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Contents |
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108 a.a.
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251 a.a.
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183 a.a.
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55 a.a.
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* Residue conservation analysis
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PDB id:
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Blood clotting
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Title:
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Human tissue factor complexed with coagulation factor viia inhibited with a bpti-mutant
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Structure:
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Protein (blood coagulation factor viia). Chain: l. Fragment: light chain. Engineered: yes. Protein (blood coagulation factor viia). Chain: h. Fragment: heavy chain. Engineered: yes. Protein (soluble tissue factor).
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Source:
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Homo sapiens. Human. Organism_taxid: 9606. Expressed in: cricetulus griseus. Expression_system_taxid: 10029. Expression_system_cell_line: kidney cells (bhk). Expressed in: escherichia coli. Expression_system_taxid: 562. Synthetic: yes.
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Biol. unit:
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Octamer (from
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Resolution:
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Authors:
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E.Zhang,R.St Charles,A.Tulinsky
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Key ref:
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E.Zhang
et al.
(1999).
Structure of extracellular tissue factor complexed with factor VIIa inhibited with a BPTI mutant.
J Mol Biol,
285,
2089-2104.
PubMed id:
DOI:
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Date:
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28-Dec-98
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Release date:
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03-Dec-99
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PROCHECK
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Headers
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References
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P08709
(FA7_HUMAN) -
Coagulation factor VII from Homo sapiens
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Seq:
Struc:
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466 a.a.
108 a.a.
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P08709
(FA7_HUMAN) -
Coagulation factor VII from Homo sapiens
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Seq:
Struc:
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466 a.a.
251 a.a.
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Enzyme class:
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Chains L, H:
E.C.3.4.21.21
- coagulation factor VIIa.
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Reaction:
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Hydrolyzes one Arg-|-Ile bond in factor X to form factor Xa.
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DOI no:
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J Mol Biol
285:2089-2104
(1999)
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PubMed id:
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Structure of extracellular tissue factor complexed with factor VIIa inhibited with a BPTI mutant.
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E.Zhang,
R.St Charles,
A.Tulinsky.
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ABSTRACT
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The event that initiates the extrinsic pathway of blood coagulation is the
association of coagulation factor VIIa (VIIa) with its cell-bound receptor,
tissue factor (TF), exposed to blood circulation following tissue injury and/or
vascular damage. The natural inhibitor of the TF.VIIa complex is the first
Kunitz domain of tissue factor pathway inhibitor (TFPI-K1). The structure of TF.
VIIa reversibly inhibited with a potent (Ki=0.4 nM) bovine pancreatic trypsin
inhibitor (BPTI) mutant (5L15), a homolog of TFPI-K1, has been determined at 2.1
A resolution. When bound to TF, the four domain VIIa molecule assumes an
extended conformation with its light chain wrapping around the framework of the
two domain TF cofactor. The 5L15 inhibitor associates with the active site of
VIIa similar to trypsin-bound BPTI, but makes several unique interactions near
the perimeter of the site that are not observed in the latter. Most of the
interactions are polar and involve mutated positions of 5L15. Of the eight
rationally engineered mutations distinguishing 5L15 from BPTI, seven are
involved in productive interactions stabilizing the enzyme-inhibitor association
with four contributing contacts unique to the VIIa.5L15 complex. Two additional
unique interactions are due to distinguishing residues in the VIIa sequence: a
salt bridge between Arg20 of 5L15 and Asp60 of an insertion loop of VIIa, and a
hydrogen bond between Tyr34O of the inhibitor and Lys192NZ of the enzyme. These
interactions were used further to model binding of TFPI-K1 to VIIa and TFPI-K2
to factor Xa, the principal activation product of TF.VIIa. The structure of the
ternary protein complex identifies the determinants important for binding within
and near the active site of VIIa, and provides cogent information for addressing
the manner in which substrates of VIIa are bound and hydrolyzed in blood
coagulation. It should also provide guidance in structure-aided drug design for
the discovery of potent and selective small molecule VIIa inhibitors.
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Selected figure(s)
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Figure 1.
