A heparin cofactor II (HCII) mutant with an Arg substituted for Leu 444 at the P1 position (L444R-rHCII) was previously found to have altered proteinase specificity (Derechin, V. M., Blinder, M. A., and Tollefsen, D. M. (1990) J. Biol. Chem. 265, 5623-5628). The present study characterizes the effect of glycosaminoglycans on the substrate versus inhibitor activity of L444R-rHCII. Heparin increased the stoichiometry of inhibition of L444R-rHCII with ␣-thrombin (compared with minus glycosaminoglycan) but decreased it with R93A,R97A,R101A-thrombin, a mutant thrombin that does not bind glycosaminoglycans. Dermatan sulfate decreased the stoichiometry of inhibition of L444R-rHCII with both proteinases. SDS-polyacrylamide gel electrophoresis showed no proteolysis of L444R-rHCII when incubated with R93A,R97A,R101A-thrombin in the absence or the presence of glycosaminoglycan or with ␣-thrombin and dermatan sulfate. In contrast, greater than 75% of the L444R-rHCII was converted to a lower molecular weight form when incubated with ␣-thrombin/heparin. A time course of ␣-thrombin inhibition by L444R-rHCII/heparin showed a rapid but transient inhibition with approximately 80% of the ␣-thrombin activity being regained after 6 h of incubation. In contrast, all other combinations of inhibitor, proteinase, and glycosaminoglycan resulted in complete and sustained inhibition of the proteinase. Heparin fragments of 8 -20 polysaccharides in length rapidly accelerated L444R-rHCII inhibition of both ␣-thrombin and R93A,R97A,R101A-thrombin. After extended incubations, R93A,R97A,R101A-thrombin was completely inhibited by L444R-rHCII with all the heparin fragments, but approximately 30 -50% of ␣-thrombin activity remained with fragments long enough to bridge HCII-thrombin. These results collectively indicate that ternary complex formation, mediated by heparin, increases L444R-rHCII inactivation by ␣-thrombin.
Serine proteinase inhibitors (serpins)1 are a highly conserved family of proteins whose primary role is to regulate the activity of a wide variety of serine proteinases involved in processes such as blood coagulation, fibrinolysis, inflammation, and cancer metastasis (1-3). Serpins inhibit their target proteinase by functioning as suicide substrates. The serpin contains a peptide bond, termed P1-P1Ј by the nomenclature of Schechter and Berger (4), within an exposed region, called the reactive site loop, that is recognized as a substrate by the proteinase (2). The initial binding of the serpin and proteinase results in the formation of a Michaelis complex, which can then partition between a kinetically stable intermediate, resulting in proteinase inhibition, and a cleaved inactive inhibitor (3, 5, 6). Although the sequence of the amino acids in the reactive site loop and on the P1-P1Ј residues in particular determines in part the proteinase specificity of the serpin, they also determine the partitioning of the serpin into an inhibitor versus substrate pathway with a given proteinase. Heparin cofactor II (HCII), protein C inhibitor, pr...
