Biochemical characterization of plasma-derived tissue factor pathway inhibitor: post-translational modification of free, full-length form with particular reference to the sugar chain.

BACKGROUND: Tissue factor pathway inhibitor (TFPI) is a physiological protease inhibitor that inhibits the initial reactions of the extrinsic blood coagulation pathway. Most TFPI in human plasma is associated with lipoproteins; however, the most functionally active form is thought to be the free, full-length form (f-pTFPI). Cell culture derived TFPI and recombinant TFPI (rTFPI) exhibit variations in their respective anticoagulant activity, which may be caused by post-translational modifications, such as the frequent differences in sugar chain structures among recombinant proteins. Sugar chain structures in rTFPI expressed in Chinese hamster ovary (CHO) cells have been reported previously, but those of plasma TFPI have not been. OBJECTIVES: To purify f-pTFPI and analyze the sugar chain structures. RESULTS AND CONCLUSION: f-pTFPI was purified to homogeneity from blood plasma using a combination of anion-exchange, heparin affinity, immunoaffinity, and reversed-phase chromatographies, resulting in a yield of 76%. f-pTFPI showed a partially phosphorylated glycoprotein comprising a total of 276 amino acids by peptide mapping. The sugar chain structures were analyzed by two-dimensional sugar mapping combined with exoglycosidase digestion of the pyridylamino sugar chains and the following results were obtained. (Sialyl) Galbeta1-3GalNAc was linked to Thr(175), partially to Thr(14) and Ser(174); sialyl complex-type sugar chains to Asn(117) and Asn(167), whereas Asn(228) was not glycosylated. Neuraminidase-resistant acidic sugar chains including sulfated sugar chains were not observed significantly. The protease inhibitory activities of f-pTFPI towards activated factor (F) X and tissue factor-activated FVII complex were identical to those of full-length rTFPI expressed in CHO cells.

Bemiparin and fluid flow modulate the expression, activity and release of tissue factor pathway inhibitor in human endothelial cells in vitro.

We investigated the localisation, gene expression, and activity of tissue factor pathway inhibitor (TFPI) in endothelial cells (EC) grown in static conditions or under shear stress, in the presence of unfractionated heparin (UFH) and two low-molecular-weight heparins (LMWHs). dalteparin and bemiparin (a second generation of LMWHs). All three preparations induced increased release, cellular redistribution, and enhanced activity of TFPI on the cell surface in static EC. In EC grown under shear stress (0.27, 4.1 and 19 dyne/cm2) and incubated with each heparin for 24 h, the release of TFPI was significantly correlated with the level of flow for bemiparin and dalteparin, but not for UFH. For all three levels of flow tested, bemiparin induced the highest secretion and increase of both cellular TFPI and cell surface activity of the inhibitor. The expression of TFPI mRNA, determined by Northern blotting, was specifically modulated by heparins. All three preparations increased the expression of TFPI by 60 to 120% in EC under minimal flow, but only bemiparin enhanced TFPI mRNA in EC under the arterial flow. Immunogold electron microscopy revealed that EC exhibited strong cellular labelling for TFPI when grown under arterial flow in the presence of bemiparin. We conclude that in EC subjected to shear stress in vitro bemiparin is more efficient than UFH or dalteparin in modulating the expression. release and activity of TFPI. We therefore suggest that bemiparin may be superior over the conventional heparins in maintaining the anticoagulant properties of the endothelium.

A kinetic analysis of the interaction of human recombinant tissue factor pathway inhibitor with factor Xa utilizing and immunoassay and the effect of antithrombin III/heparin on the complex formation.

