| First Author | Cully TR | Year | 2020 |
| Journal | Redox Biol | Volume | 36 |
| Pages | 101557 | PubMed ID | 32506037 |
| Mgi Jnum | J:312808 | Mgi Id | MGI:6791974 |
| Doi | 10.1016/j.redox.2020.101557 | Citation | Cully TR, et al. (2020) Nox4 - RyR1 - Nox2: Regulators of micro-domain signaling in skeletal muscle. Redox Biol 36:101557 |
| abstractText | The ability for skeletal muscle to perform optimally can be affected by the regulation of Ca(2+) within the triadic junctional space at rest. Reactive oxygen species impact muscle performance due to changes in oxidative stress, damage and redox regulation of signaling cascades. The interplay between ROS and Ca(2+) signaling at the triad of skeletal muscle is therefore important to understand as it can impact the performance of healthy and diseased muscle. Here, we aimed to examine how changes in Ca(2+) and redox signaling within the junctional space micro-domain of the mouse skeletal muscle fibre alters the homeostasis of these complexes. The dystrophic mdx mouse model displays increased RyR1 Ca(2+) leak and increased NAD(P)H Oxidase 2 ROS. These alterations make the mdx mouse an ideal model for understanding how ROS and Ca(2+) handling impact each other. We hypothesised that elevated t-tubular Nox2 ROS increases RyR1 Ca(2+) leak contributing to an increase in cytoplasmic Ca(2+), which could then initiate protein degradation and impaired cellular functions such as autophagy and ER stress. We found that inhibiting Nox2 ROS did not decrease RyR1 Ca(2+) leak observed in dystrophin-deficient skeletal muscle. Intriguingly, another NAD(P)H isoform, Nox4, is upregulated in mice unable to produce Nox2 ROS and when inhibited reduced RyR1 Ca(2+) leak. Our findings support a model in which Nox4 ROS induces RyR1 Ca(2+) leak and the increased junctional space [Ca(2+)] exacerbates Nox2 ROS; with the cumulative effect of disruption of downstream cellular processes that would ultimately contribute to reduced muscle or cellular performance. |
