Equilibrium Blocking Model of Isometric Tension

TL;DR

This paper presents a model explaining calcium activation in striated muscle as a myosin-dependent cooperative mechanism involving tropomyosin movement, fitting experimental data and applicable to actin-myosin systems.

Contribution

It introduces a novel equilibrium blocking model that links myosin activity to cooperative calcium regulation without relying on cooperative calcium binding.

Findings

Model fits equilibrium myosin binding data

Model explains calcium-dependent tension data

Simulates non-cooperative calcium binding with or without myosin

Abstract

Calcium activation of striated muscle is known to exhibit a strongly cooperative dependency on calcium. Because the calcium receptor protein, troponin (Tn) is known to bind calcium non-cooperatively and has yet to be linked to a cooperative change in the myosin-blocking protein, tropomyosin (Tm), we describe a model in which cooperativity is exclusively a myosin-dependent mechanism. The model couples the energies of three well-described reactions with actin, namely, actin-Tn, actin-Tm, and actin-Tm-myosin, to the well-documented positions of Tm, B (blocking), C (central), and M (myosin-dependent) respectively. Results of simulations with and without data are consistent with a strand of Tm composed of ~20 subunits being moved by the concerted action of 3-5 myosin heads resulting in an all-or-none activation of the entire region of the thin filament overlapped by myosin. Equations derived from the model fit both equilibrium myosin binding data and steady-state calcium-dependent tension data and simulate non-cooperative calcium binding both in the presence and absence of myosin. All parameters of the model can be determined experimentally. The mechanism is consistent with steric blocking being both necessary and sufficient for regulation of striated muscle and can be applied to any actin-based contractile system that includes Tm and filamentous myosin.