key: cord-0910175-2tl90nxh
authors: Barresi, Elisabetta; Martini, Claudia; Da Settimo, Federico; Greco, Giovanni; Taliani, Sabrina; Giacomelli, Chiara; Trincavelli, Maria Letizia
title: Allosterism vs. Orthosterism: Recent Findings and Future Perspectives on A(2B) AR Physio-Pathological Implications
date: 2021-03-24
journal: Front Pharmacol
DOI: 10.3389/fphar.2021.652121
sha: 4d17d4320e0474cab0135d803c13365a3fd09bfb
doc_id: 910175
cord_uid: 2tl90nxh

The development of GPCR (G-coupled protein receptor) allosteric modulators has attracted increasing interest in the last decades. The use of allosteric modulators in therapy offers several advantages with respect to orthosteric ones, as they can fine-tune the tissue responses to the endogenous agonist. Since the discovery of the first A(1) adenosine receptor (AR) allosteric modulator in 1990, several efforts have been made to develop more potent molecules as well as allosteric modulators for all adenosine receptor subtypes. There are four subtypes of AR: A(1), A(2A), A(2B), and A(3). Positive allosteric modulators of the A(1) AR have been proposed for the cure of pain. A(3) positive allosteric modulators are thought to be beneficial during inflammatory processes. More recently, A(2A) and A(2B) AR allosteric modulators have also been disclosed. The A(2B) AR displays the lowest affinity for its endogenous ligand adenosine and is mainly activated as a consequence of tissue damage. The A(2B) AR activation has been found to play a crucial role in chronic obstructive pulmonary disease, in the protection of the heart from ischemic injury, and in the process of bone formation. In this context, allosteric modulators of the A(2B) AR may represent pharmacological tools useful to develop new therapeutic agents. Herein, we provide an up-to-date highlight of the recent findings and future perspectives in the field of orthosteric and allosteric A(2B) AR ligands. Furthermore, we compare the use of orthosteric ligands with positive and negative allosteric modulators for the management of different pathological conditions.

G-protein-coupled receptors (GPCRs) are a large family of membrane receptors that mediate the response to several extracellular stimuli. Thus, several efforts have been made to discover molecules acting on GPCRs that represent about one-fourth of marketed drugs approved in 2019 by the FDA (Salmaso and Jacobson, 2020) . Among the GPCR family, Adenosine receptors (ARs) are mainly involved in the sensing of tissue damage rather than homeostatic regulators under physiological conditions (Xiao et al., 2019) . Four subtypes of ARs (A 1 , A 2A , A 2B , and A 3 ) mediate the response to the increase of extracellular adenosine concentrations in response to stressors (Chen et al., 2013) . Adenosinergic pathways possess a dual face: on one side, elevated adenosine concentration restores an energy imbalance; on the other side, chronic exposure to high adenosine levels can switch to the promotion of pathological conditions such as uncontrolled inflammation, cytokine release, and fibrosis (Borea et al., 2017) .

Particularly, the A 2B AR has emerged as a possible therapeutic target in several physio-pathological conditions, including asthma (Cicala and Ialenti, 2013) , colitis (Kolachala et al., 2008) , cancer , cardiovascular, and metabolic disorders (Effendi et al., 2020) . However, among all the ARs, the A 2B subtype is the least characterized from a pharmacological point of view owing to the lack of X-ray structure and to its low affinity for the prototypic standard ligands commonly used to study ARs. Of note, the four AR subtypes, the A 1 , A 2A , A 2B , and A 3 , share a highly conserved binding (the "orthosteric" one) site of the endogenous agonist adenosine challenging the design of selective agonists. The design and development of positive (PAMs) as well as negative (NAMs) allosteric modulators binding to a less conserved, and topographically distinct site have emerged as an attractive strategy. Allosteric modulators can modulate the effects of the endogenous ligand in its site of production evidencing their ability to be spatially and temporally more selective than the orthosteric ones (Changeux and Christopoulos, 2016; Gregory et al., 2019; Congreve et al., 2020) .

