Identification and Characterization of a Cell-Surface Receptor, P2Y15, for AMP and Adenosine
AMP and adenosine are found in all cell types and can be released by cells or created extracellularly from the breakdown of ATP and ADP. We have identified an orphan G protein-coupled receptor with homology to the P2Y family of nucleotide receptors that can respond to both AMP and adenosine. Based on its ability to functionally bind the nucleotide AMP, we have named it P2Y15. Upon stimulation, P2Y15 induces both Ca 2؉ mobilization and cyclic AMP generation, suggesting coupling to at least two different G proteins. It is highly expressed in mast cells and is found predominantly in the tissues of the respiratory tract and kidneys, which are known to be affected by AMP, adenosine, and adenosine antagonists. Until now, the effects of AMP have been thought to depend on its dephosphorylation to adenosine but we demonstrate here that P2Y15 is a bona fide AMP receptor by showing that it binds [ 32 P]AMP. Because AMP and adenosine have bronchoconstrictive effects that can be inhibited by theophylline, we tested whether theophylline and other adenosine receptor antagonists can block P2Y15. We found inhibition at a theophylline concentration well within the therapeutic dose range, indicating that P2Y15 may be a clinically important target of this drug.Adenosine can mediate diverse physiological effects including bronchoconstriction, inhibition of platelet aggregation, inhibition of lipolysis, induction of sedation, vasodilation, suppression of cardiac rate and contractility, and stimulation of gluconeogenesis. To date, five cell-surface receptors have been identified for adenosine, namely adenosine receptors A1, A2A, A2B, and A3 (collectively referred to as P1 receptors) and the growth hormone secretagogue receptor (1, 2). AMP has a similarly diverse repertoire of effects (3-6) including bronchoconstriction, stimulation of DNA synthesis, mitogenesis, and stimulation of chloride secretion, but no receptor for AMP has previously been reported. Numerous cell types can release adenosine including mast cells (7), kidney brush border cells (8), and cardiac cells (9), whereas AMP can be released by such cell types as activated platelets (10), neutrophils (4), and eosinophils (11). AMP can also be generated extracellularly from the hydrolysis of ATP and ADP by ecto-ATPases (12) and ecto-ATP diphosphohydrolases (13) and can be further dephosphorylated by ecto-5Ј-nucleotidases to produce adenosine (14).
Ligation of the CD28 surface receptor provides a major costimulatory signal for full scale T cell activation. Despite extensive studies, the intracellular signaling pathways delivered by CD28 ligation are not fully understood. A particularly controversial matter is the role of phosphatidylinositol 3-kinase (PI3K) in CD28-mediated costimulation. It is known that the binding site for PI3K and Grb-2 lies nested within the YMNM motif of the CD28 cytoplasmic domain. To elucidate the role of PI3K during CD28-mediated interleukin-2 (IL-2) production, CD28 YMNM point and deletion mutants were expressed in Jurkat cells. We then measured IL-2 promoter activation after CD28 ligation. Our results showed that the Y189F mutant, which disrupts binding by PI3K, and the YMNM deletion mutant both demonstrated reduced but significant activity for IL-2 promoter activation. In contrast, the N191A mutant, which retains PI3K binding ability, resulted in a complete abrogation of activity, suggesting that PI3K mediates a negative effect upon transcriptional activation of the IL-2 gene. Consistent with this idea, we found that the addition of a PI3K pharmacological inhibitor augmented IL-2 promoter activity, whereas coexpression of a constitutively active form of PI3K reduced this activity. Taken together, these data indicate that PI3K, when associated with the YMNM motif, may act as a negative mediator in CD28-mediated IL-2 gene transcription.