Figure 1. Kunitz domain sequences. Only mutations of 5L15 with respect to BPTI are shown; the alanine mutation
at the N-terminal is for expression purposes only. Black and shaded residues conserved and homologous, respect-
ively, with respect to BPTI. The P5-P5 inhibitor binding sites are indicated.
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Figure 4.
Figure 4. Stereoview of most of the polar interactions of 5L15 with VIIa. The 5L15 residues Asp11-Arg20 and
Glu46 in atom colors, VIIa residues in blue; pertinent VIIa residues in chymotrypsinogen numbering. The hydrogen
bonds are dual colored thin lines.
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The above figures are
reprinted
by permission from Elsevier:
J Mol Biol
(1999,
285,
2089-2104)
copyright 1999.
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Figures were
selected
by an automated process.
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Literature references that cite this PDB file's key reference
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PubMed id
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Reference
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E.Karaca,
and
A.M.Bonvin
(2011).
A multidomain flexible docking approach to deal with large conformational changes in the modeling of biomolecular complexes.
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Structure,
19,
555-565.
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C.J.Lee,
V.Chandrasekaran,
S.Wu,
R.E.Duke,
and
L.G.Pedersen
(2010).
Recent estimates of the structure of the factor VIIa (FVIIa)/tissue factor (TF) and factor Xa (FXa) ternary complex.
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Thromb Res,
125,
S7.
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D.J.Diller,
C.Humblet,
X.Zhang,
and
L.M.Westerhoff
(2010).
Computational alanine scanning with linear scaling semiempirical quantum mechanical methods.
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Proteins,
78,
2329-2337.
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E.Persson,
and
O.H.Olsen
(2009).
Activation loop 3 and the 170 loop interact in the active conformation of coagulation factor VIIa.
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FEBS J,
276,
3099-3109.
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J.R.Bjelke,
O.H.Olsen,
M.Fodje,
L.A.Svensson,
S.Bang,
G.Bolt,
B.B.Kragelund,
and
E.Persson
(2008).
Mechanism of the Ca2+-induced enhancement of the intrinsic factor VIIa activity.
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J Biol Chem,
283,
25863-25870.
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PDB code:
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S.Macedo-Ribeiro,
C.Almeida,
B.M.Calisto,
T.Friedrich,
R.Mentele,
J.Stürzebecher,
P.Fuentes-Prior,
and
P.J.Pereira
(2008).
Isolation, cloning and structural characterisation of boophilin, a multifunctional Kunitz-type proteinase inhibitor from the cattle tick.
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PLoS ONE,
3,
e1624.
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PDB code:
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D.M.Monroe,
and
N.S.Key
(2007).
The tissue factor-factor VIIa complex: procoagulant activity, regulation, and multitasking.
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J Thromb Haemost,
5,
1097-1105.
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O.H.Olsen,
K.D.Rand,
H.Østergaard,
and
E.Persson
(2007).
A combined structural dynamics approach identifies a putative switch in factor VIIa employed by tissue factor to initiate blood coagulation.
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Protein Sci,
16,
671-682.
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R.Krishnan,
P.L.Kotian,
P.Chand,
S.Bantia,
S.Rowland,
and
Y.S.Babu
(2007).
Probing the S2 site of factor VIIa to generate potent and selective inhibitors: the structure of BCX-3607 in complex with tissue factor-factor VIIa.
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Acta Crystallogr D Biol Crystallogr,
63,
689-697.
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PDB code:
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P.F.Neuenschwander,
S.R.Williamson,
A.Nalian,
and
K.J.Baker-Deadmond
(2006).
Heparin modulates the 99-loop of factor IXa: effects on reactivity with isolated Kunitz-type inhibitor domains.
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J Biol Chem,
281,
23066-23074.
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S.P.Bajaj,
A.E.Schmidt,
S.Agah,
M.S.Bajaj,
and
K.Padmanabhan
(2006).
High resolution structures of p-aminobenzamidine- and benzamidine-VIIa/soluble tissue factor: unpredicted conformation of the 192-193 peptide bond and mapping of Ca2+, Mg2+, Na+, and Zn2+ sites in factor VIIa.