The coupling of the A 2B AR with Gs causes, within the cells, the activation of adenylate cyclase with a consequent increase of cAMP levels. The increase of cAMP concentrations activates the protein kinase A (PKA) and Epac leading to the phosphorylation of cAMP response element-binding protein (CREB) and extracellular signal-regulated kinases (ERK) (Schulte and Fredholm, 2003; Giacomelli et al., 2018) . Furthermore, the A 2B AR is coupled with G q11 that mediates the activation of Phospholipase C (PLC) to increase the levels of 1,4,5-inositol triphosphate (IP 3 )/diacylglycerol (DAG), leading to activation of Protein kinase C (PKC) and increase of Ca 2+ levels ( Figure 1 ) (Ciruela et al., 2010) .

Although there are no A 2B AR ligands currently in clinical evaluation, several pre-clinical data have been reported to support their use to treat different conditions such as acute lung injury, ischemia, vascular leakage, metabolic disorders, and bone defects Carluccio et al., 2020; Gnad et al., 2020) ( Table 1) . The A 2B AR is highly expressed in the respiratory tract and its modulation has been related to the pathogenesis of chronic obstructive pulmonary disease (COPD) and pulmonary fibrosis (Zhong et al., 2005; Cronstein, 2011; Giacomelli et al., 2018) . The A 2B AR has been proposed as a potential target in acute lung injury (ALI): in fact, the administration of aerosolized BAY-60-6583 1 attenuates pulmonary edema and diminishes lung inflammation (Hoegl et al., 2015) . The A 2B AR expression has been related to the activation of the hypoxia-inducible factor in different cell types such as endothelial cells (Feoktistov et al., 2004) , lung (Eckle et al., 2014) , liver cancer cells , intestinal epithelial cells (Kong et al., 2006) . Its activation has been reported to be useful in the treatment of ischemic injury in different tissues such as the intestines (Hart et al., 2011) , heart (Ni et al., 2018 ) and brain (Coppi et al., 2020) .

In addition to the already known A 2B AR activity, the A 2B AR has been recently related to physiological processes and pathological conditions opening the way to new possible therapeuthic applications of the A 2B AR ligands. In fact, the activity of the A 2B AR has been linked to glucose homeostasis and insulin secretion and resistance (Merighi et al., 2015) . Accordingly, it has been reported that the A 2B AR is abundantly expressed in skeletal muscle (SKM) as well as brown adipose tissue (BAT), and its gene deletion in SKM cells causes sarcopenia, diminishes muscle strength, and reduces energy expenditure (Gnad et al., 2020) . Similarly, the adipose tissue specific silencing exacerbates the age-related reduction of BAT. The same authors demonstrated that the receptor stimulation with the A 2B AR agonist BAY-60-6583 1 ameliorates obesity (Gnad et al., 2020) .

Elevated adenosine concentration is known to exert immunosuppressive action through activation of the ARs mainly by the A 2A and A 2B subtypes. Interestingly, the use of adenosine as A 2A and A 2B AR agonist has been proposed and tested as an effective treatment strategy for the recent COVID-19 Falcone et al., 2020) .

The role of the different ARs in orchestrating the mesenchymal stem cell (MSCs) differentiation has been the focus of several researches (Reviewed in Carluccio et al., 2020) . The activation of the A 1 AR promotes osteoclast differentiation reducing the MSC-osteoblast differentiation. Conversely, several evidence support the role played by the A 2B AR in the adenosinemediated commitment of MSC into osteoblast differentiation (Gharibi et al., 2011; Carroll et al., 2012; He et al., 2013; Mediero and Cronstein, 2013; Rao et al., 2015; Shih et al., 2019) . The receptor activation promotes the expression of the osteogenic factor Runx2 and the phosphatase alkaline (ALP), favoring osteoblastogenesis (Gharibi et al., 2011) . Adenosine levels raise up to micromolar concentrations during bone injury, thus triggering the activation of the A 2B AR that is highly expressed in MSCs. Furthermore, the inflammation evoked during bone injury further enhances the anabolic responses evoked by A 2B AR ligands (Daniele et al., 2017) . These data support the role of the A 2B AR as an interesting target in the treatment of bone defects such as osteoporosis. Accordingly, the A 2B AR stimulation attenuates bone loss in ovariectomized mice, supporting its potential as a target for osteoporosis also consequent to estrogen deficiency (Shih et al., 2019) .

It is beyond the scope of this perspective to review the whole available literature concerning A 2B AR ligands. Instead, we have chosen to select a number of relevant (classes of) compounds to 1) offer a reliable overview of those drugs involved in both preclinical and clinical studies, and 2) briefly recapitulate the effects produced by a specific orthosteric or allosteric binding to the A 2B AR.

