Cellular and functional characterization of three recombinant antithrombin mutants that caused pleiotropic effect-type deficiency.

Abstract

Inherited antithrombin deficiency is associated with a predisposition for familial venous thromboembolic disease. Pleiotropic effect-type mutants of antithrombin that have an amino acid replacement in a distal hinge region including strands 1C, 4B, and 5B of the polypeptide chain are known to exhibit impaired interactions with both thrombin and heparin, coupled with a secretion defect. To examine the mechanism of pleiotropic effect-type antithrombin deficiency, we expressed three mutants, Oslo (Ala404-->Thr), Kyoto (Arg406-->Met), and Utah (Pro407-->Leu), in baby hamster kidney (BHK) cells, and compared their secretion rates, affinities for heparin and abilities to form thrombin-antithrombin (TAT) complexes with those of wild-type (Wt) antithrombin. Pulse-chase experiments showed that the Oslo- and Kyoto-mutants were secreted at rates similar to Wt antithrombin. In contrast, the Utah-mutant underwent partial intracellular degradation. The intracellular degradation of the Utah-mutant was not inhibited by lysosomotropic inhibitors, but by proteasome inhibitors such as carbobenzoxy-L-leucyl-L-leucyl-L-leucinal (LLL) and lactacystin, indicating that a part of the Utah-mutant was degraded by proteasome through quality control in the endoplasmic reticulum (ER). Crossed immunoelectrophoresis in the presence of heparin showed that only the Oslo-mutant lacks heparin-binding ability. Incubation with thrombin showed that the Kyoto- and Utah-mutants, but not the Oslo-mutant, formed a weak but detectable TAT complex. Furthermore, heparin enhanced the TAT complex formation by the Kyoto- and Utah-mutants, suggesting heparin cofactor activities of these mutants. These results show that each of the Oslo-, Kyoto-, and Utah-mutants exhibits different properties as to secretion, intracellular degradation and functional activity, although they are grouped as pleiotropic effect-type mutants.