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Query: EC:3.4.21.5 (
thrombin
)
33,306
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
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.
...
PMID:Chemical synthesis of human protein S thrombin-sensitive module and first epidermal growth factor module. 966 41
Thrombospondins are thought to function as inhibitors of angiogenesis. However, the mechanism(s) of this activity is not well understood. In this study, we have used the yeast two-hybrid system to identify proteins that interact with the thrombospondins 1 (TSP1) and 2 (TSP2) properdin-like type 1 repeats (
TSR
). One of the proteins identified that interacted with both
TSR
was matrix metalloproteinase 2 (MMP2). The isolated MMP2 cDNA clone encoded amino acid residues 237-633, which include the fibronectin-like gelatin binding region flanking the catalytic center and the carboxyl hemopexin-like region. Further testing of this clone demonstrated that the
TSR
interacted with the NH(2)-terminal region of the MMP2 that contains the catalytic domain. The protein interaction observed in yeast was further demonstrated by immunoprecipitation and Western blotting using purified intact TSP1, TSP2, MMP2, and MMP9. Although MMP2 interacted with TSP1 and TSP2 via its gelatin-binding domain or a closely mapping site, neither TSP1 nor TSP2 was degraded by MMP2 in vitro. Tissue culture and in vitro assays demonstrated that the presence of purified
TSR
and intact TSP1 resulted in inhibition of MMP activity. The ability of TSP1 to inhibit MMP3-dependent activation of pro-MMP9 and
thrombin
-induced activation of pro-MMP2 suggests that the TSPs may inhibit MMP activity by preventing activation of the MMP2 and MMP9 zymogens.
...
PMID:Thrombospondin type 1 repeats interact with matrix metalloproteinase 2. Regulation of metalloproteinase activity. 1090 Feb 5
Plasma protein S exhibits multiple anticoagulant activities. About 20% of protein S normally circulates in a form that is cleaved in its
thrombin
-sensitive region (
TSR
, residues 47-72) and this cleaved protein S is inactive as a cofactor for activated protein C (APC). To clarify whether the same cleavage(s) in the
TSR
neutralizes both APC-cofactor and APC-independent direct anticoagulant activities, protein S was treated with several proteases, and activities and cleavages were monitored. Thrombin cleaved protein S first at Arg49, which abolished protein S APC-cofactor activity, but not APC-independent activity. A slower second
thrombin
cleavage at Arg70 abolished the direct prothrombinase inhibitory activity of protein S and its ability to bind phospholipids. Factor Xa cleaved protein S only at Arg60 and abolished APC-cofactor activity but not APC-independent anticoagulant activity. The snake venom enzyme Protac C efficiently cleaved protein S at two sites in the
TSR
, which impaired both types of protein S anticoagulant activity in the presence of phospholipids. Protac C-cleaved protein S did not compete with Factor Xa for limiting phospholipid surfaces but could still inhibit prothrombinase activity in the absence of phospholipids. Thus, the APC-cofactor activity protein S is significantly more sensitive to structural changes in the
TSR
than is the APC-independent activity of protein S.
...
PMID:Activated protein C-dependent and -independent anticoagulant activities of protein S have different structural requirements. 1249 Feb 86
Protein S is an anticoagulant protein containing a Gla (enclosing gamma-carboxyglutamic acids) module, a
TSR
(
thrombin
sensitive region) module, four EGF (epidermal growth factor)-like modules, and a SHBG (sex hormone binding globulin)-like region. Protein S is a cofactor to activated protein C (APC) in the degradation of coagulation factors Va and VIIIa but also has APC-independent activities. The function of the fourth EGF module (EGF4) in protein S has so far not been clear. We have now investigated this module through studies of recombinant wild-type protein S and a naturally occurring mutant (Asn217Ser). The mutant has essentially normal APC anticoagulant activity and a previously reported secretion defect. In the wild-type protein, Asn217 is normally beta-hydroxylated. The binding of calcium to wild-type protein S is characterized by four high-affinity binding sites with K(D) values ranging from 10(-)(7) to 10(-)(9) M. Three of these binding sites are located in EGF modules. Using surface plasmon resonance, competition with a calcium chelator, and antibody-based methods, we found that one high-affinity binding site for calcium was lost in protein S Asn217Ser but that the mutation also affected the calcium-dependent conformation of EGF1. We conclude that binding of calcium to EGF4 of protein S, involving Asn217, is important for the maintenance of the structure of protein S. Also, the abolition of binding of calcium to EGF4, related to Asn217, impairs both the structure and function of EGF1.
...
PMID:Binding of calcium to anticoagulant protein S: role of the fourth EGF module. 1693 20
