Bradykinin B2 receptor knockout mice are protected from thrombosis by increased nitric oxide and prostacyclin.

Bradykinin (BK) liberates nitric oxide, prostacyclin, and tissue plasminogen activator from endothelial cells. We hypothesized that BK B2 receptor knockout (KO) mice (BKB2R(-/-)) have increased thrombosis risk. Paradoxically, the BKB2R(-/-) mice have long bleeding times and delayed carotid artery thrombosis, 78 +/- 6.7 minutes, versus 31 +/- 2.7 minutes in controls. The mechanism(s) for thrombosis protection was sought. In BKB2R(-/-) plasma coagulation, fibrinolysis and anticoagulant proteins are normal except for an increased prekallikrein and decreased factor XI. BKB2R(-/-) mice have elevated BK 1-5 (160 +/- 75 fmol/mL, vs 44 +/- 29 fmol/mL in controls) and angiotensin II (182 +/- 41 pg/mL, vs 49 +/- 7 pg/mL in controls). Ramipril treatment shortens vessel occlusion time. BKB2R(-/-) mice have elevated plasma 6-keto-PGF1alpha (666 +/- 232 ng/mL, vs 23 +/- 5.3 ng/mL in controls) and serum nitrate (61 +/- 5.3 microM, vs 24 +/- 1.8 microM in controls). Treatment with L-NAME (NG-mono-methyl-L-arginine ester) or nimesulide shortens the thrombosis time. BKB2R(-/-) mice have increased angiotensin receptor 2 (AT2R) mRNA and protein expression. Treatment with an AT2R antagonist, PD123 319, normalizes the thrombosis time and nitrate and 6-keto-PGF1alpha. The long bleeding times in BKB2R(-/-) mice also correct with L-NAME and nimesulide therapy. In BKB2R(-/-) mice, angiotensin II binding to an overexpressed AT2R promotes thromboprotection by elevating nitric oxide and prostacyclin. These investigations indicate a pathway for thrombosis risk reduction via the plasma kallikrein/kinin and renin angiotensin systems.

Mapping the interaction of bradykinin 1-5 with the exodomain of human protease activated receptor 4.

The angiotensin converting enzyme breakdown product of bradykinin, bradykinin 1-5 (RPPGF), inhibits thrombin-induced human or mouse platelet aggregation. RPPGF binds to the exodomain of human protease-activated receptor 1 (PAR1). Studies determined if RPPGF also binds to the exodomain of human PAR4. RPPGF binds to a peptide of the thrombin cleavage site on PAR4. Recombinant wild-type and mutated exodomain of human PAR4 was prepared. The N-terminal arginine on RPPGF binds to the P2 position or proline46 on PAR4 to block thrombin cleavage. These data indicate that RPPGF influences thrombin activity by binding to the thrombin cleavage site on both PAR4 and PAR1.

Characterization of molecular defects of Fitzgerald trait and another novel high-molecular-weight kininogen-deficient patient: insights into structural requirements for kininogen expression.

A 6-year-old male with vertebral-basilar artery thrombosis was recognized to have high-molecular-weight kininogen (HK) deficiency. The propositus had no HK procoagulant activity and antigen (< 1%). Using monoclonal antibodies (Mabs) to kininogen domain 3, the propositus, family members, and Fitzgerald plasma were determined to have detectable low-molecular-weight kininogen. Mabs to HK domains 5 and 6 do not detect HK antigen in the propositus' plasma. The propositus has a single base pair (bp) deletion in cDNA position 1492 of exon 10 affecting amino acid 480 of the mature protein and resulting in a frameshift and a premature stop codon at position 1597 (amino acid 532). Unexpectedly, Mabs to the heavy chain and domain 5 of HK detect a 92-kDa form of HK in Fitzgerald plasma, the first HK-deficient plasma. The 92-kDa Fitzgerald HK has amino acid residues through 502, corresponding to domains 1 through 5, but lacks epitopes of domain 6 (positions 543 to 595). Fitzgerald DNA has a normal exon 10, but a 17-bp mutation in intron 9. These combined results indicate that mutations in the kininogen gene may differentially affect biosynthesis, processing, and/or secretion of HK.