Novel Nongenomic Signaling by Glucocorticoid May Involve Changes to Liver Membrane Order in Rainbow Trout
L Dindia, J Murray, Erin Faught, T Davis, Zoya Leonenko, M Vijayan

TL;DR
This study shows that stress levels of cortisol rapidly fluidize rainbow trout liver membranes, modulating cell signaling pathways independently of genomic effects, indicating a novel nongenomic mechanism of glucocorticoid action.
Contribution
It reveals a new rapid, nongenomic pathway where cortisol alters membrane fluidity to influence cell signaling in fish liver cells.
Findings
Cortisol rapidly fluidizes trout liver membranes in vitro.
Cortisol modulates phosphorylation of key signaling proteins within 10 minutes.
Membrane fluidization by cortisol is specific and not caused by sex steroids.
Abstract
Stress-induced glucocorticoid elevation is a highly conserved response among vertebrates. This facilitates stress adaptation and the mode of action involves activation of the intracellular glucocorticoid receptor leading to the modulation of target gene expression. However, this genomic effect is slow acting and, therefore, a role for glucocorticoid in the rapid response to stress is unclear. Here we show that stress levels of cortisol, the primary glucocorticoid in teleosts, rapidly fluidizes rainbow trout (Oncorhynchus mykiss) liver plasma membranes in vitro. This involved incorporation of the steroid into the lipid domains, as cortisol coupled to a membrane impermeable peptide moiety, did not affect membrane order. Studies confirmed that cortisol, but not sex steroids, increases liver plasma membrane fluidity. Atomic force microscopy revealed cortisol mediated changes to membrane…
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Taxonomy
TopicsPhysiological and biochemical adaptations · Aquaculture disease management and microbiota · Stress Responses and Cortisol