The number of A 2B AR agonists developed is the most limited among the ARs agonists, and no agonists for this AR subtype have yet entered clinical trials; nevertheless, some relevant A 2B AR agonists have been proposed and subjected to preclinical studies. Among them, the most promising compound, the nonnucleoside agonist BAY-60-6583 1 ( Table 1) , showed to be useful in the treatment of acute lung injury as well as in cardiovascular diseases, such as atherosclerosis and coronary artery disorders (Eckle et al., 2008; Gao et al., 2014) .

Conversely, several highly potent and selective A 2B AR antagonists have been reported and some of these had entered in clinical trials in the past decades. CVT-6883 (2, Table 1 , also known as GS-601), developed by Gilead along with various other compounds, such as, CGS15493 (3, Table 1 , developed by Novartis), WO-00125210 (Bayer HealthCare Pharmaceuticals), IPDX (4, Table 1 , Vanderbilt University), and ATL-907 (Adenosine Therapeutics) have entered phase I and II trials for the treatment of asthma (Chandrasekaran et al., 2019; Effendi et al., 2020) . In addition, the dual A 2B /A 3 AR antagonist QAF-807 (5, Table 1 , Novartis) had reached phase III clinical trial but it failed to attenuate PC20 AMP challenge as a marker of airway inflammation in mild asthmatic subjects (Wilson, 2008) .

The discrepancy between the few drugs entered in clinical practice and the pivotal role of adenosinergic system in several pathological processes can be partially explained by the ubiquitous AR expression in almost all tissues, increasing the possibility of unwanted side effects. In this respect, smallmolecules acting as allosteric modulators of the A 2B AR might be worthy of investigation as they could represent a potential novel therapeutic strategy for pathological conditions characterized by an altered functionality of this AR subtype.

The first selective PAM, PD81,723, has been reported in 1990 for the A 1 AR subtype (Bruns and Fergus, 1990) . Since then, many research groups have performed extensive structureactivity relationship studies and reported several PAMs of different AR subtypes (Valant et al., 2012; 2018; Deb et al., 2019) . Less has been reported regarding A 2A and A 2B AR allosteric modulators. In 2013, our research group serendipitously has discovered the first class of A 2B AR allosteric modulators (Taliani et al., 2013) . Specifically, adopting the strategy of designing AR antagonists starting from benzodiazepine receptor (BzR) ligands, the indol-3ylglyoxylamide scaffold, previously exploited by us to develop BzR ligands (Da Settimo et al., 1996; Da Settimo et al., 1998; Primofiore et al., 2001; Primofiore et al., 2006; Primofiore et al., 2007; Taliani et al., 2009; Cosimelli et al., 2012; Salerno et al., 2012) , has been structurally modified, providing a series of 1benzyl-3-ketoindoles (6a-b, 7a-c, 8a-b, Table 1 ). These compounds possess two structural features characterizing most of the A 2B AR antagonists: three lipophilic moieties linked to a heterocyclic ring and a group capable to establish hydrogen bonds.

No compounds show significant binding affinities toward A 1 , A 2A, , and A 3 ARs, except for 7a and 7b, which display moderate A 1 AR affinity (sub-micromolar K i values). Quite surprisingly, the new compounds act as selective human A 2B AR modulators in a stably transfected cell line. In particular, 6a,b and 7a behave as PAMs of the A 2B AR in functional assay by increasing the efficacy but not the potency of the A 2B AR agonists (NECA, BAY 60-6583, adenosine) in stimulating cAMP accumulation. These compounds have been deeply investigated using competitive and kinetic binding experiments resulting in the hypothesis that they favor the receptor active state without altering the orthosteric site. Compounds 7b,c and 8a,b act as NAMs of the A 2B AR by decreasing both efficacy and potency of agonists. Similar to the PAMs, the activity of these compounds have been also investigated with binding experiments. They probably interfer with receptor-G s protein coupling and, consequently, with the agonist functional response favoring the receptor uncoupled state (Trincavelli et al., 2014) .

The positive or negative profile of these compounds seems to be correlated to small structural differences. However, the limited number of compounds allowed to delineate only preliminary structure-activity relationships. In brief, compounds 6a, 6b, 8a, and 8b act as PAMs or NAMs depending on the nature of the linker between the indole nucleus and the lipophilic side chain, i.e. glyoxylamide for 6 and carboxamide for 8. Conversely, for compounds 7 the interaction with the protein strictly depends on the nature of the pendant aromatic ring: 7a with a phenyl ring is a PAM while 7b and 7c, featuring a furyl or a thienyl ring, respectively, are NAMs.