We have recently shown that a complex formation of tissue factor pathway inhibitor (TFPI) and factor Xa (Xa) promotes a clearance of proteoglycans-associated TFPI. In the current studies, the interaction between human recombinant TFPI (h-rTFPI) and Xa were kinetically analyzed by utilizing both a protease inhibitor, p-(amidophenyl) methanesulfonyl fluoride hydrochloride, and a specific enzyme-linked immunosorbent assay for the complex of h-rTFPI with Xa. We further investigated the effect of antithrombin III on the complex formation between h-rTFPI and Xa. We found that the h-rTFPI/Xa complex formed in a time-dependent manner: the second-order rate constant (K1) for the complex formation was calculated to be 0.86x10(6) M(-1)s(-1). The addition of antithrombin III to the h-rTFPI solution modestly reduced the rate of the complex formation between h-rTFPI and Xa. Heparin strikingly enhanced antithrombin III's inhibition of Xa and resulted in complete abrogation of the complex formation between h-rTFPI and Xa in the absence or presence of acidic phospholipids. Furthermore, antithrombin III induced dissociation of the preformed h-rTFPI/Xa complex in the presence of heparin. These results suggest that in the presence of heparin, antithrombin III interferes with the catabolism of TFPI mediated via Xa.

Human recombinant tissue factor pathway inhibitor induces apoptosis in cultured human endothelial cells.

Tissue factor pathway inhibitor (TFPI) is mainly synthesized in vascular endothelial cells and exhibits a strong and specific inhibitory activity against tissue factor-mediated blood coagulation. In the present study, we demonstrate that human recombinant TFPI (h-rTFPI) inhibits the growth of cultured human umbilical vein endothelial cells (HUVECs) by inducing apoptosis. In a growth-rate assay of HUVECs, the growth of the cultured HUVECs is completely abolished by the addition of 1 microM h-rTFPI to the culture medium containing fetal bovine serum (FBS), basic fibroblast growth factor, and epidermal growth factor. In addition, h-rTFPI and h-rTFPI-C which lacks the carboxyl-terminal basic region prevent the survival of growth-arrested HUVECs which are starved in a medium containing 2%, FBS alone, suggesting that h-rTFPI directly induces the death of these HUVECs. This hypothesis is supported by the finding that h-rTFPI does not inhibit the synthesis of DNA in HUVECs during proliferation, as shown by a 5-bromo-2'-deoxyuridine (BrdU) incorporation assay. Furthermore, Giemsa staining and a gel electrophoretic analysis of DNA fragmentation show that the HUVEC death mediated by h-rTFPI has the typical characteristics of apoptosis. However, the apoptosis in HUVECs is considerably inhibited in the presence of 1 microg/ml of the protein synthesis inhibitor, cycloheximide. Therefore, the process of apoptosis triggered by h-rTFPI is, at least in part, actively conducted by the cells.

Human recombinant tissue-factor pathway inhibitor prevents the proliferation of cultured human neonatal aortic smooth muscle cells.

Tissue-factor pathway inhibitor (TFPI) inhibits the procoagulant activity of the tissue-factor/factor VIIa complex. It was recently reported that TFPI prevented restenosis following tissue injury in a rabbit atherosclerotic model. In order to clarify the mechanism behind this successful prevention of restenosis, we investigated the direct effect of human recombinant TFPI (h-rTFPI) on the proliferation of cultured human neonatal aortic smooth muscle cells (hSMC). We found that h-rTFPI exhibits inhibitory activity toward hSMC proliferation, while h-rTFPI-C which lacks the carboxyl (C)-terminal region does not. Furthermore, we found that h-rTFPI binds to hSMCs with K(d) = 526 nM but that this binding is inhibited by the addition of the synthetic C-terminal peptide, Lys254-Met276, to h-rTFPI. Thus, the interaction of h-rTFPI with hSMCs mediated via the C-terminal region is responsible for the anti-proliferative action of h-rTFPI. On the basis of these results, we presume that the anti-proliferative effect of h-rTFPI in addition to its anticoagulant function plays a significant role in preventing restenosis following tissue injury.

Antithrombotic effect of human recombinant tissue factor pathway inhibitor on endotoxin-induced intravascular coagulation in rats: concerted effect with antithrombin.

