Post-translational modifications of thromboxane receptor G-protein alpha q complex in hypoxic PPHN
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Date
2014-01, 2014-01
Authors
Sikarwar, Anurag Singh
Journal Title
Journal ISSN
Volume Title
Publisher
American Thoracic Society
John Wiley and Sons, Inc
John Wiley and Sons, Inc
Abstract
Introduction: Persistent pulmonary hypertension of the newborn (PPHN) is associated with an elevated thromboxane to prostacyclin ratio, pulmonary artery (PA) hyperreactivity and hypersensitivity. Thromboxane receptor (TP), coupling with G-protein Gαq causes pulmonary vasoconstriction; whereas prostacyclin receptor (IP), coupling with Gαs, causes vasodilation and TP phosphorylation via adenylyl cyclase (AC)-cAMP-protein kinase A (PKA), desensitizes TP. Both TP phosphorylation and Gαq palmitoylation play major roles in regulation of signaling through the TP-Gαq complex. We hypothesized that increased Gαq palmitoylation and decreased AC activity could cause hypoxic TP hyperresponsiveness. We studied the impact of hypoxia on selected post-translational modifications of the receptor-G-protein complex, determining TP vasoconstriction: Gαq palmitoylation, TP phosphorylation and upstream AC activity.
Methods: Force responses to thromboxane mimetic U46619, palmitoylation inhibition by 2-bromopalmitate (2-BP) and AC activation (forskolin) were studied by myography in hypoxic PPHN and control newborn swine pulmonary artery. Ca2+ mobilization was studied by fluorescent calcium indicators fura-2AM in pulmonary myocytes (PASMC), and fluo-4NW in HEK293 cells. Effects of hypoxia on Gαq palmitoylation were studied by metabolic labeling. Gαq cysteines and TP serines were mutated to determine sites of post-translational modifications. Protein expression and receptor-G-protein coupling were studied by Western blot and co-immunoprecipitation. PKA activity was assayed; and AC activity quantified.
Results: Hypoxia increases Gαq palmitoylation, without increasing total palmitate uptake. Palmitoylation inhibition decreases U46619-stimulated force generation as well as Ca2+ mobilization in PPHN PA rings and hypoxic PASMC. Mutation of palmitoylable cysteine and palmitoylation inhibition proportionately decrease U46619-mediated Ca2+ mobilization in HEK293 cells. TP serine phosphorylation is decreased by hypoxia due to decreased PKA activity; this causes TP hypersensitivity and hyper-reactivity. Serine 324 of TPα is the target of PKA-mediated desensitization. AC activator-induced relaxation is reduced in PPHN PA. Basal and receptor-stimulated AC activity are decreased in hypoxic PASMC. Decreased AC activity is not due to decreased AC expression, ATP availability nor increased Gαi activation.
Conclusion: Increased Gαq palmitoylation plays a role in TPα hyper-responsiveness in hypoxic PPHN. Hypoxia also reduces responses to agents acting through AC, unleashing TP-mediated vasoconstriction. Reactivation of pulmonary AC might be useful therapeutically to promote vasodilation and TP desensitization.
Description
Keywords
PPHN, post-translational modifications
Citation
Sikarwar, A. S., et al. 2014 Palmitoylation of Galphaq determines its association with the thromboxane receptor in hypoxic pulmonary hypertension. Am J Respir Cell Mol Biol 50(1):135-43.
Santhosh, K. T., et al. 2014 Thromboxane receptor hyper-responsiveness in hypoxic pulmonary hypertension requires serine 324. Br J Pharmacol 171(3):676-87.
Santhosh, K. T., et al. 2014 Thromboxane receptor hyper-responsiveness in hypoxic pulmonary hypertension requires serine 324. Br J Pharmacol 171(3):676-87.