Based on the evidence that the A 2B AR is the principal AR subtype implicated in MSC differentiation to osteoblasts and bone formation (Gharibi et al., 2011) , the A 2B AR PAM 6b has been selected for its specificity toward the A 2B AR and evaluated for its effect on the agonist-mediated MSC differentiation to osteoblasts. Compound 6b potentiates the effects of either adenosine and synthetic orthosteric A 2B AR agonists (NECA and BAY 60-6583 1) in promoting MSC differentiation to osteoblasts in vitro (Trincavelli et al., 2014b) by increasing the osteogenic marker expression and by favoring osteoblast mineralization. In addition, in the early stage of differentiation, 6b potentiates the physiological and A 2B agonist-mediated reduction of IL-6 levels that in turn is necessary to support the differentiation process in MSCs. On the contrary, in the late differentiation phase, 6b improves the physiological and A 2B agonist-mediated IL-6 increase, important to ensure a pro-survival effect in osteoblasts. These results provide the basis for a prospective therapeutic use of selective A 2B AR PAMs in bone diseases.

Very recently, Barresi et al. (2021) , to expand the knowledge about the pharmacophoric requirements for A 2B AR allosteric modulation, have reported a series of novel derivatives chemically related to 6-8. Compounds from this library exhibit different degrees of similarity with the indoles 6, 7, and 8, including novel indole-based derivatives bearing various substitutions at 1-and/ or 3-positions, and derivatives characterized by different aromatic heterocycles in place of indole. Interestingly, structure-activity relationships in terms of matrix mineralization stimulation activity in MSCs (either in the presence or in the absence of the agonist BAY60-6583 1) suggest that the indole nucleus and N1-arylalkyl group do not represent key pharmacophoric elements for a compound acting as A 2B AR PAM. In this study compound 9 (Table 1) , which possesses a peculiar chemical structure with respect to the reference N1-benzyl substituted indoles 6-8, has been identified to represent a novel lead structure for the development of novel A 2B AR PAMs potentially acting as antiosteoporosis agents.

Allosteric modulation is a fundamental mechanism in biology and the development of allosteric ligand on GPCRs is a fastgrowing field. Allosteric modulators have the potential to inhibit, activate, or maintain the signaling of the GPCR receptor allowing their modulation based on the physiological requirement without blocking endogenous ligand binding. The research on this field has delivered hundred of candidates in the pipeline and also FDA-approved therapies.

Among the GPCRs, ARs have attracted considerable attention in drug developmemt. During the last fifty decades, several efforts have been made to develop small molecules acting as agonists, antagonists or allosteric enhancers of ARs. Most of these molecules failed in clinical trials and only three are currently approved for human use: adenosine, Regadenoson and Istradefylline. However, increasing evidence demonstrates the biological role played by ARs, particularly by the A 2B subtype, in pathological conditions. The A 2B AR is expressed under stress conditions in almost all human tissues, and exhibits a low affinity for its endogenous agonist adenosine. Based on the tissue, the nature of the stimuli and the time of exposure, the A 2B AR can mediate positive or negative effects. Thus, in the last decade, the research has been focused, on one hand, on a deeper knowledge of the molecular mechanism evoked by the A 2B AR activation in different pathological conditions; on the other hand, on the development of small molecules able to selectively bind to this receptor subtype. New A 2B AR ligands are currently being developed and the discovery of allosteric modulators represents an attractive research topic. The use of a GPCR orthosteric agonist can always lead to undesired effects due to its activation in other tissues. The limitation of the use of an AR orthosteric agonists and antagonists can not be completely overcome by the use of an allosteric modulator. Of note, the use of an A 2B AR agonist can lead to its activation in all the tissue (also where a low amount of adenosine is present) promoting undesired side effects. Conversely, allosteric modulators may represent a more physiologic alternative to orthosteric agonist and antagonist as they promote sitespecific and event-specific responses mainly in damaged tissues, where adenosine is massively released. Thus, the development of potent and selective A 2B AR PAMs can open the way to a new application of AR ligand in clinical practice likely reducing the side effects with respect to those potentially caused by orthosteric agonists.

