Background: RGS21 is expressed in tastant-responsive lingual epithelium, but with unknown function. Results: RGS21 accelerated intrinsic GTPase activity of multiple G␣ subunits; RGS21 over-and underexpression in epithelial cells modulated bitterant responsiveness. Conclusion: RGS21 is a negative regulator of bitterant signal transduction. Significance: RGS21 represents a nonreceptor regulatory component of gustatory signaling that alters sensitivity of bitterant responsiveness in an endogenous, cellular context.
Chemical signaling plays an important role in predator–prey interactions and feeding dynamics. Like other organisms that are sessile or slow moving, some marine sponges contain aversive compounds that defend these organisms from predation. We sought to identify and characterize a fish chemoreceptor that detects one of these compounds. Using expression cloning in Xenopus oocytes coexpressing the cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel, the beta-2 adrenergic receptor (β 2 AR), and fractions of a zebrafish cDNA library, we isolated a cDNA clone encoding receptor activity–modifying protein (RAMP)-like triterpene glycoside receptor (RL-TGR), a novel coreceptor involved in signaling in response to triterpene glycosides. This coreceptor appears to be structurally and functionally related to RAMPs, a family of coreceptors that physically associate with and modify the activity of G protein–coupled receptors (GPCRs). In membranes from formoside-responsive oocytes, RL-TGR was immunoprecipitated in an apparent complex with β 2 AR. In HEK293 cells, coexpression of β 2 AR induced the trafficking of RL-TGR from the cytoplasm to the plasma membrane. These results suggest that RL-TGR in the predatory fish physically associates with the β 2 AR or another, more physiologically relevant GPCR and modifies its pharmacology to respond to triterpene glycosides found in sponges that serve as a potential food source for the fish. RL-TGR forms a coreceptor that responds to a chemical defense compound in the marine environment, and its discovery might lead the way to the identification of other receptors that mediate chemical defense signaling.
Objectives/Hypothesis: Motile cilia of airway epithelial cells help to expel harmful inhaled material. Activation of bitterant-responsive G protein-coupled receptors (GPCRs) is believed to potentiate cilia beat frequency and mucociliary clearance. In this study, we investigated whether regulator of G protein signaling-21 (RGS21) has the potential to modulate signaling pathways connected to airway mucociliary clearance, given that RGS proteins modulate GPCR signaling by acting as GTPase-accelerating proteins (GAPs) for the Gα subunits of heterotrimeric G proteins. Study Design: This is a pilot investigation to determine if RGS21, a potential tastant specific RGS gene, is expressed in sinonasal mucosa, and to determine its specific Gα substrate using in vitro biochemical assays with purified proteins. Methods: Rgs21 expression in sinonasal mucosa was determined using quantitative, real-time PCR and a transgenic mouse expressing RFP from the Rgs21 promoter. Rgs21 was cloned, over-expressed, and purified using multistep protein chromatography. Biochemical and biophysical assays were used to determine if RGS21 could bind and accelerate the hydrolysis of GTP on heterotrimeric Gα subunits. Results: Rgs21 was expressed in sinonasal mucosa and lingual epithelium. Purified recombinant protein directly bound and accelerated GTP hydrolysis on Gα subunits. Conclusions: Rgs21 is expressed in sinonasal mucosa, is amenable to purification as a recombinant protein, and can bind to Gαi/o/q subunits. Furthermore, RGS21 can accelerate the hydrolysis rate of GTP on Gαi subunits. This provides evidence that RGS21 may be a negative regulator of bitterant responses. Future studies will be needed to determine the physiological role of this protein in mucociliary clearance.
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