The citric acid cycle is central to the regulation of energy homeostasis and cell metabolism 1 . Mutations in enzymes that catalyse steps in the citric acid cycle result in human diseases with various clinical presentations 2 . The intermediates of the citric acid cycle are present at micromolar concentration in blood and are regulated by respiration, metabolism and renal reabsorption/ extrusion. Here we show that GPR91 (ref.3), a previously orphan G-protein-coupled receptor (GPCR), functions as a receptor for the citric acid cycle intermediate succinate. We also report that GPR99 (ref. 4), a close relative of GPR91, responds to a-ketoglutarate, another intermediate in the citric acid cycle. Thus by acting as ligands for GPCRs, succinate and a-ketoglutarate are found to have unexpected signalling functions beyond their traditional roles. Furthermore, we show that succinate increases blood pressure in animals. The succinate-induced hypertensive effect involves the renin-angiotensin system and is abolished in GPR91-deficient mice. Our results indicate a possible role for GPR91 in renovascular hypertension, a disease closely linked to atherosclerosis, diabetes and renal failure 5,6 .In a search for natural ligands for orphan GPCRs, we tested extracts from various animal tissues for their ability to evoke an increase in intracellular Ca 2þ concentration ([Ca 2þ ] i ) using the aequorin assay 7 . We found that fractions from pig kidney extracts specifically activated cells expressing GPR91 (Fig. 1a). GPR91 is an orphan GPCR highly expressed in the kidney and shares 33% amino acid identity with GPR99/GPR80 (refs 4, 8). On the basis of their homology with the purinergic receptor P2Y1, nucleotide ligands were predicted for GPR91 and GPR99 (ref. 4). However, the GPR91 ligand activity in pig kidney extracts was resistant to various stringent treatments including alkaline phosphatase, peptidase, and hydrolysis in 6 M HCl at 100 8C. Accordingly, the supposition that GPR91 might be activated by a nucleotide or peptide ligand was unlikely. We purified the natural ligand for GPR91 by ion-exchange, size-exclusion and reversed-phase fast performance liquid chromatography/high-performance liquid chromatography (Fig. 1a).A major molecular ion [M þ H] þ at m/z 119.2 was observed by mass spectrometry (Fig. 1b). 1 H NMR analysis revealed a single type of proton in the highly purified GPR91 ligand (Fig. 1c). 13 C NMR analysis further suggested the presence of -CH 2 -(methylene) and ¼C¼O (carbonyl) groups (Fig. 1d). Combined with mass spectrometry results and the biochemical properties of the ligand, the purified GPR91 ligand was predicted and confirmed to be succinic acid (Fig. 1c, d).Commercially obtained succinate (the physiological form of succinic acid) increased [Ca 2þ ] i dose-dependently in the aequorin assay (Fig. 2a). Succinate also activated mouse and rat orthologues of GPR91 (Fig. 2a). The succinate-induced increase in [Ca 2þ ] i was further confirmed with a fluorimetric imaging plate reader (FLIPR) system in the 293-hGP...
Signaling through its widely distributed cell surface receptor, interleukin (IL)-17 enhances the transcription of genes encoding proinflammatory molecules. Although it has been well documented that IL-17 activates the transcription factor nuclear factor (NF)-κB and c-Jun NH2-terminal kinase (JNK), the upstream signaling events are largely unknown. Here we report the requirement of tumor necrosis factor receptor–associated factor (TRAF)6 in IL-17–induced NF-κB and JNK activation. In embryonic fibroblasts (EFs) derived from TRAF6 knockout mice, IL-17 failed to activate the IκB kinases (IKKs) and JNK. Consequently, IL-17–induced IL-6 and intercellular adhesion molecule 1 expression in the TRAF6-deficient cells was abolished. Lack of TRAF6 appeared to be the sole defect responsible for the observed failure to respond to IL-17, because transient transfection of TRAF6 expression plasmid into the TRAF6-deficient cells restored IL-17–induced NF-κB activation in a luciferase reporter assay. Furthermore, the levels of IL-17 receptor (IL-17R) on the TRAF6-deficient EFs were comparable to those on the wild-type control cells. Defect in IL-17 response was not observed in TRAF2-deficient EFs. Moreover, when TRAF6 and IL-17R were coexpressed in 293 cells, TRAF6 coimmunoprecipitated with IL-17R. Together, these results indicate that TRAF6, but not TRAF2, is a crucial component in the IL-17 signaling pathway leading to proinflammatory responses.
