Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.4.21.69 (APC)
 16,337 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Structure-function relationships in the 6 epidermal growth factor-like domains of human thrombomodulin (TME, residues 227-462) were studied by deletion mutagenesis. Purified and characterised proteins were used for kinetic studies. Deletion of EGF1, EGF2 and residues 310-332 in EGF3 had no effect on thrombin binding (Kd) or on kcat/KM for protein C activation by the thrombin-thrombomodulin complex. Deletion of the rest of EGF3 and the interdomain loop between EGF3 and EGF4 had no effect on Kd but decreased kcat/KM to 10% of TME. Deletion of residues 447-462 of EGF6 had no effect on kcat/KM but increased Kd for thrombin approximately 6-fold. Thus, the region 333-350 in EGF3-4 is critical for protein C activation by the thrombin-thrombomodulin complex and the region 447-462 in EGF6 is critical for thrombin binding.
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PMID:Structure-function studies of the epidermal growth factor domains of human thrombomodulin. 131 40

To elucidate the binding sites for thrombin and protein C in the six epidermal growth factor (EGF) domains of human thrombomodulin, recombinant mutant proteins were expressed in COS-1 cells. Mutant protein EGF456, which contains the fourth, fifth, and sixth EGF domains from the NH2 terminus of thrombomodulin, showed complete cofactor activity in thrombin-catalyzed protein C activation, as did intact thrombomodulin or elastase-digested thrombomodulin. EGF56, containing the fifth and sixth EGF domains, did not have cofactor activity; but EGF45, containing the fourth and fifth EGF domains, had about one-tenth of the cofactor activity of EGF456. Thrombin binding to attached recombinant thrombomodulin (D123) was inhibited by EGF45 as well as by EGF56. A synthetic peptide (ECPEGYILDDGFICTDIDE), corresponding to Glu-408 to Glu-426 in the fifth EGF domain, inhibited thrombin binding to attached thrombomodulin (D123) with an apparent Ki of 95 microM. At Ca2+ concentrations of 0.25-0.3 mM, intact protein C was maximally activated by thrombin in the presence of EGF45, EGF456, or EGF1-6, which contains the first to sixth EGF domains; but such maximum cofactor activity was not observed when gamma-carboxyglutamic acid-domainless protein C was used. These findings suggest that: 1) thrombin binds to the latter half of the fifth EGF domain; and 2) protein C binds to the fourth EGF domain of thrombomodulin through Ca2+ ions.
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PMID:Further localization of binding sites for thrombin and protein C in human thrombomodulin. 217 98

Vitamin-K-dependent protein S is an anticoagulant plasma protein functioning as a cofactor to activated protein C (APC) in the degradation of factors Va and VIIIa. The APC-cofactor function of protein S is species specific, as human protein S potentiates the anticoagulant activity of human but not that of bovine APC, whereas bovine protein S is a cofactor to APC from both species. To elucidate which modules in protein S determine the species specificity, in vitro mutagenesis was used to construct six recombinant chimeric molecules between human and bovine protein S. Wild-type human and bovine protein S and the chimeras were expressed in 293 cells and the recombinant proteins purified by monoclonal antibody affinity chromatography. The recombinant proteins were found to be post-translationally modified, they bound C4b-binding protein and were functionally active as cofactors to APC. Chimeras having both the thrombin-sensitive region (TSR) and the first epidermal-growth-factor-(EGF)-like module of bovine origin expressed APC-cofactor activity similar to that of bovine protein S. Those chimeras, in which TSR or EGF1 derived from different species, manifested APC-cofactor activity similar to that of human protein S, i.e. they did not express cofactor activity to bovine APC. These data indicate that sequence differences in the TSR and EGF1 of human and bovine protein S cause the species specificity of the APC-cofactor activity. The data support the concept that these two modules of protein S interact with APC on the surface of negatively charged phospholipids.
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PMID:Expression and functional characterization of chimeras between human and bovine vitamin-K-dependent protein-S-defining modules important for the species specificity of the activated protein C cofactor activity. 785 19

