Draculin (named after Count Dracula) is a glycoprotein found in the saliva of vampire bats, Desmodus rotundus. It functions as an anticoagulant, inhibiting coagulation factors IX (IXa) and X (Xa) by establishing rapid equilibrium with factor Xa, and is the first natural polypeptide which has been described to show immediate anti-IXa and anti-Xa properties. The rapid equilibrium achieved at comparable concentrations of FXa and Draculin, as well as the lack of any detectable lag phases in assays, supports the conclusion that Draculin is a tight-binding inhibitor. In addition, Draculin inhibits the conversion of prothrombin to thrombin, preventing fibrinogen from converting to fibrin.
thumb|Blood CoagulationDraculin is a noncompetitive, tight-binding inhibitor of FXa. The inhibition upon contact with the blood of the victim is immediate. Draculin forms equimolar complexes with factor FXa. The formation of draculin-factor Xa is a two-stage process. The first reversible stage is characterized by the following constants: k1 = 1.117*106 M-1*sec-1, k-1 = 15.388*10-1 sec-1. The second irreversible (concentration-independent) stage is characterized by the forward reaction rate constant k2 = 0.072 sec-1. The dissociation constant is determined as the ratio k-1/k1 = 13.76 nM. Because of the immediate inhibition, the reaction is not readily reversible initially, but is a reversible reaction. It does not act on thrombin, trypsin or chymotrypsin and does not express fibrinolytic activity. The protein increases the lag phase as well as the height of the peak of thrombin generation when in plasma, leading to prolonged bleeding. As a glycoprotein, Draculin requires a specific glycosylation profile to express its maximum inhibitory activity. Its attached oligosaccharides are essential FXa inhibition, as demonstrated by the loss of anti-Xa activity following incubation with the lectins WGA and PNA.
left|thumb|367x367px|Example of Noncompetitive inhibition
P-aminobenzamidine (pAB) is used as fluorescent probe that reports on the active site accessibility in serine proteases, showing increased fluorescence upon binding. Scientists have found that Draculin does not interfere with pAB-FXa binding; however, at concentrations that inhibit FXa, Draculin has been shown to reduce the fluorescence of the pAB-FXa complex by 14%. This observation, and the Lineweaver-Burk pattern, supports Draculin's noncompetitive inhibitory mechanism and suggests that additional Draculin-FXa-[S] complexes can form under these conditions. Although prey animals have been known to develop acquired immunological resistance to Draculin over prolonged exposure, the frequent site-directed or mutagenesis with the venom limits the rapid evolution of such resistance.