FFA2 (GPR43) has been identified as a receptor for short-chain fatty acids (SCFAs) that include acetate and propionate. FFA2 is highly expressed in islets, a subset of immune cells, and adipocytes. Although the potential roles of FFA2 activation in these tissues have previously been described, the physiological functions are still unclear. The potency for SCFAs on FFA2 is low, in the high micromolar to millimolar concentrations. To identify better pharmacological tools to study receptor function, we used high-throughput screening (HTS) to discover a series of small molecule phenylacetamides as novel and more potent FFA2 agonists. This series is specific for FFA2 over FFA1 (GPR40) and FFA3 (GPR41), and it is able to activate both the G␣ q and G␣ i pathways in vitro on Chinese hamster ovary cells stably expressing FFA2. Treatment of adipocytes with these compounds also resulted in G␣ i -dependent inhibition of lipolysis similar to that of endogenous ligands (SCFAs). It is noteworthy that these compounds not only acted as FFA2 agonists but also exhibited positive cooperativity with acetate or propionate. The observed allosteric modulation was consistent in all the functional assays that we have explored, including cAMP, calcium mobilization, guanosine 5Ј-[␥-thio]triphosphate binding, and lipolysis. Molecular modeling analysis of FFA2 based on human  2 -adrenergic receptor structure revealed potential nonoverlapping binding sites for the endogenous and synthetic ligands, further providing insight into the binding pocket for the allosteric interactions. This is the first report describing the identification of novel allosteric modulators with agonist activity for FFA2, and these compounds may serve as tools for further unraveling the physiological functions of the receptor and its involvement in various diseases.
The 55-kDa receptor for tumor necrosis factor (TR55) triggers multiple signaling cascades initiated by adapter proteins like TRADD and FAN. By use of the primary amine monodansylcadaverine (MDC), we addressed the functional role of tumor necrosis factor (TNF) receptor internalization for intracellular signal distribution. We show that MDC does not prevent the interaction of the p55 TNF receptor (TR55) with FAN and TRADD. Furthermore, the activation of plasmamembrane-associated neutral sphingomyelinase activation as well as the stimulation of proline-directed protein kinases were not affected in MDC-treated cells. In contrast, activation of signaling enzymes that are linked to the "death domain" of TR55, like acid sphingomyelinase and c-Jun-N-terminal protein kinase as well as TNF signaling of apoptosis in U937 and L929 cells, are blocked in the presence of MDC. The results of our study suggest a role of TR55 internalization for the activation of select TR55 death domain signaling pathways including those leading to apoptosis.Tumor necrosis factor (TNF), 1 originally defined by its antitumoral activity, is now recognized as a pleiotropic cytokine exerting a wide variety of immunoregulatory activities (for review, see Refs. 1-3). TNF action is mediated by two types of cell surface receptors of 55 kDa (TR55) and 75 kDa (TR75) molecular masses, respectively. Both receptors mediate distinct TNF responses (4 -6). The majority of activities of soluble TNF appears to be mediated by TR55 (7-11). Like other cytokine receptors, the cytoplasmic domain of both TNF receptors lacks intrinsic enzymatic activities. The activation of intracellular signaling enzyme systems is initiated by a selective interplay between the cytoplasmic domain of the TNF receptors and a number of recently identified TNF receptor-associated proteins (see Ref. Results from numerous studies have revealed that TNF signaling further involves activation of downstream enzyme systems at multiple subcellular compartments such as the plasmamembrane, endosomes, mitochondria, the cytosol, and the nucleus (for review, see Refs. 11, 23, and 24). Membrane-associated enzyme systems transmitting TR55 signals include plasmamembrane-bound phospholipases such as phosphatidylcholine-specific phospholipase C (25), which generates the lipid second messenger molecule 1,2-diacylglycerol and a N-SMase (9), producing ceramide by sphingomyelin hydrolysis. Ceramide generated at the plasmamembrane triggers activation of a 97-kDa ceramide-activated protein kinase (26), recently suggested to be identical with the "kinase suppressor of ras" (27). Ceramide-activated protein kinase belongs to a family of proline-directed protein kinases (PDPK) (9), including members of the mitogen-activated protein kinases (28). TNF signaling further involves intracellular membrane compartments like caveolae and endosomes harboring an acid SMase (A-SMase) (9,29,30). In mitochondria, TNF induces reactive oxygen species that are generated at the level of the oxidative phosphorylation complex III (31). T...
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