Epithelial Gpr116 regulates pulmonary alveolar homeostasis via Gq/11 signaling
Kari Brown, Alyssa Filuta, Marie-Gabrielle Ludwig, Klaus Seuwen, Julian Jaros, Solange Vidal, Kavisha Arora, Anjaparavanda P. Naren, Kathirvel Kandasamy, Kaushik Parthasarathi, Stefan Offermanns, Robert J. Mason, William E. Miller, Jeffrey A. Whitsett, James P. Bridges
Kari Brown, Alyssa Filuta, Marie-Gabrielle Ludwig, Klaus Seuwen, Julian Jaros, Solange Vidal, Kavisha Arora, Anjaparavanda P. Naren, Kathirvel Kandasamy, Kaushik Parthasarathi, Stefan Offermanns, Robert J. Mason, William E. Miller, Jeffrey A. Whitsett, James P. Bridges
View: Text | PDF
Research Article Cell biology Pulmonology

Epithelial Gpr116 regulates pulmonary alveolar homeostasis via Gq/11 signaling

Abstract

Pulmonary function is dependent upon the precise regulation of alveolar surfactant. Alterations in pulmonary surfactant concentrations or function impair ventilation and cause tissue injury. Identification of the molecular pathways that sense and regulate endogenous alveolar surfactant concentrations, coupled with the ability to pharmacologically modulate them both positively and negatively, would be a major therapeutic advance for patients with acute and chronic lung diseases caused by disruption of surfactant homeostasis. The orphan adhesion GPCR GPR116 (also known as Adgrf5) is a critical regulator of alveolar surfactant concentrations. Here, we show that human and mouse GPR116 control surfactant secretion and reuptake in alveolar type II (AT2) cells by regulating guanine nucleotide–binding domain α q and 11 (Gq/11) signaling. Synthetic peptides derived from the ectodomain of GPR116 activated Gq/11-dependent inositol phosphate conversion, calcium mobilization, and cortical F-actin stabilization to inhibit surfactant secretion. AT2 cell–specific deletion of Gnaq and Gna11 phenocopied the accumulation of surfactant observed in Gpr116–/– mice. These data provide proof of concept that GPR116 is a plausible therapeutic target to modulate endogenous alveolar surfactant pools to treat pulmonary diseases associated with surfactant dysfunction.

Authors

Kari Brown, Alyssa Filuta, Marie-Gabrielle Ludwig, Klaus Seuwen, Julian Jaros, Solange Vidal, Kavisha Arora, Anjaparavanda P. Naren, Kathirvel Kandasamy, Kaushik Parthasarathi, Stefan Offermanns, Robert J. Mason, William E. Miller, Jeffrey A. Whitsett, James P. Bridges

×

Figure 3

Peptide-induced activation of GPR116.

Options: View larger image (or click on image) Download as PowerPoint
Peptide-induced activation of GPR116. (A) Model of the full-length GPR11...
(A) Model of the full-length GPR116 protein with the GAP16 peptide corresponding to the amino acids of the CTF ectodomain and scrambled (SCR) peptide sequence. (B) Membrane localization of transfected V5-tagged GPR116 in HEK cells (inset, green = V5-tagged GPR116, blue = DAPI-stained nuclei; original magnification, ×60) and IP conversion assays. GAP16 treatment resulted in dose-dependent IP conversion that was inhibited by cotreatment with the Gq inhibitor YM-254890 (100 nM) (n = 3 independent experiments, 2 biological replicates per group). (C) Representative calcium transient traces of GAP16-stimulated GPR116-V5 stably transfected HEK cells. Ionomycin was added as a positive control; overlaying control lines in black include SCR peptide (50 μM, 100 μM, and 250 μM) and vehicle (n = 3 independent experiments, 3 biological replicates per group). (D) Quantification of calcium transient data (n = 4 independent experiments, 3 biological replicates per group). (E) Calcium transients of GAP16-stimulated (250 μM), GPR116-V5 stably transfected HEK cells pretreated with the Gq inhibitor YM-254890 (YM) 2 hours prior to stimulation (n = 3 independent experiments, 2 biological replicates per group). Data are expressed as mean ± SD. **P < 0.01, ***P < 0.001, ****P < 0.0001 (1-way ANOVA for B and D).