Inhibiting Actin Polymerization Increases Tension Cost in Porcine Airway Smooth Muscle

Abstract

The polymerization of globular to filamentous actin in smooth muscle occurs upon activation and is associated with cytoskeletal remodeling. Remodeling of the cortical cytoskeleton in this manner allows for tethering of contractile proteins and force transmission to the extracellular matrix. Muscle contraction involves ATP hydrolysis and cross‐bridge cycling, which are both sensitive to internal load. During isometric activation of smooth muscle, ATP hydrolysis rate peaks initially but decreases with time, reaching a steady‐state, while maintaining maximum force. Thus, tension cost, i.e., the rate of ATP hydrolysis per unit of force, decreases over time, reflecting increased efficiency of smooth muscle contraction. We hypothesized that the time‐dependent decrease in tension cost and ATP hydrolysis are associated with actin polymerization and a subsequent increase in internal loading on cross‐bridges. In permeabilized porcine airway smooth muscle (ASM) strips, ATP hydrolysis rate and isometric force were measured simultaneously after activation with maximum Ca2+ (pCa 4.0). Two strips were tested from each animal. One strip was treated with Cytochalasin‐D (Cyto‐D; 1 μM for 30 min), an inhibitor of actin polymerization, and one was an untreated, time‐matched control. We found that peak and steady‐state isometric force decreased by ~40%, and peak and steady‐state ATP hydrolysis rate increased by ~30% and ~20%, respectively, following Cyto‐D treatment. Thus, tension cost increased by ~100% and ~60% at peak and steady‐state, respectively. These results support our hypothesis that the time‐dependent decrease in ATP hydrolysis rate relates to an increase in internal load on cross‐bridges via actin polymerization. Inhibition of actin polymerization induced by Cyto‐D in smooth muscle impairs contractile protein tethering and therefore reduces internal loading, resulting in increases in tension cost, ATP hydrolysis rate and faster cross‐bridge cycling.