Factor IX consists of a gamma-carboxyglutamic acid-rich domain followed by two epidermal growth factor (EGF)-like domains and the C-terminal protease domain. To delineate the function of EGF1 domain in factor IX, we constructed three mutants: an EGF1 domain-deleted mutant (IX delta EGF1), a point mutant (IXQ50P) with a Gln-50-->Pro change, and a replacement mutant (IXPCEGF1) in which the EGF1 domain of factor IX was replaced by that of protein C. These mutants and wild-type (WT) factor IX (IXWT) were expressed in 293 kidney cells by using pRc/CMV vector. The purified proteins had the same gamma-carboxyglutamic acid content as the normal plasma factor IX (IXNP) and were activated normally by factor XIa-Ca2+. In contrast, IX delta EGF1 could not be activated by factor VIIa-tissue factor-Ca2+, and the activation of IXPCEGF1 in this system was markedly slow; however, IXQ50P was activated at a normal rate. In additional studies, both IXWT and IX delta EGF1 were rapidly converted to their respective IX alpha forms by factor Xa-phospholipid-Ca2+. Since this reaction has an absolute requirement for phospholipid, it indicates that the mutants under study are not impaired in their interactions with phospholipid. Relative coagulant activities of factor XIa-activated proteins were IXNP, 100%; IXWT, 75-85%; IX delta EGF1, < or = 1%; IXPCEGF1, < or = 2%; and IXQ50P, 6-10%. We conclude that the EGF1 domain of factor IX is required for its activation by factor VIIa-tissue factor and that the Gln-50 residue is not critical for this activation. Further, the EGF1 domain of factor IX is not essential for phospholipid binding and for its activation by factor XIa. In addition, the low coagulant activities of the activated mutants indicate that the EGF1 domain is also important in factor X activation by factor IXa-factor VIIIa-Ca(2+)-phospholipid complex.
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PMID:First epidermal growth factor-like domain of human blood coagulation factor IX is required for its activation by factor VIIa/tissue factor but not by factor XIa. 817 Sep 49

We describe a PCR-based method for domain replacement that does not require restriction site sequences. We illustrate the technique in which the first epidermal growth factor (EGF1)-like domain of factor IX (FIX) is replaced by the EGF1-like domain of protein C. The method employs four oligonucleotide primers. Two are external primers (forward primer A and inverse primer B) and contain sequences flanking the FIX cDNA nucleotides. The other two primers (forward primer C and inverse primer D) direct the PCR amplification of the EGF1-like domain of protein C, and they are hybrid primers that contain sequences of protein C gene at the 3' end and of FIX gene at the 5' end. Thus the amplified fragment of EGF1-like domain of protein C (PCEGF1 fragment) is flanked by FIX gene sequences on both ends. When this fragment is mixed with FIX cDNA and subjected to one cycle of PCR, two products are obtained: one containing PCEGF1 fragment linked to FIX cDNA sequence upstream and the other containing PCEGF1 fragment linked to FIX cDNA sequence downstream of its EGF1-like domain. The first product is amplified using primers A and D, and the second product is amplified using primers B and C. Both products contain overlapping sequences, which allow annealing upon mixing. The annealed product is amplified by PCR using primers A and B. The final product contains FIX cDNA in which its EGF1 sequence has been replaced by the PCEGF1 sequence.
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PMID:A PCR-based method for site-specific domain replacement that does not require restriction recognition sequences. 826 84

