Review
Adenosine receptors as drug targets

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Abstract

There are four adenosine receptors, A1, A2A, A2B and A3, together forming a defined subgroup of G protein coupled receptors. They are well conserved and widely expressed. The endogenous agonist, adenosine, has a minimal concentration in body fluids (20–200 nM) that is sufficient to slightly activate the receptors where they are very highly expressed—as in the basal ganglia, on fat cells and in the kidney. Here adenosine can play a physiological role and here antagonists such as caffeine can have effects in healthy individuals. Adenosine levels rise in stress and distress (up to 30 μM in ischemia) and tend to minimize the risk for adverse outcomes by increasing energy supply and decreasing cellular work, by stimulating angiogenesis, mediating preconditioning and having multiple effects on immune competent cells. These pathophysiological roles of adenosine also offer some potential drug targets, but the fact that adenosine receptors are involved in so many processes does not simplify drug development.

Introduction

Adenosine receptors comprise a tight, evolutionarily well conserved, subgroup of G protein-coupled receptors [1].1 They are denoted A1 , A2A, A2B and A3 ; the first and the last couple predominantly to G proteins of the Gi family, whereas the two A2 receptors predominantly couple to members of the Gs family [2]. Nevertheless, the receptors can couple also to other G protein pathways, especially when over expressed. The natural ligand is adenosine, but at A1 and A3 receptors also inosine can act as a partial agonist [3], [4].

When we want to consider these receptors as potential drug targets it is important to know what level of activation that is achieved by endogenous adenosine acting at the receptors in different locations. Two factors are then of importance: (1) the potency of adenosine as an agonist at the different adenosine receptors, and (2) the levels of adenosine that are found under physiological and pathophysiological conditions.

Unfortunately it proves very difficult to determine the affinity of adenosine to the receptors by direct binding studies. The reason is that adenosine is rapidly metabolized and also rapidly formed in biological preparations including membrane preparations. Therefore, if metabolism of the labelled added adenosine is prevented, endogenous adenosine accumulates to confound the measurements, and we do not have reliable data on the comparative affinity of the endogenous agonist at the four adenosine receptors.

The potency of adenosine must therefore be measured in functional assays. This introduces another important confounding factor: potency of the agonist is markedly influenced by the receptor number [5], [6], [7]. Adenosine receptors generally exhibit the behaviour described by pharmacologists as “spare receptors.” In such systems alterations in receptor number is manifested by parallel shifts in the dose response curve, not as alterations in the maximal response. It is therefore important to compare potencies between receptors at comparative receptor densities. When this is done it is observed that adenosine is equipotent at A1, A2A and A3 receptors, but is some 50 times less potent at A2B receptors if alterations in cAMP are recorded [3]. If, by contrast, we instead examine the ability to activate MAP kinase (which all the receptors do), adenosine is equipotent at all of them [8], [9]. Thus, the potency of endogenous adenosine depends both on receptor number, and on the type of response measured. Furthermore, there is no really good reason to divide the receptors into high affinity and low affinity receptors as is sometimes done.

Because it is a key metabolite there is always a finite intracellular concentration of adenosine. Since most if not all cells possess equilibrative adenosine transporters, there will, by necessity, be also a finite level of adenosine in the extracellular space, even under the most basal conditions. This is in the range of 30–200 nM [10]. From this baseline level adenosine can increase substantially via several mechanisms: (1) formation intracellularly and export via transporters, and (2) formation in the extracellular space from adenine nucleotides released from cells. Adenosine is formed intracellularly whenever there is a discrepancy between the rates of ATP synthesis and ATP utilization; e.g. when work load is markedly enhanced or when the supply of oxygen and glucose is limiting as in ischemia.

ATP might, as originally proposed, act as a neurotransmitter, stored and released together with other transmitters [11], sometimes ATP may be preferentially released via so-called kiss-and-run mechanism [12].Several additional mechanisms have now moved to the foreground: (1) release from cells with damage to the cell membrane e.g. in necrotic cell death, (2) release from large storage vesicles containing hormones, (3) via connexin/pannexin “hemichannels,” (4) from transport vesicles delivering proteins to the cell membrane, and (5) from a subset of lysosomes. It is well known that ATP is released from many cells where cell membranes subjected to stretch [13], perhaps via one of the above mentioned mechanisms.

One ATP (or ADP) is released the phosphate groups of extracellular ATP are rapidly split off by ecto-enzymes working in concert, first via nucleoside triphosphate diphosphohydrolases (NTDPases) similar to CD39 [14], followed by hydrolysis via ecto-5′-nucleotidase, CD73 [15]. Knock-outs of these enzymes have revealed their importance in different organs and situations.

As one would predict from these biochemical/cell biological considerations adenosine levels will rise under conditions of stress and be particularly high under circumstances when the organism is in severe distress such as after an ischemic insult. Several studies estimate the resting extracellular levels of adenosine to be in the range 20–300 nM, and the levels can rise to the low micromolar range in conditions of extreme physiology such as strenuous exercise or subsistence at high altitude and hence low ambient oxygen. In ischemic areas or after massive tissue trauma leading to cell death by necrosis levels can increase to perhaps 30 μM [16].

