjunctive treatment for coumarin-induced skin necrosis.

Prothrombin Synthesis in Rat Hepatoma H4IIEC3 Cells: Response to the Proposed “Coagulopoietin Factor”

Based on studies in intact animals, the presence of humoral factors, "coagulopoietins", which regulate the synthesis of vitamin K-dependent plasma proteins has been proposed. These proposed factors are produced in response to vitamin K deficiency, coumarin treatment, or specific antibody depletion of vitamin K-dependent clotting factors. The production of prothrombin by rat hepatoma H4IIEC3 cells has now been shown to be dependent on the source of bovine serum in the media. Cells grown in serum from cows treated with dicoumarol produce about 20% more prothrombin in 24 h than those cells grown in control serum. The humoral factor causing this response is present early in the course of dicoumarol treatment, and the increase in prothrombin production is dependent on the amount of serum from a dicoumarol-treated cow in the media. Based on membrane filtration studies, the factor appears to be associated with the protein fraction of serum.

Comparison of the Ca 2+ binding properties of the γ-carboxyglutamic acid-containing module of protein Z in the intact protein and in N-terminal fragments

Protein Z is a vitamin K-dependent plasma protein of unknown function. Its modular structure is identical with those of factors VII, IX, X, and protein C. These proteins have an N-terminal γ-carboxyglutamic acid (Gla)-containing module which binds six to ten Ca 2+. In factors IX, X, and protein C, the adjacent epidermal growth factor (EGF)-like module binds one Ca 2+ whereas the EGF-like module in protein Z does not. We have compared the Ca 2+ binding properties of a fragment of protein Z comprising the Gla and N-terminal EGF-like modules (pZ-GlaEGF N) with those of intact protein Z and the isolated Gla module by measuring the Ca 2+-induced quenching of the intrinsic protein fluorescence. The similar Ca 2+ affinities of pZ-GlaEGF N and protein Z indicate that pZ-GlaEGF N has a native conformation and normal Ca 2+ binding properties. A comparison of the Ca 2+ binding to pZ-GlaEGF N with those to the corresponding fragments of factors IX, X, and protein C indicate that Ca 2+ binding to the N-terminal EGF-like modules in the latter proteins does not influence the folding and Ca 2+ binding properties of their Gla modules. Furthermore, the Ca 2+-induced fluorescence enhancements of GlaEGF fragments from factors IX, X, and protein C appear to be caused by Ca 2+ binding to the site in the EGF-like modules since it is not observed for pZ-GlaEGF N.

Purification of rabbit, rat and mouse protein C with the use of monoclonal antibody to human protein C, PC01

Ca ++-dependent monoclonal antibody specific to γ-carboxyglutamic acid (Gla) domain of protein C was produced. It did not cross-react to the other vitamin K-dependent plasma proteins but to protein C of the other species. Using this monoclonal antibody, PC01, rabbit (170μg), rat (60μg) and mouse (40μg) protein Cs were isolated from 100 ml of their plasma by affinity chromatography. All of these protein Cs were two chain form linked by disulfide bond as well as human protein C and activated by thrombin-thrombomodulin complex. Rat and mouse protein Cs showed similar characters to human protein C. On the other hand rabbit protein C had different M r of heavy and light chains and showed lower anticoagulant activity compared with human protein C.

Beta-Hydroxyaspartic acid and beta-hydroxyasparagine residues in recombinant human protein S are not required for anticoagulant cofactor activity or for binding to C4b-binding protein.

Among the vitamin K-dependent plasma proteins, only protein S contains the post-translationally modified amino acid erythro-beta-hydroxyasparagine (Hyn). Protein S also contains erythro-beta-hydroxyaspartic acid (Hya). The function of these unusual amino acids, located in the epidermal growth factor-like domains, is unknown. To determine if these post-translational modifications contribute to the functional integrity of human protein S (HPS), recombinant human protein S lacking Hya and Hyn (rHPSdesHya/Hyn) was purified from the medium of human kidney 293 cells that were transfected with HPS cDNA and grown in the presence of the hydroxylase inhibitor 2,2'-dipyridyl. Solution-phase equilibrium binding studies revealed that rHPSdesHya/Hyn binds C4b-binding protein (C4BP) in a manner indistinguishable from recombinant HPS and plasma-derived HPS, exhibiting a Kd in the presence of 2 mM CaCl2 of approximately 0.7 nM and a Kd in the presence of 4 mM EDTA approximately 10-fold higher. In a purified component system, rHPSdesHya/Hyn displayed normal anticoagulant cofactor activity in the activated protein C-catalyzed inactivation of coagulation factor Va bound in the prothrombinase complex. In addition, digestion of rHPSdesHya/Hyn with thrombin in the presence of EDTA appeared normal, and 2 mM CaCl2 prevented the cleavage. Together these results suggest that the post-translational modifications of Asn and Asp residues are not necessary for the macromolecular or Ca2+ interactions associated with the anticoagulant and C4BP binding characteristics of HPS.

Factor XSanto Domingo. Evidence that the severe clinical phenotype arises from a mutation blocking secretion.