Charge-to-alanine mutations of three amino acid residues, viz, D46, D48, and D/Hya71, which are known to be important in stabilizing Ca2+ binding to epidermal growth factor (EGF) domains of vitamin K-dependent blood coagulation proteins, have been engineered into recombinant human protein C (r-PC). The resulting variants were then employed to assess the importance of this Ca2+ binding site in the activation properties of r-PC and in the activity of activated protein C (APC). Another mutation, of D48 to E, was constructed in order that a more conservative mutation at the Ca2+ binding site could be similarly examined. The mutant proteins were fully processed with regard to proper signal peptide cleavage, gamma-carboxylation, and beta-hydroxylation, except, of course, for the D71A mutant in this latter case. The D48E variant possessed an additional residue of gamma-carboxyglutamic acid (Gla), showing that E48 was gamma-carboxylated. All of the mutants were reactive against a monoclonal antibody (MAb) specific for a Ca(2+)-dependent epitope within the amino-terminus of the Gla domain of r-PC, demonstrating that a proper Ca(2+)-dependent conformation was adopted in this region of the protein. None of the mutants, except for [D48 gamma]r-PC, were reactive against another Ca(2+)-dependent MAb which possessed specificity for Ca2+ binding to the EGF1 region of PC-this being the area of the protein that contained the mutated residues. These data strongly suggest that the alanine mutations present at D46, D48, and D71 diminished Ca2+ binding to the EGF1 domain of r-PC. Steady state kinetic analysis demonstrated that determinants for the Ca(2+)-dependent inhibition of the thrombin (fIIa)-catalyzed activation of r-PC, and for the kinetic recognition of the fIIa/thrombomodulin complex, were not dependent on the integrity of the Ca2+ sites present in EGF1. The lone exception was [D48 gamma]r-PC, which did not undergo inhibition by Ca2+, an effect likely due to the potential for altered coordination of Ca2+ due to the Gla insertion, rather than to a dependency on D48. Plasma-based anticoagulant assays, as well as individual factor Va and factor VIIIa inactivation assays, showed that only [D71A]r-APC possessed a significantly reduced activity compared to wild-type r-APC. These observations suggest that D/Hya71 is likely an important determinant for activity of APC toward its physiological substrates, factor Va and factor VIIIa.
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PMID:Functional consequences of mutations in amino acid residues that stabilize calcium binding to the first epidermal growth factor homology domain of human protein C. 895 Jul 80

The genomic analysis of a 70-year-old man with recurrent deep venous thrombosis having a protein S (PS)-deficient phenotype corresponding to both type III and type II evidenced two different mutations: a +5 g-->a mutation in the donor splice site of intron e (ivs e) and a ser 460 to Pro mutation. The propositus' son, who had a type II PS deficiency phenotype, only bore the ivs e +5 g-->a mutation. The study of platelet PS mRNA prepared from this subject showed that the ivs e, +5 g-->a mutation led to the generation of two abnormal transcripts, one lacking exon 5 and the other lacking exons 5 and 6. The presence of an additional PS band with a decreased molecular mass on immunoblots performed in reducing conditions suggested the presence of truncated PS lacking EGF1 (encoded by exon 5). Two monoclonal antibodies (MoAbs) were used to further characterize the nonfunctional plasma PS. Comparison of PS levels measured with each of these MoAbs and PS levels in conventional assays was consistent with the presence of an abnormal inactive protein in the plasma of both patients bearing the ivs e, +5 g-->a mutation, suggesting that variant PS lacking EGF1 is secreted but is devoid of activated protein C cofactor activity.
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PMID:A mutation of the active protein S gene leading to an EGF1-lacking protein in a family with qualitative (type II) deficiency. 961 57