In our current study, we examined the antithrombotic effect of Chinese hamster ovary cell-derived human recombinant tissue factor pathway inhibitor (h-rTFPI) by intravenous injection of h-rTFPI with or without antithrombin into endotoxin-treated rats. An injection of h-rTFPI at a high dose (4 mg/kg of h-rTFPI or three doses of 1 mg/kg) significantly prevented the decrease of fibrinogen and factor VIII and the increase of fibrin/fibrinogen degradation products and glutamic-pyruvic transaminase in rats, while a single injection of 1 mg/kg of h-rTFPI or 250 U/kg of antithrombin did not significantly prevent intravascular coagulation. However, a simultaneous injection of 1 mg/kg of h-rTFPI and 250 U/kg of antithrombin did significantly prevent intravascular coagulation. From the studies on the clearance rate and immunohistochemical staining of injected h-rTFPI into normal rats, we found that most of the intravenously-injected h-rTFPI was localized on the central vein and sinusoids in the liver and catabolized via the proteoglycan-mediated pathway with a half-life of 48 min. These results suggest that h-rTFPI and antithrombin prevented endotoxin-induced intravascular coagulation in concert by binding to the vascular walls of the liver and by inhibiting fibrin formation on Kupffer cells in hepatic sinusoids.

The clearance of proteoglycan-associated human recombinant tissue factor pathway inhibitor (h-rTFPI) in rabbits: a complex formation of h-rTFPI with factor Xa promotes a clearance rate of h-rTFPI.

The very rapid clearance of human recombinant tissue factor pathway inhibitor (h-rTFPI) may result from its binding to vascular proteogly can and LDL receptor-related protein (LRP). To investigate the effect of factor Xa on the clearance of h-rTFPI, we developed a specific ELISA for h-rTFPI/factor Xa complex, and compared the pharmacokinetic parameters of h-rTFPI/factor Xa complex and the clearance rate of the cellular proteogly can-associated h-rTFPI/factor Xa complex with those of h-rTFPI by itself in rabbits. We found that the h-rTFPI/factor Xa complex disappeared from circulation at a rapid rate of clearance, having pharmacokinetic parameters similar to those of non-complexed h-rTFPI. After the rapid disappearance of the h-rTFPI complex from plasma, an intravenous injection of heparin resulted in a release of h-rTFPI/factor Xa complex into plasma. However, the recovery of heparin-releasable h-rTFPI/factor Xa decreased significantly in a time-dependent manner. Therefore, we examined the half-life of proteogly can-associated h-rTFPI/factor Xa and determined it to be 51 min, which was significantly shorter than that of h-rTFPI by itself (107 min). These results suggest that a complex formation of h-rTFPI with factor Xa promotes a clearance of proteogly can-associated h-rTFPI existing in the liver and kidney.

Amino acid sequence and carbohydrate structure of a recombinant human tissue factor pathway inhibitor expressed in Chinese hamster ovary cells: one N-and two O-linked carbohydrate chains are located between Kunitz domains 2 and 3 and one N-linked carbohydrate chain is in Kunitz domain 2.

Human tissue factor pathway inhibitor is a protease inhibitor with three tandem Kunitz-type inhibitory domains. The recombinant protein (r-hTFPI) was produced using Chinese hamster ovary cells, and its polypeptide and carbohydrate chain structures were analyzed. The complete amino acid sequence, composed of 276 residues, was determined using a protein sequencer after protease digestion and it was identical to that predicted from the cDNA sequence. Among three potential N-glycosylation sites, both Asn117 and Asn167 were fully N-glycosylated but Asn228 was not. Thr175 was also fully O-glycosylated, but Ser174 was partially O-glycosylated. Carbohydrate composition and mass spectrometric analyses of the undecapeptide OG-11 (residues Leu 170approximately Leu180) showed that two O-linked carbohydrate chains consisted of a type-1 core structure (Gal-GalNAc-Ser/Thr) with 0-3 mol of N-acetylneuraminic acid(s). The N-linked carbohydrate chains were analyzed by two-dimensional carbohydrate mapping combined with sequential glycosidase digestion, after the reducing-ends of carbohydrate residues were tagged with 2-aminopyridine and non-reducing-end sialic acids were removed with sialidase. All the N-linked structures in r-hTFPI were complex-type carbohydrate chains with one fucose residue attached to the reducing-end GlcNAc and consisted of bi-, tri-, and tetraantennary carbohydrate chains in the ratio 1.9:1.3:1.0. Fucosylated tri- and tetraantennary carbohydrate chains with one or two N-acetyllactosaminyl repeats were also found (30% of carbohydrate chains determined). Thus, the region between Kunitz domains 2 and 3 encoded by exon 7 was highly glycosylated by two O-linked carbohydrate chains at Ser174 and Thr175 and one N-linked carbohydrate chain at Asn167. These results indicated that the region is occupied by a cluster of three bulky and acidic carbohydrate chains.

