Uncovering the functional role of GPR39 in the renal collecting duct

Abstract

G protein-coupled receptors (GPCRs) are seven transmembrane domain receptors that comprise the largest class of proteins in the mammalian genome. GPR39 is part of the ghrelin subfamily of GPCRs, and is well-expressed in the kidney but has no reported function in renal physiology. To probe the renal role of GPR39, we first sought to localize it; in the absence of a validated immunofluorescence (IF) antibody, we used RNAscope. We found that Gpr39 localizes to nephron segments in the cortex and medulla which are positive for DBA (Dolichos Biflorus Agglutinin), a collecting duct marker. RNAScope expression of Gpr39 was highest in the inner medullary collecting duct, with lower levels in the outer medullary and cortical collecting ducts. Within the collecting duct, Gpr39 transcripts colocalized with Aqp2, indicating that Gpr39 is expressed specifically in principal cells. To address whether GPR39 is apical or basolateral, we cloned murine Gpr39 with a C-terminal EGFP tag and transiently transfected this construct into either polarized M-1 cells (murine collecting duct cell line) or polarized MDCK cells (Madin-Darby canine kidney cells); in both cases, cells were grown to confluence on permeable supports. In both cell lines, heterologous GPR39 trafficked to the basolateral membrane. Based on the localization of GPR39 to principal cells, we hypothesized that GPR39 activation may alter AQP2 expression or trafficking. To test this hypothesis in vitro, we first validated mpkCCD (mouse principal cell kidney cortical collecting duct) cells as a model. We cultured mpkCCD on transwells until polarized (TER >5kΩ·cm 2 ). In the absence of dDAVP, mpkCCD do not express AQP2 by western or IF. Basolateral treatment with 1nM dDAVP for 4 days induced AQP2 expression (western blot) and apical trafficking (confocal IF). We also confirmed that withdrawal of dDAVP (4h) resulted in a cytosolic accumulation of AQP2, while the re-introduction of dDAVP (1h) returned AQP2 to the apical membrane by IF. Moreover, we found that Gpr39 expression was unaffected by dDAVP by qPCR (n=3, ΔCt ± SEM: control = 7.9±0.3, dDAVP = 7.2±0.1) and western blot. In a preliminary study, we treated mpkCCD with 13nM of a GPR39 selective agonist, cpd1324, or with a vehicle control, and probed for changes in AQP2 by IF. Both groups were treated with 1nM dDAVP and with 10μM ZnCl2 (a GPR39 cofactor). We found that cpd1324 treatment decreased AQP2 by IF (mean integrated fluorescence density ± SEM (A.U.): cpd1324 = 233.5 ± 20.8, control = 373.8 ± 13.0). Additionally, cpd1324 treatment reduced the apical AQP2 abundance (mean integrated fluorescence density ± SEM (A.U.) of the most apical Z-slice: cpd1324 = 6.05e+05 ± 3.9e+04, control = 2.6e+06 ± 4.3e+05). These results suggest that GPR39 agonism may antagonize vasopressin-induced AQP2 trafficking and/or expression. NIH T32HL007534 This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.