Human plasma protein S is a nonenzymatic cofactor for activated protein C (APC) in the inactivation of coagulation factors Va and VIIIa, and helps to provide an essential negative feedback on blood coagulation. Previous indirect evidence suggested that the thrombin-sensitive region (TSR: residues 47-75, 1 disulfide) and the first epidermal growth factorlike region (EGF1: residues 76-116, 3 disulfides) of protein S may be functionally important for expression of its APC cofactor activity. To study the functional importance of these modules directly, access to the isolated TSR and EGF1 modules would be preferred. Recombinant expression of protein S intact TSR and correctly folded EGF1 has not been possible. Here we describe the synthesis of both TSR and EGF1 modules by stepwise solid phase peptide synthesis using the in situ neutralization/2-(1H-benzotriazol-1-yl)-1,1,3,3-tetramethyluron ium hexafluorophosphate activation procedure for tert-butoxycarbonyl chemistry. For the TSR, correct intramodular disulfide bonding was confirmed. To overcome folding difficulties with the EGF1, a two-step oxidation procedure was used in which the cysteines involved in the middle, crossing, disulfide bond (Cys85-Cys102) remained protected with acetamidomethyl (Acm) groups after hydrogen fluoride treatment of the peptide resin. Selective formation of the first two disulfide bonds (Cys80-Cys93 and Cys104-Cys113) was followed by release of the Acm groups and subsequent formation of the third disulfide bond (Cys85-Cys102). CD studies revealed 54% of beta-sheet/turn in the EGF1 that is characteristic for EGF modules. Deuterium exchange studies suggested a very tightly packed core in EGF1 that is not accessible to the bulk solvent, likely a result from the compact structure caused by its three disulfide bonds. The 30% beta-sheet structure observed in the TSR involved amide protons that could be readily exchanged by deuterons, likely reflecting a more flexible structure of the TSR loop in contrast to the rigid structure of EGF1. The establishment of synthetic access to the TSR and EGF1 of protein S provides a versatile tool to study interactions of these modules with the blood coagulation components of the anticoagulant plasma protein C pathway.
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PMID:Chemical synthesis of human protein S thrombin-sensitive module and first epidermal growth factor module. 966 41

Human protein S (PS) potentiates the anticoagulant activity of human but not bovine activated protein C (APC), whereas bovine PS is a cofactor to APC from both species. The structural requirements for the specificity of the APC cofactor function of human PS are located in its thrombin-sensitive region (TSR) and the first epidermal growth factor (EGF1)-like module. To elucidate which residues in these two modules determine the specificity of the APC cofactor activity, 41 human PS mutants were expressed. All mutants were cofactors to human APC and some also to bovine APC. Residues in TSR (positions 49 and 52) and EGF1 (residues 97 and 106) together determined the specificity of the APC cofactor function, whereas substitution of individual residues did not change specificity. Bovine PS, and mutants expressing cofactor activity to bovine APC, stimulated phospholipid binding of bovine APC. In contrast, human PS and mutants lacking cofactor activity to bovine APC failed to support binding of bovine APC to phospholipids. These data indicate that residues in TSR and EGF1 cause the specificity of the APC cofactor activity and support the concept that key residues in these two modules interact with APC on the phospholipid surface.
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PMID:Amino acid residues in thrombin-sensitive region and first epidermal growth factor domain of vitamin K-dependent protein S determining specificity of the activated protein C cofactor function. 976 74

Protein S is an important anticoagulant protein acting as cofactor to activated protein C (APC) in the degradation of membrane-bound factors Va and VIIIa. Binding of protein S to the membrane depends on the Gla-domain, whereas sites for APC-interaction are located in the thrombin-sensitive region (TSR) and the first EGF domain. The aims of the present investigation were to localize the sites on protein S which are involved in APC-cofactor function and to elucidate possible orientations of the TSR in relation to the membrane. For these purposes, we determined the epitope for a calcium-dependent monoclonal antibody (HPS67) against the TSR, which inhibits APC cofactor activity even though it does not impede protein S binding to the membrane. HPS67 did not recognize wild-type mouse protein S but gained reactivity against a recombinant mouse protein in which G49 and R52 were mutated to R and Q (found in human protein S), respectively, suggesting these two residues to be part of a surface exposed epitope for HPS67. This information helped in the validation and refinement of the structural model for the Gla-TSR-EGF1-modules of protein S. The X-ray structure of a Fab-fragment mimicking HPS67 was docked onto the protein S model. The observation that HPS67 did not inhibit phospholipid binding of protein S has implications for the possible orientation of protein S on the membrane surface. In the proposed model for membrane-bound protein S, there is no contact between the TSR and the membrane. Rather, the TSR is free to interact with membrane-bound APC.
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PMID:Topological studies of the amino terminal modules of vitamin K-dependent protein S using monoclonal antibody epitope mapping and molecular modeling. 984 74


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