Recombinant Human Soluble Thrombomodulin Delivers Bounded Thrombin to Antithrombin III: Thrombomodulin Associates with Free Thrombin and Is Recycled to Activate Protein C

Masaharu Aritomi; Naoko Watanabe; Rika Ohishi; Komakazu Gomi; Takao Kiyota; Shuji Yamamoto; Torao Ishida; Ikuro Maruyama

doi:10.1055/s-0038-1649597

Thrombosis and Haemostasis, Table of Contents

Thromb Haemost 1993; 70(03): 418-422
DOI: 10.1055/s-0038-1649597

Original Article

Coagulation

Schattauer GmbH Stuttgart

Recombinant Human Soluble Thrombomodulin Delivers Bounded Thrombin to Antithrombin III: Thrombomodulin Associates with Free Thrombin and Is Recycled to Activate Protein C

Authors

Masaharu Aritomi

¹The Institute for Life Science Research, Asahi Chemical Industry, Fuji City, Japan
Naoko Watanabe

¹The Institute for Life Science Research, Asahi Chemical Industry, Fuji City, Japan
Rika Ohishi

¹The Institute for Life Science Research, Asahi Chemical Industry, Fuji City, Japan
Komakazu Gomi

¹The Institute for Life Science Research, Asahi Chemical Industry, Fuji City, Japan
Takao Kiyota

¹The Institute for Life Science Research, Asahi Chemical Industry, Fuji City, Japan
Shuji Yamamoto

¹The Institute for Life Science Research, Asahi Chemical Industry, Fuji City, Japan
Torao Ishida

¹The Institute for Life Science Research, Asahi Chemical Industry, Fuji City, Japan
Ikuro Maruyama

²The Department of Clinical Laboratory Medicine, Kagoshima University School of Medicine, Kagoshima City, Japan

Abstract

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Summary

Recombinant human soluble thrombomodulin (rhs-TM), having no transmembrane domain or chondroitin sulfate, was expressed in Chinese hamster ovary cells. Interactions between rhs-TM, thrombin (Th), protein C (PC) and antithrombin III (ATIII) were studied. Equilibrium between rhs-TM and Th had no detectable time lag in clotting inhibition (K _d = 26 nM) or PC activation (K _d = 22 nM), while ATIII inhibited Th at a bimolecular rate constant = 5,200 M^-1s^-1 (K _d <0.2 nM). A mixture of ATIII, Th and rhs-TM showed that ATIII reacted with Th slower than rhs-TM, whose presence did not affect the reaction between ATIII and Th. In a mixture of rhs-TM, ATIII and PC, the repeated addition of Th caused the repeated activation of PC; which was consistent with the Simulation based on the assumption that rhs-TM is recycled as a Th cofactor. From these results, we concluded that upon inhibition of the rhs-TM-Th complex by ATIII, rhs-TM is released to recombine with free Th and begins to activate PC, while the Th-ATIII complex does not affect rhs-TM-Th equilibrium.

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References

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