Factor X (FX) is a vitamin K-dependent plasma protein required for the intrinsic and extrinsic pathways of blood coagulation. FXSanto Domingo is a hereditary FX deficiency which is characterized clinically by a severe bleeding diathesis. The proposita has a FX activity of less than 1% and a FX antigen of less than 5%. We have determined the molecular basis of the defect in the FXSanto Domingo gene by amplification of all eight exons with polymerase chain reaction and subsequent sequence analysis. The patient is homozygous for a G----A transition in exon I at codon -20 (numbering the alanine at the NH2 terminus of the mature protein as +1), resulting in the substitution of arginine for glycine in the carboxy-terminal part of the signal peptide. This amino acid change occurs near the presumed cleavage site of the signal peptidase. We hypothesized that the mutation might prevent cleavage by the signal peptidase which in turn would impair proper secretion of the FX protein. To test this hypothesis, we compared the expression of wild type and mutant FX cDNA in a human kidney cell line. Wild type and mutant constructs in the expression vector pCMV4 were introduced into the human embryonic kidney cell line 293 by calcium phosphate transfection. FX antigen levels in the supernatant of the cells harboring the wild type construct were 2.4 micrograms/10(7) cells per 24 h, whereas antigen levels in media from cells containing the FXSanto Domingo construct were undetectable. No FX antigen was detected in the cell lysates of cells transfected with the mutant construct. To insure that the difference in protein levels was not due to a difference in steady state levels of mRNA, Northern analysis was performed on RNA from the cell lysates of both constructs. The results showed a transcript of the same size, present in roughly equal amounts, in both cases. Thus, the defect in the signal sequence of FXSanto Domingo exerts its effect posttranscriptionally. FXSanto Domingo is the first described example of a bleeding diathesis due to a mutation in the signal sequence.

γ-Carboxylated Isoforms of Recombinant Human Protein S With Different Biologic Properties

Human protein S (HPS), a regulator of hemostasis, is a vitamin K-dependent plasma protein with potential clinical utility. We have obtained high-level expression of the cDNA for HPS in two mammalian cell lines. Both cell lines secreted single chain recombinant HPS (rHPS) in serum-free medium as determined by Western blot analysis. The ability of the rHPS from both cell lines to act as a cofactor for human protein C (HPC) was determined; the rHPS secreted from the human 293 cell line had an activity six times that of the rHPS from the AV12-664 Syrian hamster cell line. Furthermore, the relative specific cofactor activity of rHPS from the 293 cell line was actually 2.5-fold higher than that of single-chain human plasma-derived HPS. Essentially all of the rHPS secreted from the 293 cell line exhibited a calcium-dependent elution profile on anion exchange chromatography, whereas only 25% to 35% of the hamster cell-derived rHPS exhibited this profile. However, the calcium-eluted rHPS from the AV12 cell line had a high specific cofactor activity, equivalent to that of the 293-derived rHPS. A NaCl-elutable rHPS fraction (calcium nondependent) was isolated from the recombinant AV12-664 cell line, further purified, and found to have reduced activity, only 40% that of the calcium-dependent rHPS. The only observable difference in the calcium-dependent and nondependent rHPS molecules was in the content of gamma-carboxyglutamic acid (Gla); the calcium-dependent material contained approximately 10 mol Gla/mol protein whereas the calcium-nondependent material contained only approximately 8 mol Gla/mol of protein. In addition, the calcium-nondependent rHPS had reduced ability to interact with phospholipid vesicles as evidenced by an eightfold increase in the apparent kd. Our data demonstrate the isolation of rHPS with high specific activity, and show that a reduction in as few as two Gla residues dramatically decreases its functional cofactor activity for HPC, due to a reduction in ability to interact with the phospholipid bilayer.

Protein S Deficiency Associated With Central Retinal Artery Occlusion

Protein S and protein C are vitamin K-dependent plasma proteins that modulate coagulation. Protein C deficiency has been reported in association with amaurosis fugax, 1 and it has been suggested that there may be an association of protein C activity with branch retinal vein occlusion. 2 We have recently cared for a patient with protein S deficiency and a central retinal artery occlusion. Report of a Case. —A 30-year-old man developed transient episodes of vision loss in the left eye, each lasting about 3 minutes. Visual acuity was 20/100 OS. The anterior segment was normal, and the intraocular pressure was 15 mm Hg. The disc was normal. There was narrowing of the retinal arterioles and mild dilatation of the retinal veins. No retinal emboli were present. He was being treated with sodium warfarin (Coumadin), and the prothrombin time was 15.7 seconds, with a reference range of 9.8 to 11.4 seconds.

The first EGF-like domain from human factor IX contains a high-affinity calcium binding site.

It has been suggested that epidermal growth factor-like (EGF-like) domains, containing conserved carboxylate residues, are responsible for the high-affinity calcium binding exhibited by a number of vitamin K-dependent plasma proteins involved in the control of the blood coagulation cascade. These include the procoagulant factors IX and X, and the anticoagulants protein C and protein S. To test this hypothesis we have expressed the first EGF-like domain from human factor IX (residues 46-84) using a yeast secretion system, and examined calcium binding to the domain. Using 1H-NMR to measure a calcium-dependent shift assigned to Tyr69 we have detected a high-affinity calcium binding site (Kd = 200-300 microM). We suggest that other EGF-like domains of this type may have similar calcium binding properties. In addition, we have completely assigned the aromatic region of the NMR spectrum by NOESY and COSY analysis, and have used these data to discuss the effect of calcium and pH on the conformation of the domain with reference to a model based on the structure of human EGF.