Hypoxia sensing through β-adrenergic receptors
Hoi I. Cheong, Kewal Asosingh, Olivia R. Stephens, Kimberly A. Queisser, Weiling Xu, Belinda Willard, Bo Hu, Josephine Kam Tai Dermawan, George R. Stark, Sathyamangla V. Naga Prasad, Serpil C. Erzurum
Hoi I. Cheong, Kewal Asosingh, Olivia R. Stephens, Kimberly A. Queisser, Weiling Xu, Belinda Willard, Bo Hu, Josephine Kam Tai Dermawan, George R. Stark, Sathyamangla V. Naga Prasad, Serpil C. Erzurum
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Research Article Vascular biology

Hypoxia sensing through β-adrenergic receptors

Abstract

Life-sustaining responses to low oxygen, or hypoxia, depend on signal transduction by HIFs, but the underlying mechanisms by which cells sense hypoxia are not completely understood. Based on prior studies suggesting a link between the β-adrenergic receptor (β-AR) and hypoxia responses, we hypothesized that the β-AR mediates hypoxia sensing and is necessary for HIF-1α accumulation. Beta blocker treatment of mice suppressed hypoxia induction of renal HIF-1α accumulation, erythropoietin production, and erythropoiesis in vivo. Likewise, beta blocker treatment of primary human endothelial cells in vitro decreased hypoxia-mediated HIF-1α accumulation and binding to target genes and the downstream hypoxia-inducible gene expression. In mechanistic studies, cAMP-activated PKA and/or GPCR kinases (GRK), which both participate in β-AR signal transduction, were investigated. Direct activation of cAMP/PKA pathways did not induce HIF-1α accumulation, and inhibition of PKA did not blunt HIF-1α induction by hypoxia. In contrast, pharmacological inhibition of GRK, or expression of a GRK phosphorylation–deficient β-AR mutant in cells, blocked hypoxia-mediated HIF-1α accumulation. Mass spectrometry–based quantitative analyses revealed a hypoxia-mediated β-AR phosphorylation barcode that was different from the classical agonist phosphorylation barcode. These findings indicate that the β-AR is fundamental to the molecular and physiological responses to hypoxia.

Authors

Hoi I. Cheong, Kewal Asosingh, Olivia R. Stephens, Kimberly A. Queisser, Weiling Xu, Belinda Willard, Bo Hu, Josephine Kam Tai Dermawan, George R. Stark, Sathyamangla V. Naga Prasad, Serpil C. Erzurum

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Figure 2

Beta blocker attenuates hypoxia responses in vitro.

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Beta blocker attenuates hypoxia responses in vitro. (A) Expression of HI...
(A) Expression of HIF-1α and Lamin B in HUVECs treated with escalating doses of propranolol, followed by 5-hour hypoxia (2% oxygen) (n = 2–7/condition). Data are mean ± SEM. *P < 0.05, Student’s t test. (B) HIF-1α occupancy at target genes in HUVECs treated with diluent or propranolol, followed by 12-hour hypoxia. ChIP with control IgG or HIF-1α antibody and quantification of promoter regions of CXCL12, HK2, and VEGFA by quantitative PCR. Fold enrichment was percentage of input (hypoxia with or without beta blocker) divided by average percentage of input (normoxia) (n = 3). *P < 0.05, ANOVA. (C) Heatmap showing the levels of differentially expressed transcripts of HUVECs treated with diluent (–) or propranolol (+), followed by 24-hour hypoxia. The levels of expression relative to normoxia are represented on a continuous scale from blue (lowest) to pink (highest) (n = 5 biological replicates). FDR = 0.05. (D) Kyoto Encyclopedia of Genes and Genomes pathway analysis of transcripts reversed by propranolol under hypoxia in HUVECs. Enrichment score is computed by –log (P value).