Altered structure and dynamics of pathogenic cytochrome c variants correlate with increased apoptotic activity

Abstract

AbstractMutation of cytochrome c in humans causes mild autosomal dominant thrombocytopenia. The role of cytochrome c in platelet formation, and molecular mechanism underlying the association of cytochrome c mutations with thrombocytopenia remains unknown, although a gain-of-function is most likely. Cytochrome c contributes to several cellular processes, with exchange between conformational states proposed to regulate changes in function. Here we use experimental and computational approaches to determine whether pathogenic variants share changes in structure and function, and to understand how these changes might occur. We find that three pathogenic variants (G41S, Y48H, A51V) cause an increase in apoptosome activation and peroxidase activity. Molecular dynamics simulations of these variants, and two non-naturally occurring variants (G41A, G41T), indicate that increased apoptosome activation correlates with increased overall flexibility of cytochrome c, particularly movement of the Ω loops. This suggests that the binding of cytochrome c to apoptotic protease activating factor-1 (Apaf-1) may involve an “induced fit” mechanism which is enhanced in the more conformationally mobile variants. In contrast, peroxidase activity did not significantly correlate with protein dynamics suggesting that the mechanism by which the variants alter peroxidase activity is not related to the conformation dynamics of the hexacoordinate heme Fe state of cytochrome c analyzed in the simulations. Recent suggestions that conformational mobility of specific regions of cytochrome c underpins changes in reduction potential and the alkaline transition pK were not supported. These data highlight that conformational dynamics of cytochrome c drives some but not all of its properties and activities.