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J Biol Chem,
281,
24873-24888.
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PDB codes:
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A.E.Schmidt,
H.S.Chand,
D.Cascio,
W.Kisiel,
and
S.P.Bajaj
(2005).
Crystal structure of Kunitz domain 1 (KD1) of tissue factor pathway inhibitor-2 in complex with trypsin. Implications for KD1 specificity of inhibition.
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J Biol Chem,
280,
27832-27838.
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PDB code:
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D.Navaneetham,
L.Jin,
P.Pandey,
J.E.Strickler,
R.E.Babine,
S.S.Abdel-Meguid,
and
P.N.Walsh
(2005).
Structural and mutational analyses of the molecular interactions between the catalytic domain of factor XIa and the Kunitz protease inhibitor domain of protease nexin 2.
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J Biol Chem,
280,
36165-36175.
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PDB code:
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H.R.Maun,
C.Eigenbrot,
H.Raab,
D.Arnott,
L.Phu,
S.Bullens,
and
R.A.Lazarus
(2005).
Disulfide locked variants of factor VIIa with a restricted beta-strand conformation have enhanced enzymatic activity.
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Protein Sci,
14,
1171-1180.
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Y.Fromovich-Amit,
A.Zivelin,
N.Rosenberg,
M.Landau,
J.P.Rosa,
and
U.Seligsohn
(2005).
Of four mutations in the factor VII gene in Tunisian patients, one novel mutation (Ser339Phe) in three unrelated families abrogates factor X activation.
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Blood Coagul Fibrinolysis,
16,
369-374.
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A.Zivelin,
T.Ogawa,
S.Bulvik,
M.Landau,
J.R.Toomey,
J.Lane,
U.Seligsohn,
and
D.Gailani
(2004).
Severe factor XI deficiency caused by a Gly555 to Glu mutation (factor XI-Glu555): a cross-reactive material positive variant defective in factor IX activation.
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J Thromb Haemost,
2,
1782-1789.
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H.S.Chand,
A.E.Schmidt,
S.P.Bajaj,
and
W.Kisiel
(2004).
Structure-function analysis of the reactive site in the first Kunitz-type domain of human tissue factor pathway inhibitor-2.
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J Biol Chem,
279,
17500-17507.
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J.H.Morrissey
(2004).
Tissue factor: a key molecule in hemostatic and nonhemostatic systems.
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Int J Hematol,
79,
103-108.
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K.E.Eilertsen,
and
B.Østerud
(2004).
Tissue factor: (patho)physiology and cellular biology.
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Blood Coagul Fibrinolysis,
15,
521-538.
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S.Pestka,
C.D.Krause,
D.Sarkar,
M.R.Walter,
Y.Shi,
and
P.B.Fisher
(2004).
Interleukin-10 and related cytokines and receptors.
|
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Annu Rev Immunol,
22,
929-979.
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Y.Fromovich-Amit,
A.Zivelin,
N.Rosenberg,
H.Tamary,
M.Landau,
and
U.Seligsohn
(2004).
Characterization of mutations causing factor VII deficiency in 61 unrelated Israeli patients.
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J Thromb Haemost,
2,
1774-1781.
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A.Aktimur,
M.A.Gabriel,
D.Gailani,
and
J.R.Toomey
(2003).
The factor IX gamma-carboxyglutamic acid (Gla) domain is involved in interactions between factor IX and factor XIa.
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J Biol Chem,
278,
7981-7987.
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B.V.Norledge,
R.J.Petrovan,
W.Ruf,
and
A.J.Olson
(2003).
The tissue factor/factor VIIa/factor Xa complex: a model built by docking and site-directed mutagenesis.
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Proteins,
53,
640-648.
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PDB code:
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G.Mariani,
F.H.Herrmann,
S.Schulman,
A.Batorova,
K.Wulff,
D.Etro,
A.Dolce,
G.Auerswald,
J.Astermark,
J.F.Schved,
J.Ingerslev,
and
F.Bernardi
(2003).
