Agonist-occupied A3 adenosine receptors exist within heterogeneous complexes in membrane microdomains of individual living cells.

G protein-coupled receptors are known to be organized within different membrane compartments or microdomains of individual cells. Here, we have used a fluorescent A3 adenosine receptor (A3-AR) agonist, ABEA-X-BY630, and the technique of fluorescence correlation spectroscopy (FCS) to investigate the diffusional characteristics of functional agonist-occupied A3-AR complexes in single living cells. In Chinese hamster ovary cells expressing the human A3-AR, the fluorescent A3-AR agonist was able to inhibit forskolin-stimulated [3H]cAMP production (pEC50=8.57), and this was antagonized by the A3-selective antagonist MRS1220 (pK(B)=9.32). The fluorescent ligand also stimulated phosphoinositide hydrolysis (pEC50=7.34). Ligand binding to the A3-AR on the membranes of single cells and subsequent increases in single cell [Ca2+]i were monitored simultaneously in real time using confocal microscopy. FCS measurements in small-membrane microdomains (approximately 0.2 microm2) revealed two agonist-occupied A3-AR components with differing diffusion characteristics (diffusion coefficients=2.65x10(-8) and 1.19x10(-9) cm2/s, respectively). The binding of ligand to these two components was reduced from 5.1 and 14.9 to 2.6 and 3.3 receptors/microm2, respectively, by MRS1220 (100 nM). These data provide direct evidence for at least two populations of agonist-occupied A3-receptor complexes, showing different motilities within the membrane of single living cells.

Quantitative analysis of the formation and diffusion of A1-adenosine receptor-antagonist complexes in single living cells.

The A1-adenosine receptor (A1-AR) is a G protein-coupled receptor that mediates many of the physiological effects of adenosine in the brain, heart, kidney, and adipocytes. Currently, ligand interactions with the A1-AR can be quantified on large cell populations only by using radioligand binding. To increase the resolution of these measurements, we have designed and characterized a previously undescribed fluorescent antagonist for the A1-AR, XAC-BY630, based on xanthine amine congener (XAC). This compound has been used to quantify ligand-receptor binding at a single cell level using fluorescence correlation spectroscopy (FCS). XAC-BY630 was a competitive antagonist of A1-AR-mediated inhibition of cAMP accumulation [log10 of the affinity constant (pKb) = 6.7)] and stimulation of inositol phosphate accumulation (pKb = 6.5). Specific binding of XAC-BY630 to cell surface A1-AR could also be visualized in living Chinese hamster ovary (CHO)-A1 cells by using confocal microscopy. FCS analysis of XAC-BY630 binding to the membrane of CHO-A1 cells revealed three components with diffusion times (tauD) of 62 micros (tauD1, free ligand), 17 ms (tauD2, A1-AR-ligand), and 320 ms (tauD3). Confirmation that tauD2 resulted from diffusion of ligand-receptor complexes came from the similar diffusion time observed for the fluorescent A1-AR-Topaz fusion protein (15 ms). Quantification of tauD2 showed that the number of receptor-ligand complexes increased with increasing free ligand concentration and was decreased by the selective A1-AR antagonist, 8-cyclopentyl-1,3-dipropylxanthine. The combination of FCS with XAC-BY630 will be a powerful tool for the characterization of ligand-A1-AR interactions in single living cells in health and disease.

Influence of receptor number on functional responses elicited by agonists acting at the human adenosine A(1) receptor: evidence for signaling pathway-dependent changes in agonist potency and relative intrinsic activity.

Activation of A(1) adenosine receptors leads to the inhibition of cAMP accumulation and the stimulation of inositol phosphate accumulation via pertussis toxin-sensitive G-proteins. In this study we have investigated the signaling of the A(1) adenosine receptor in Chinese hamster ovary (CHO) cells, when expressed at approximately 203 fmol/mg (CHOA1L) and at approximately 3350 fmol/mg (CHOA1H). In CHOA1L cells, the agonists N(6)-cyclopentyladenosine (CPA), (R)-N(6)-(2-phenylisopropyl)adenosine, and 5'-(N-ethylcarboxamido)adenosine (NECA) inhibited cAMP production in a concentration-dependent manner. After pertussis toxin treatment, the agonist NECA produced a stimulation of cAMP production, whereas CPA and (R)-N(6)-(2-phenylisopropyl)adenosine were ineffective. In CHOAIH cells, however, all three agonists produced both an inhibition of adenylyl cyclase and a pertussis toxin-insensitive stimulation of adenylyl cyclase. All three agonists were more potent at inhibiting adenylyl cyclase in CHOA1H cells than in CHOA1L cells. In contrast, A(1) agonists (and particularly NECA) were less potent at stimulating inositol phosphate accumulation in CHOA1H cells than in CHOA1L cells. After pertussis toxin treatment, agonist-stimulated inositol phosphate accumulation was reduced in CHOA1H cells and abolished in CHOA1L cells. The relative intrinsic activity of NECA in stimulating inositol phosphate accumulation, compared to CPA (100%), was much greater in the presence of pertussis toxin (289.6%) than in the absence of pertussis toxin (155.2%). These data suggest that A(1) adenosine receptors can couple to both pertussis toxin-sensitive and -insensitive G-proteins in an expression level-dependent manner. These data also suggest that the ability of this receptor to activate different G-proteins is dependent on the agonist present.