N2- and C8-substituted oligodeoxynucleotides with enhanced thrombin inhibitory activity in vitro and in vivo.

2'-Deoxyguanosine (G) analogues carrying various hydrophobic substituents in the N2 and C8 positions were synthesized and introduced through solid-phase synthesis into 15-mer oligodeoxynucleotide, GGTTGGTGTGGTTGG, which forms a chairlike structure consisting of two G-tetrads and is a potent thrombin inhibitor. The effects of the substitutions at N2 and C8 of the G-tetrad-forming G residues on the thrombin inhibitory activity are relatively small, suggesting that these substitutions cause relatively small perturbations on the chairlike structure formed by the oligodeoxynucleotide. Introduction of a benzyl group into N2 of G6 and G11 and naphthylmethyl groups into N2 of G6 increased the thrombin inhibitory activity, whereas other substituents in these positions had almost no effect or decreased the activity. Particularly, the oligodeoxynucleotide carrying a 1-naphthylmethyl group in the N2 position of G6 showed an increase in activity by about 60% both in vitro and in vivo. Substitutions on the N2 position of other G residues had little effect or decreased the activity. Introduction of a relatively small group, such as methyl and propynyl, into the C8 positions of G1, G5, G10, and G14 increased the activity, presumably due to the stabilization of a chairlike structure, whereas introduction of a large substituent group, phenylethynyl, decreased the activity, probably due to the steric hindrance.

In vitro and in vivo activities of oligodeoxynucleotide-based thrombin inhibitors containing neutral formacetal linkages.

A series of 15-mer oligodeoxynucleotide analogues were synthesized, and their thrombin inhibitory activities in vitro and in vivo were evaluated. These oligodeoxynucleotide analogues share the same sequence (GGTTGGTGTGGTTGG) but have one or more phosphodiester linkages replaced by a neutral formacetal group. The results obtained from monosubstitutions show that no single phosphodiester group is critical for the thrombin inhibitory activity, suggesting that the interaction between the oligodeoxynucleotide and thrombin is based on a multiple-site charge-charge interaction. Analysis of the effects of different phosphodiester replacements indicates that the backside and left side of the chairlike structure formed by the molecule may be involved in binding with thrombin, presumably by having direct contacts with the anion-binding exosite of the enzyme. For the oligodeoxynucleotides containing two noncontiguous formacetal groups, the effect of the disubstitution is the sum of the effects obtained from the corresponding two monosubstitutions. Infusion of an oligodeoxynucleotide containing four formacetal groups into monkeys showed an increased in vivo anticoagulant effect and an extended in vivo half-life compared to the unmodified oligodeoxynucleotide.

Pilot study of the efficacy of a thrombin inhibitor for use during cardiopulmonary bypass.

Heparin is normally used for anticoagulation during cardiopulmonary bypass (CPB), but its use is contraindicated in patients with a history of heparin-induced thrombocytopenia, heparin-provoked thrombosis, or both. Heparin therapy can also be ineffective due to heparin resistance. A short-acting, oligonucleotide-based thrombin inhibitor (thrombin aptamer) may potentially serve as a substitute for heparin in these and other clinical situations. We tested a novel thrombin aptamer in a canine CPB pilot study to determine its anticoagulant efficacy, the resultant changes in coagulation variables, and the aptamer's clearance mechanisms and pharmacokinetics. Seven dogs were studied initially: Four received varied doses of the aptamer (to establish the pharmacokinetic profile) and 3 received heparin. Subsequently, 4 other dogs underwent CPB, receiving a constant infusion of the aptamer before CPB (to characterize the baseline coagulation status), with partial CPB and hemodilution, during 60 minutes of total CPB, and, finally, after a 2-hour recovery period. At a 0.5 mg.kg-1.min-1 dose, the activated clotting time rose with aptamer infusion from 106 +/- 12 seconds to 187 +/- 8 seconds (+/- 1 standard deviation) (p = 0.014), increased further with hemodilution (to 259 +/- 41 seconds; p = 0.017), and was even more prolonged during total CPB (> 1,500 seconds; p < 0.001). This later increase in the activated clotting time paralleled a rise in the plasma concentration of the thrombin aptamer during total CPB, as determined by high-performance liquid chromatography.(ABSTRACT TRUNCATED AT 250 WORDS)

A peptide derived from a tissue factor loop region functions as a tissue factor--factor VIIa antagonist.

Tissue factor (TF) is a transmembrane protein that functions in the initiation of blood coagulation in vivo. At sites of vascular injury, TF serves as a cell-surface receptor for the serine protease factor VIIa (FVIIa), forming an enzyme--cofactor complex and enhancing the catalytic activity of FVIIa. Tissue factor, along with the receptors for alpha- and gamma-interferons, is a member of the class 2 cytokine receptor superfamily. Crystallographic analysis demonstrated that the extracellular domain of TF consists of two immunoglobulin-like domains joined by a linker region. Each domain is comprised of two antiparallel beta-sheets containing seven conserved beta-strands separated by more variable loop regions. Extensive mutagenesis has been performed in order to map the FVIIa binding site on TF. Results indicated that the discontinuous binding site for FVIIa lies at the domain--domain interface and includes residues from extended loops and beta-strands within both the N- and C-terminal domains. Our previous study provided evidence that three consecutive residues (D44, W45, K46) within the TF loop region between beta-strands C and C' of the N-terminal domain were important for interactions with FVIIa. We have presently extended our alanine-scanning mutagenesis to include the residues within the flanking beta-strands. Thirteen sTF mutants were screened for their ability to enhance FVIIa activity. Three residues within strand C (Y34, Q37, I38) and two residues within C' (K48, Y51) were shown to be important for TF cofactor function.(ABSTRACT TRUNCATED AT 250 WORDS)

Conversion of thrombin into an anticoagulant by protein engineering.

At sites of vascular injury, thrombin interacts with multiple procoagulant substrates, to mediate both fibrin clotting and platelet aggregation. But upon binding to thrombomodulin on the vascular endothelium, thrombin instead activates protein C, thereby functioning as an anticoagulant and attenuating clot formation. Upon infusion in vivo, both the procoagulant and anticoagulant effects of thrombin were observed. Preliminary studies indicating that thrombin's protein C activating and fibrinogen clotting activities could be dissociated by mutagenesis suggested to us that a thrombin variant that lacked procoagulant activity while retaining anticoagulant function might be an attractive antithrombotic agent. Using protein engineering, we introduced a single substitution, E229A, that substantially shifted thrombin's specificity in favour of the anticoagulant substrate, protein C. In monkeys, this modified thrombin functioned as an endogenous protein C activator demonstrating dose-dependent, reversible anticoagulation without any indication of procoagulant activity. Notably, template bleeding times were not prolonged, suggesting a reduced potential for bleeding complications.