Abstract

G protein‐coupled receptors (GPCRs) in the kidney regulate the reabsorption of essential nutrients, ions, and water from the glomerular filtrate. Abnormality in the renal luminal sodium transport plays an important role in the pathogenesis of essential hypertension. There are a growing number of GPCRs and their interacting protein components that are localized on the nuclear membrane or within the nucleus, where they retain their signaling functions. In most cases, nuclear GPCRs are constitutively expressed on the nuclear membrane. The functions of these nuclear GPCRs are not well understood. Recently we showed that G protein‐coupled receptor 37L1 (GPR37L1), expressed on the apical membrane of renal proximal tubules (RPT), regulates luminal sodium transport and blood pressure via modulating NHE3 function. However, the GPR37L1 signaling pathway in the RPT has not been studied. Co‐immunoprecipitation (Co‐IP), combined with mass spectrometry analyses, revealed the association of GPR37L1 with nuclear import proteins: IPO7, IPO8, KPNA2, KPNB1; nuclear export proteins: XPO1 and XPO7; nuclear pore complex proteins: NUP210; kinases involved in signaling: mTOR, PRKDC, IRS4; and a DNA (Cytosine‐5‐)‐Methyltransferase 1 (DNMT1) in the GPR37L1 protein complex. Immunoblot analyses of nuclear preparations from the human RPT cells (hRPTCs) confirmed the presence of GPR37L1 in the nucleus. Confocal fluorescence imaging of hRPTCs expressing GPR37L1 tagged with green fluorescence protein (GPR37L1‐GFP) showed distinct nuclear membrane expression of GPR37L1. Association of GPR37L1 with mTOR, PRKDC, and DNMT1 proteins was confirmed by Co‐IP followed by immunoblot analyses. Overexpression of GPR37L1 in hRPTCs increased the phosphorylation of PI3, and AKT and decreased the expression of DNMT1, and NHE3 promoter methylation. Our data show that GPR37L1 signals via the PI3K/AKT/mTOR pathway to decrease the expression of DNMT1. Decreased DNMT1 function reduces CpG methylation on the NHE3 promoter that in turn increases NHE3 transcription. This is the first report showing the direct role of a nuclear GPCR in the regulation of renal sodium transport through epigenetic gene regulation.Support or Funding InformationR56DK116828: Prasad Konkalmatt

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