Thermostable peroxidase activity with a recombinant antibody L chain-porphyrin Fe(III) complex.

In order to engineer a new type of catalytic antibody, we attempt to use a monoclonal antibody L chain as a host protein for a porphyrin. TCPP (meso-tetrakis(4-carboxyphenyl)porphyine) was chemically synthesized and Balb/c mice were immunized using TCPP as a hapten. Two hybridoma cells (03-1, 13-1), that produce monoclonal antibody against TCPP, were obtained. Genes for both H and L chains of monoclonal antibodies were cloned, sequenced and overexpressed using E. coli as a host. ELISA and fluorescence quenching method show that the independent antibody L chains from both Mab03-1 and Mab13-1 have specific interaction with TCPP. Furthermore, the recombinant antibody L chain from Mab13-1 exhibits much higher peroxidase activity than TCPP Fe(III) alone. The enzyme activity was detectable with pyrogallol and ABTS (2,2-azinobis-3-ethylbenzthiazolin-6-sulfonic acid) but not with catechol. This new catalytic antibody was extremely thermostable. Optimum temperature of the peroxidase reaction by the complex of 13-1L chain and TCPP Fe(III) was 90 degrees C, while that the TCPP Fe(III) alone was 60 degrees C.

Amino acid sequence and inhibitory activity of rhesus monkey tissue factor pathway inhibitor (TFPI): comparison with human TFPI.

Rhesus monkey cDNA for tissue factor pathway inhibitor (TFPI) was cloned by means of the reverse transcriptase-polymerase chain reaction, using liver mRNA, and its nucleotide sequence was determined by sequencing five independent clones. Monkey TFPI was found to have a signal peptide of 28 amino acid residues and to be a mature protein of 276 amino acid residues, in which three and seventeen amino acid residue substitutions compared to human TFPI were found, respectively. All the cysteine residues, three putative carbohydrate-linked asparagine residues, and the P1 amino acid residues of each of the three Kunitz inhibitor domains were conserved in the two species. Recombinant monkey TFPI (rTFPI) was isolated from the culture medium of transformed Chinese hamster ovary cells. Amino acid sequence analysis and immunoblotting analysis, using polyclonal and monoclonal antibodies, showed that the carboxyl-terminal basic part of Rhesus monkey rTFPI had been truncated. The inhibitory activity of monkey rTFPI was compared with that of human rTFPI without the carboxyl-terminal basic part. The prothrombin time of human plasma was slightly more prolonged by the addition of monkey rTFPI than by that of human rTFPI. However, no significant differences were found between the potencies of human and monkey rTFPI as to the inhibition of factor Xa and tissue factor-factor VIIa complex.

N-fatty acyl compounds inhibit myristoyl acylation of pp60v-src and reduce tumorigenicity of Rous sarcoma virus-infected cells.

Prevention of NH2-terminal myristoylation of pp60v-src was determined with N-fatty acyl glycinal derivatives. Of all the compounds tested, N-myristoyl and N-lauroyl glycinal diethylacetal, N-myristoyl glycyl glycinal diethylacetal, and N-myristoyl-4-aminobutyl aldehyde diethylacetal strongly inhibited myristoylation of pp60v-src; but N-myristoyl diglycyl, N-myristoyl triglycyl, N-decanoyl glycinal diethylacetal, and N-palmitoyl glycinal diethylacetal did not. N-Myristoyl glycinal diethylacetal (25 or 50 microM) suppressed both morphological transformation and colony formation of Rous sarcoma virus-infected chick embryo fibroblasts.