The contribution of blockade of adenosine A1 and A2A receptor to the psychostimulant effects of caffeine is still a matter of debate. When analyzing motor activity in rats, acutely administered caffeine shows a profile of a non-selective adenosine receptor antagonist, although with preferential A1 receptor antagonism. On the other hand, tolerance to the effects of A1 receptor blockade seems to be mostly responsible for the tolerance to the motor-activating effects of caffeine, while the residual motor-activating effects of caffeine in tolerant individuals seem to involve A2A receptor blockade. These behavioral studies correlate with in vivo microdialysis experiments that suggest that A1 receptor-mediated modulation of striatal glutamate release is involved in the psychostimulant effects of caffeine. Experiments in transfected cells demonstrate the ability of A1 receptors to heteromerize with A2A receptors and the A1-A2A receptor heteromer can be biochemically identified in the striatum, in striatal glutamatergic terminals. The striatal A1-A2A receptor heteromer provides a "concentration-dependent switch" mechanism by which low and high concentrations of synaptic adenosine produce the opposite effects on glutamate release. The analysis of the function of A1-A2A receptor heteromers during chronic treatment with caffeine gives new clues about the well-known phenomenon of tolerance to the psychostimulant effects of caffeine.
Chronic exposure of A(1) adenosine receptors (A(1)R) to A(1)R agonists leads to activation, phosphorylation, desensitization, and internalization to intracellular compartments of the receptor. Desensitization and internalization of A(1)R is modulated by adenosine deaminase (ADA), an enzyme that regulates the extracellular concentration of adenosine. ADA interacts with A(1)R on the cell surface of the smooth muscle cell line DDT1 MF-2, and both proteins are internalized following agonist stimulation of the receptor. The mechanism involved in A(1)R and ADA internalization upon agonist exposure is poorly understood in epithelial cells. In this report, we show that A(1)R and ADA interact in LLC-PK(1) epithelial cells. Exposure of LLC-PK(1) cells to A(1)R agonists induces aggregation of A(1)R and ADA on the cell surface and their translocation to intracellular compartments. Biochemical and cell biology assays were used to characterize the intracellular vesicles containing both proteins after agonist treatment. A(1)R and ADA colocalized together with the rafts marker protein caveolin. Filipin, a sterol-binding agent that disrupts rafts (small microdomains of the plasma membrane), was able to inhibit A(1)R internalization. In contrast, acid treatment of the cells, which disrupts internalization via clathrin-coated vesicles, did not inhibit agonist-stimulated A(1)R internalization. We demonstrated that A(1)R agonist N(6)-(R)-phenylisopropyl adenosine promotes the translocation of A(1)R into low-density gradient fractions containing caveolin. Furthermore, a direct interaction of the C-terminal domain of A(1)R with caveolin-1 was demonstrated by pull down experiments. These results indicate that A(1)R and ADA form a stable complex in the cell surface of LLC-PK(1) cells and that agonist-induced internalization of the A(1) adenosine receptor and ADA is mediated by clathrin-independent endocytosis.
The effect of nitrobenzylthioinosine (NBTI) on [3H]adenosine uptake and the characterization of the [3H]NBTI binding in cell (primary cultures and LLC-PK1 cell line) plasma membrane and brush-border membrane (BBM) vesicles from pig renal cortices and LLC-PK1 cells was analyzed. [3H]adenosine uptake was strongly inhibited by NBTI in nonconfluent cells, whereas it was totally insensitive to the reagent in BBM. The concentration dependence of [3H]adenosine uptake in BBM was linear, suggesting simple diffusion. In both cell membranes and BBM high-affinity [3H]NBTI binding was observed. [3H]NBTI binding as well as NBTI-sensitive [3H]adenosine uptake was strongly reduced when cells grew to confluence. Both reduction effects were reproduced by treatment of nonconfluent cells with chlorophenyl adenosine 3',5'-cyclic monophosphate (cAMP), which indicates that the transporter is regulated by a cAMP-dependent protein kinase. To confirm this hypothesis, the binding of [3H]NBTI was analyzed in pig kidney BBM obtained in the presence of orthovanadate and alkaline phosphatase. With respect to control membranes, BBM obtained in the presence of orthovanadate showed a lower maximum number of binding sites (Bmax), whereas those obtained in the presence of alkaline phosphatase showed a slight increase in Bmax for [3H]NBTI binding. Taken together, these results suggest that the reduction in both [3H]NBTI-binding capacity and NBTI-sensitive [3H]adenosine uptake takes place by a mechanism that involves phosphorylation of the transporter molecule or of a protein that interacts with it.
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