The discoidin domain receptor (DDR1) is characterized by a discoidin I motif in the extracellular domain, an unusually long cytoplasmic juxtamembrane (JM) region, and a kinase domain that is 45% identical to that of the NGF receptor, TrkA. DDR1 also has a major splice form, which has a 37 amino acid insert in the JM region with a consensus Shc PTB site that is lacking in the shorter receptor. One class of ligands for the DDR receptors has recently been identified as being derived from the collagen family, but neither native PC12 cells, which express modest amounts of DDR1, nor transfected PC12 cells, which express much larger amounts of DDR1, respond to this ligand. A chimeric receptor, containing the extracellular domain of hPDGFRbeta fused to the transmembrane and intracellular regions of DDR1, also fails to mediate neuronal-like differentiation in stably transfected PC12 cells and is only weakly autophosphorylated. However, chimeric receptors, which are composed of combinations of intracellular regions from DDR1 and TrkA (with the extracellular domain of hPDGFRbeta), in some cases provided ligand (PDGF) -inducible receptor responses. Those with the TrkA kinase domain and the DDR1 JM regions were able to produce differentiation to varying degrees, whereas the opposite combination did not. Analysis of the signaling responses of the two chimeras with DDR1 JM sequences (with and without the insert) indicated that the shorter sequence bound and activated FRS2 whereas the insert-containing form activated Shc instead. Both activated PLCgamma through the carboxyl-terminal tyrosine of the TrkA domain (Y785 in TrkA residue numbering). Mutation of this site (Y-->F) eliminated PLCgamma activation (indicating there are no other cryptic binding sites for PLCgamma in the DDR1 sequences) and markedly reduced the differentiative activity of the receptor. This is in contrast to TrkA (or PDGFRbeta/TrkA chimeras), where ablation of this pathway has no notable effect on PC12 cell morphogenic responses. Thus, the activation of FRS2 and Shc (leading to MAPK activation) is weaker in the DDR1/TrkA chimeras than in TrkA alone, and the PLCgamma contribution becomes essential for full response. Nonetheless, both DDR1 JM regions contain potentially usable signaling sites, albeit they apparently are not activated directly in DDR1 (or DDR1 chimeras) in a ligand-dependent fashion. These findings suggest that the DDR1 receptors do have signaling capacity but may require additional components or altered conditions to fully activate their kinase domains and/or sustain the activation of the JM sites.
Due to the high incidence of mammary tumors in dogs, it is important to elucidate the pathogenesis of these tumors in veterinary medicine. Radiation therapy is often used to treat mammary tumors that target DNA lesions. RAD51 is a key molecule that repairs DNA damage via homologous recombination. We examined the relationship between RAD51 expression and radiosensitivity in mammary tumor cell lines. CHMp and CHMm from the same individual were selected based on the differences in RAD51 expression. The radiosensitivity of both cell lines was examined using MTT and scratch assays; CHMm, which has high RAD51 expression, showed higher sensitivity to radiation than CHMp. However, the nuclear focus of RAD51 during DNA repair was formed normally in CHMp, but not in most of CHMm. Since irradiation resulted in the suppression of cell cycle progression in CHMp, the expression of p21, a cell cycle regulatory factor, was detected in CHMp after 15 Gy irradiation but not in CHMm. These results indicate that functional expression is more important than the quantitative expression of RAD51 in canine mammary tumor cells in response to DNA damage.
Feline coronaviruses (FCoVs) infect cats worldwide and cause severe systemic diseases, such as feline infectious peritonitis (FIP). FIP has a high mortality rate, and drugs approved by the Food and Drug Administration have been ineffective for the treatment of FIP. Investigating host factors and the functions required for FCoV replication is necessary to develop effective drugs for the treatment of FIP. FCoV utilizes an endosomal trafficking system for cellular entry after binding between the viral spike (S) protein and its receptor. The cellular enzymes that cleave the S protein of FCoV to release the viral genome into the cytosol require an acidic pH optimized in the endosomes by regulating cellular ion concentrations. Ionophore antibiotics are compounds that form complexes with alkali ions to alter the endosomal pH conditions. This study shows that ionophore antibiotics, including valinomycin, salinomycin, and nigericin, inhibit FCoV proliferation in vitro in a dose-dependent manner. These results suggest that ionophore antibiotics should be investigated further as potential broad-spectrum anti-FCoV agents.
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