Mechanisms Underlying TNFα‐Induced Hyperreactivity in Airway Smooth Muscle

Abstract

Inflammation and pro‐inflammatory cytokines (e.g., TNFα, IL‐13) induce airway smooth muscle (ASM) hyper‐reactivity and remodeling characteristic of asthma. We hypothesized that exposure to TNFα (and IL‐13) increases isometric force generation in porcine ASM via several underlying mechanisms: 1) increasing sensitivity to ACh stimulation; 2) enhancing the cytosolic Ca2+ ([Ca2+]cyt) response to ACh; 3) increasing the Ca2+ sensitivity of force generation; 4) enhancing the Ca2+‐dependent phosphorylation of myosin regulator light chain (rMLC); 5) promoting expression of non‐muscle rMLC; 6) increasing actin and myosin heavy chain (MyHC) content (i.e., the number of contractile units); and/or 7) promoting cytoskeletal remodeling (actin polymerization). Studies were performed on intact ASM strips (~1 mm wide × ~5 mm long) dissected from porcine tracheas obtained from a local abattoir. The ASM strips were placed in PSS with and without TNFα (100 ng/ml) for 24 h. The ACh concentration dependence of force generation ASM was determined (ACh range from 10 nM to 1mM), and the EC50 (i.e., the ACh concentration that produces 50% of maximal ASM force) was determined. In control, untreated ASM, the EC50 for ACh was 2.6 μM compared to 1.3 μM following TNFα treatment. We found that across all ACh concentrations, ASM force increased after TNFα treatment with an ~50% increase in maximum ASM force. The [Ca2+]cyt response induced by the EC50 [ACh] was similar in control and TNFα treated ASM. Thus, with an increase in force and no effect on [Ca2+]cyt, there was an apparent increase in Ca2+ sensitivity of force after TNFα treatment. However, in both control and TNFα treated ASM, the extent of rMLC phosphorylation induced by ACh stimulation was not affected by TNFα treatment. Importantly, the extent of rMLC phosphorylation at the ACh EC50 was comparable between control and TNFα treatment indicating no change in Ca2+ sensitivity. The expression of non‐muscle rMLC (determined by 2D gel electrophoresis) was also unaffected by TNFα treatment. Total actin and MyHC concentrations increased by ~45% following TNFα treatment; thus, the number of contractile units contributing to force increased. This was reflected by a marked increase in the Ca2+ activation of ATP consumption (cross‐bridge cycling) of ASM following TNFα treatment. Cytoskeletal remodeling was evaluated by ACh‐induced actin polymerization (F‐/G‐actin ratio) but was found to be unaffected by TNFa treatment. Together, our results show that two primary mechanisms underlie the marked increase in ASM force generation induced by 24‐h TNFα exposure: 1) an increase in ACh sensitivity, and 2) an increase in actin and MyHC concentrations (number of contractile units).Support or Funding InformationSupported by NIH grant HL126451 (GCS) and HL150890 (GCS)