Loss of protein C vs protein S results in discrepant thrombotic phenotypes

Blood Adv. 2024 Dec 10:bloodadvances.2024013237. doi: 10.1182/bloodadvances.2024013237. Online ahead of print.

Abstract

Venous thrombosis is a leading cause of morbidity/mortality and associated with deficiencies of the anticoagulant protein C (PC, PROC) and its cofactor, protein S (PS, PROS1). Heterozygous mutations increase the risk of adult-onset thrombosis, while homozygous mutations result in pre/neonatal lethal thrombosis. PC- and PS-deficient patient phenotypes are generally considered clinically indistinguishable. Here we generate proc (zebrafish PROC ortholog) and pros1 knockouts through genome editing in zebrafish and uncover partially discordant phenotypes. proc-/- mutants exhibited ~70% lethality at one year of age, while pros1-/- survival was unaffected. Induced venous endothelial injury in both mutants revealed reduced occlusive thrombus formation. This is consistent with the consumptive coagulopathy of zebrafish antithrombin (at3) knockouts, which also results in spontaneous venous thrombosis. However, proc and pros1 mutants revealed a discrepancy. Although both mutants demonstrated spontaneous thrombosis, proc-/- was localized to the cardiac and venous systems, while pros1-/- was intracardiac. Aside from coagulation, PC has been shown to have PS-independent roles in inflammation. proc mutants displayed altered inflammatory markers and defects in neutrophil migration independent of pros1. Transcriptomic analysis and gene knockdown identified novel proc genetic interactions with adgrf7, a GPCR not previously known to be involved in coagulation. In summary, our data reveal differences between PC- and PS-deficient thrombosis, with cardiovascular tissue-specific phenotypes and survival differences, suggesting the possibility of underlying clinical differences in affected patients. This model of complete proc-/- deficiency in an accessible organism will facilitate further in vivo study of these distinctions, as well as PS-dependent and independent functions of PC.