Thrombosis in inherited factor VII deficiency.
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J Thromb Haemost,
1,
2153-2158.
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E.Persson,
and
O.H.Olsen
(2002).
Assignment of molecular properties of a superactive coagulation factor VIIa variant to individual amino acid changes.
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Eur J Biochem,
269,
5950-5955.
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K.Soejima,
M.Yuguchi,
J.Mizuguchi,
K.Tomokiyo,
T.Nakashima,
T.Nakagaki,
and
S.Iwanaga
(2002).
The 99 and 170 loop-modified factor VIIa mutants show enhanced catalytic activity without tissue factor.
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J Biol Chem,
277,
49027-49035.
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L.Perera,
T.A.Darden,
and
L.G.Pedersen
(2002).
Predicted solution structure of zymogen human coagulation FVII.
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J Comput Chem,
23,
35-47.
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C.Eigenbrot,
D.Kirchhofer,
M.S.Dennis,
L.Santell,
R.A.Lazarus,
J.Stamos,
and
M.H.Ultsch
(2001).
The factor VII zymogen structure reveals reregistration of beta strands during activation.
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Structure,
9,
627-636.
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PDB code:
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D.Kirchhofer,
C.Eigenbrot,
M.T.Lipari,
P.Moran,
M.Peek,
and
R.F.Kelley
(2001).
The tissue factor region that interacts with factor Xa in the activation of factor VII.
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Biochemistry,
40,
675-682.
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E.Persson,
L.S.Nielsen,
and
O.H.Olsen
(2001).
Substitution of aspartic acid for methionine-306 in factor VIIa abolishes the allosteric linkage between the active site and the binding interface with tissue factor.
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Biochemistry,
40,
3251-3256.
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E.Persson,
M.Kjalke,
and
O.H.Olsen
(2001).
Rational design of coagulation factor VIIa variants with substantially increased intrinsic activity.
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Proc Natl Acad Sci U S A,
98,
13583-13588.
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M.Osterlund,
R.Owenius,
K.Carlsson,
U.Carlsson,
E.Persson,
M.Lindgren,
P.O.Freskgård,
and
M.Svensson
(2001).
Probing inhibitor-induced conformational changes along the interface between tissue factor and factor VIIa.
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Biochemistry,
40,
9324-9328.
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L.C.Petersen,
O.H.Olsen,
L.S.Nielsen,
P.O.Freskgård,
and
E.Persson
(2000).
Binding of Zn2+ to a Ca2+ loop allosterically attenuates the activity of factor VIIa and reduces its affinity for tissue factor.
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Protein Sci,
9,
859-866.
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R.J.Petrovan,
and
W.Ruf
(2000).
Role of residue Phe225 in the cofactor-mediated, allosteric regulation of the serine protease coagulation factor VIIa.
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Biochemistry,
39,
14457-14463.
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A.C.Pike,
A.M.Brzozowski,
S.M.Roberts,
O.H.Olsen,
and
E.Persson
(1999).
Structure of human factor VIIa and its implications for the triggering of blood coagulation.
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Proc Natl Acad Sci U S A,
96,
8925-8930.
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PDB code:
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J.Shobe,
C.D.Dickinson,
T.S.Edgington,
and
W.Ruf
(1999).
Macromolecular substrate affinity for the tissue factor-factor VIIa complex is independent of scissile bond docking.
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J Biol Chem,
274,
24171-24175.
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R.Owenius,
M.Osterlund,
M.Lindgren,
M.Svensson,
O.H.Olsen,
E.Persson,
P.O.Freskgård,
and
U.Carlsson
(1999).
Properties of spin and fluorescent labels at a receptor-ligand interface.
|
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Biophys J,
77,
2237-2250.
|
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The most recent references are shown first.
Citation data come partly from CiteXplore and partly
from an automated harvesting procedure. Note that this is likely to be
only a partial list as not all journals are covered by
either method. However, we are continually building up the citation data
so more and more references will be included with time.
Where a reference describes a PDB structure, the PDB
code is
shown on the right.
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Links
