Although suspected conceptually in the 60 s, Protein C and Protein S activities in hemostasis were investigated and reported from the mid-80 s, followed by the discovery of Thrombomodulin, an endothelial cell membrane associated protein, playing the most important heamostatic role. These 3 proteins act in regulating thrombogenesis and protecting against thrombo-embolic events. When blood is activated, any trace of circulating thrombin is captured by Thrombomodulin in the microcirculation, making thrombin become an anticoagulant through its capacity to activate Protein C to Activated Protein C, which operates as a sentinel in blood coagulation, in the form of a complex with free Protein S, to block any new blood activation site, and more especially circulating activated Factors V and VIII. Protein S not only acts as the Activated Protein C cofactor, but also as the cofactor of Tissue Factor Pathway Inhibitor. In addition, it has some functions in the complement pathway through its binding to C4b-BP. Another capability of activated protein C is to lower fibrinolytic activity, as the Activated Protein C Inhibitor is also known as Plasminogen Activator Inhibitor 3. The Protein C-Protein S system becomes less efficient in the presence of mutated Factor V (Factor V-Leiden or other variants), which is resistant to its inactivating effect. Other pathologies linked to this system concern the development of allo- or auto-antibodies to Protein S or to thrombin, which can generate severe thrombotic complications in affected patients. Some antithrombotic drugs have originated from this regulatory system. Protein C or Protein S concentrates are used for treating deficient patients. Activated Protein C (especially in patients with sepsis) or Thrombomodulin are proposed as antithrombotic medications. Most importantly, congenital or acquired Protein C or Protein S deficiencies are associated with severe recurrent thrombotic events. From the clinical standpoint most of the patients are heterozygous, as homozygosity is almost incompatible with life in the absence of a continuous and efficient treatment. Laboratory investigation of this highly complex system involves many different specialized assays for measuring these 3 proteins' activities, their antigenic content or their genetic sequence. The Protein S in-vitro anticoagulant activity is weak and contrasts with its high antithrombotic role in-vivo, showing that diagnostic assays have not yet succeeded in reproducing all the natural mechanisms for evidencing the anticoagulant role of Protein S. This paradoxal notion is discussed and illustrated in this manuscript as well is a revisit of the major characteristics and pathophysiological functions of the Protein C-Protein S-Thrombomodulin system; the associated pathologies; and the main laboratory tools available for clinical diagnosis. In respect to future perspectives, we also focused on developing more significant and relevant assays, especially for Protein S, thanks to the understanding of its biological roles.
Keywords: Laboratory assays; Protein C; Protein S; Regulation of coagulation; Thrombomodulin.
Copyright © 2019. Published by Elsevier Ltd.