Ionic Strength Influence on Myofibril Thin Filament State Probed by Troponin Exchange

Abstract

Activation of striated muscle contraction is a cooperative process initiated by calcium binding to troponin C (TnC). This is a solid-phase signal transduction process involving 3 states of thin filament: a blocked (B) state preventing myosin interaction, a closed (C) state allowing weak myosin interaction, and an fully activated open or M state. Here we evaluated the influence of ionic strength on Tn dissociation in relationship to myofibril thin filament state. The data we obtained showed that ionic strength had a significant influence on Tn dissociation with low ionic strength increasing Tn dissociation rate from non-overlap region (B or C state) and high ionic strength increasing Tn dissociation rate from overlap region (M state) of myofibril thin filament in both absence and presence of calcium. When ionic strength was decreased to ≤ 50 mM, Tn dissociation from non-overlap region became even faster than overlap region in the absence of calcium, suggesting that actin-tropomyosin in the non-overlap region actually changed from the inhibited B state to the C state at low ionic strength. Also, low ionic strength increased myofibril ATPase activity in the absence of calcium and the calcium-sensitivity of ATPase activity. Based on this and our current studies, we propose a refined kinetic scheme for Tn dissociation from myofibril thin filament, which suggests that the regulatory dissociation of TnI from actin-tropomyosin and association to TnC is not necessarily calcium coupled. Low ionic strength favors the B to C state equilibrium towards the C state (Head et al., Eur. J. Biochem, 227: 694) by favoring TnI dissociation from actin and possibly association with TnC in the absence of calcium. This well explains reported inconsistence between ATPase activity and S1 binding to actin under low ionic strength.