If these data are related to the estimated potency of adenosine receptors we arrive at a picture like that illustrated in Fig. 1. One can see that in places where the receptors are very abundant there will be a physiological role of adenosine, in places where receptors are fewer receptors may only be activated under extreme or pathological circumstances.

It was shown early that theophylline and other methylxanthines are very effective as antagonists of the actions of adenosine. This antagonism was the basis for the first proposal that there are specific adenosine receptors, at which methylxanthines are antagonists [17], and it was soon realized that many of the effects of the xanthines are in fact due to inhibition of actions of endogenous adenosine [18], [19]. There is, however, one receptor A3 , which is not influenced by reasonable concentrations of most xanthines. [1]. It is probably that this contributed to its remaining undiscovered for so long. Based on the xanthine structures several more potent, and some receptor subtype selective, antagonists have been synthesized. These have been complemented by non-xanthine antagonists and several receptor-selective agonists, and we now are in the fortunate position to have a set of apparently quite selective pharmacological tools [1], [20], [21], [22], [23].

However, many of the most potent and selective antagonists have physicochemical properties that complicate their use in vivo in animals and man. Therefore, the fact that there are mice with targeted deletions of one or more adenosine receptors has been very useful to delineate the roles played by adenosine receptors [24]. There is always a concern that deleting a receptor throughout life will induce major adaptive changes. In the case of adenosine receptors this has not been borne out: there are remarkably few adaptations, and particularly there are few if any compensatory changes in the remaining three receptors if one of them is deleted at birth. The reason for this is presumably that adenosine is not a critical regulator of many really important physiological processes. After all there is a pressure for adaptive changes only for continuously ongoing processes, not for processes that are coming into play in an emergency.

One powerful technique is to combine the use of drugs with the knock-out. This has for example been used to test the hypothesis that caffeine is acting by blocking adenosine receptors. In general this hypothesis has fared well using this stringent test—at least as long as low doses of the drug are used. It has long been known that caffeine has biphasic effects—stimulatory and causing slightly euphoria in low doses—inhibitory and dysphoric at high doses [19]. There is variability among species, strains and individuals, and it is not possible to precisely state what is a high and a low dose. Generally, in rats and mice doses below 15 mg/kg can be considered low, and acting via adenosine blockade, doses above 25 mg/kg high and at least partly acting via other mechanisms. It remains to be shown what these mechanisms are [19], [25].

Despite the general conclusion that caffeine acts by blocking adenosine receptors is well established there can be interesting surprises. For example, studies on the actions of caffeine in sleep—one of the best recognized actions in man—were generally based on the assumption that A1 receptors in basal forebrain nuclei including tuberomammillary nucleus are involved [26], [27]. In particular it was assumed that sleep deprivation would lead to accumulation of adenosine in these areas [26]. It was therefore a major surprise when the A1 receptor knock-out mouse showed normal sleep–wake cycles and similar rebound sleep after deprivation [28]. Furthermore, it was found that the response to caffeine was unaltered in mice lacking A1 receptors, but lost in mice that do not have A2A receptors [29]. Thus, there is a close link between the pathways that mediate changes in wakefulness and those that alter locomotion, suggesting new important regulatory pathways for sleep-wakefulness.

Not only are knock-out animals indispensable in drug research, but mice that are hemizygous for relevant genes are also very useful. As indicated above a decrease in adenosine receptor number leads to a rightward shift in the dose response curve to adenosine and other agonists. This is also the case for a competitive antagonist. Thus, one might expect that some features of long-term administration of an antagonist may be mimicked by a hemizygous receptor deletion, especially for a drug such as caffeine where complete receptor blockade cannot be achieved due to low potency and the presence of dose-limiting side effects. Indeed, this contention has been borne out since mice that lack one copy of both the A1 and the A2A receptor gene exhibit several features of animals that have been treated for a long time with caffeine [30]. We also showed that the hyperreactivity to psyhostimulants that is a feature of adult mice borne to dams given caffeine just before and after pregnancy, can be mimicked in mice hemizygous for the A1 gene [31]. It is notoriously difficult to judge whether a drug that is given to the dam but affects the pup, even in adulthood, does so because of a primary action on the pup or on the mother. Since we could recapitulate the phenotype by a genetic model we could make the decisive experiment (raising heterozygous pups in wild-type mother, and raising wild-type pups in heterozygous mothers). The results conclusively show that it is by a primary action on the dam that the behaviour of the pup later on in life is affected [31]. Furthermore, since the effect can be transmitted at least one generation an epigenetic mechanism by which maternal behaviour influences the offspring is implicated.

Section snippets

Are there therapeutic possibilities?

Using drugs and mice with targeted deletions it has been possible to delineate a number of physiological and pathophysiological processes where one or more adenosine receptors are involved. The list of such processes is quite wide, and since it is increasing each year it is likely that it will further lengthen. A partial list is given below:

  • A1 receptors: decreased renal blood flow; tubuloglomerular feedback; inhibition of lipolysis; inhibition of neurotransmitter release; inhibition of

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