Characterizing Protease-Resistant ADAMTS13 Mutants

Abstract

ADAMTS13 is a metalloprotease that regulates the length, and thus, the platelet-capturing capacity of von Willebrand factor. The regulation of ADAMTS13 activity remains poorly understood. Numerous circulating proteases cleave ADAMTS13 in vitro, impairing its activity, but the physiological significance of this mechanism remains unknown. Two commonly cleaved regions within ADAMTS13 were identified and mutants were developed: two with one of each region mutated (T4L and T8L mutants), one with both regions mutated (T4L/T8L or “double” mutant), and one with an additional elastase site mutated (T4L/T8L + I380G). This work characterizes the mutants’ resistance to proteolysis and compares the activity of the double mutant to wild-type ADAMTS13 (WT). Each mutant and WT was incubated with purified coagulation and neutrophil proteases, activated neutrophils, or added to plasma before initiating coagulation with or without tissue plasminogen activator. Cleavage patterns were visualized with western blot. FRETS-VWF73 and microfluidic flow assays were used to compare WT and mutant activity. Coagulation proteases cleave both predicted sites within WT, and the double mutant exhibits near complete resistance to cleavage over 3 hours. Resistance to degradation by neutrophil proteases is prolonged in the double mutant, but additional cleavage sites are present. Elastase cleavage is prevented in the T4L/T8L + I380G mutant. In plasma, WT is degraded upon initiating coagulation and subsequent fibrinolysis, which is prevented in the double mutant. WT is also degraded in the presence of activated neutrophils, and the double and T4L/T8L + I380G mutants exhibit improved but incomplete resistance. Finally, the mutants exhibit similar activity to WT using FRETS-VWF73 and the microfluidic assay. This work validates the location of two protease-sensitive regions within ADAMTS13 and confirms the resistance of the double mutant to coagulation proteases in vitro. Future work will complete the activity analysis, and compare the mutants’ therapeutic efficacy to WT in vivo.