The original contributions presented in the study are included in the article/Supplementary Material, further inquiries can be directed to the corresponding authors.

EB, CG, GG, ST, and MT conceived and wrote the manuscript. EB and CG prepared the images. CM, FS, GG, and MT edited and reviewed the final version of the article. All authors have read and agreed to the published version of the manuscript.

Novel positive allosteric modulators of A 2B adenosine receptor acting as bone mineralisation promoters

Pathological overproduction: the bad side of adenosine

Allosteric enhancement of adenosine A 1 receptor binding and function by 2-amino-3-benzoylthiophenes

Adult mesenchymal stem cells: is there a role for purine receptors in their osteogenic differentiation? Purinergic Signal

A 2B adenosine receptor promotes mesenchymal stem cell differentiation to osteoblasts and bone formation in vivo

Therapeutic potentials of A 2B adenosine receptor ligands: current status and perspectives

Allosteric modulation as a unifying mechanism for receptor function and regulation

Adenosine receptors as drug targets-what are the challenges?

Adenosine signaling in airways: toward a promising antiasthmatic approach

Adenosine receptors interacting proteins (ARIPs): behind the biology of adenosine signaling

Impact of GPCR structures on drug discovery

A 2B adenosine receptors: when outsiders may become an attractive target to treat brain ischemia or demyelination

Therapeutic effects of adenosine in high flow 21% oxygen aereosol in patients with Covid19-pneumonia

From the pharmacophore to the homology model of the benzodiazepine receptor: the indolyglyoxylamides affair

Adenosine receptors and fibrosis: a translational review

N'-Phenylindol-3-ylglyoxylohydrazide derivatives: synthesis, structure-activity relationships, molecular modeling studies, and pharmacological action on brain benzodiazepine receptors

Synthesis, structure-activity relationships, and molecular modeling studies of N-(indol-3-ylglyoxylyl)benzylamine derivatives acting at the benzodiazepine receptor

Osteogenesis is improved by low tumor necrosis factor alpha concentration through the modulation of gs-coupled receptor signals

Medicinal chemistry and therapeutic potential of agonists, antagonists and allosteric modulators of A 1 adenosine receptor: current status and perspectives

A 2B adenosine receptor signaling attenuates acute lung injury by enhancing alveolar fluid clearance in mice

Identification of hypoxia-inducible factor HIF-1A as transcriptional regulator of the A 2B adenosine receptor during acute lung injury

Focusing on adenosine receptors as a potential targeted therapy in human diseases

Can adenosine fight COVID-19 acute respiratory distress syndrome?

Hypoxia modulates adenosine receptors in human endothelial and smooth muscle cells toward an A 2B angiogenic phenotype

A 2B adenosine receptor and cancer

Probing biased/partial agonism at the G protein-coupled A 2B adenosine receptor

Adenosine receptor subtype expression and activation influence the differentiation of mesenchymal stem cells to osteoblasts and adipocytes

The A 2B adenosine receptor modulates the epithelial-mesenchymal transition through the balance of cAMP/PKA and MAPK/ERK pathway activation in human epithelial lung cells

Adenosine/A 2B receptor signaling ameliorates the effects of aging and counteracts obesity

In Vitro to in Vivo translation of allosteric modulator concentration-effect relationships: implications for drug discovery

Hypoxia-inducible factor-1α-dependent protection from intestinal ischemia/reperfusion injury involves ecto-5'-nucleotidase (CD73) and the A 2B adenosine receptor

Adenosine regulates bone metabolism via A 1 , A 2A , and A 2B receptors in bone marrow cells from normal humans and patients with multiple myeloma

Alveolar epithelial A 2B adenosine receptors in pulmonary protection during acute lung injury

A 3 adenosine receptors as modulators of inflammation: from medicinal chemistry to therapy

Historical and current adenosine receptor agonists in preclinical and clinical development

Blockade of adenosine A 2B receptors ameliorates murine colitis

HIF-dependent induction of adenosine A 2B receptor in hypoxia

HIF-1α regulates A 2B adenosine receptor expression in liver cancer cells

Adenosine and bone metabolism

Adenosine receptors and diabetes: focus on the A 2B adenosine receptor subtype

Infarctsparing effect of adenosine A 2B receptor agonist is primarily due to its action on splenic leukocytes via a PI3K/Akt/IL-10 pathway

Refinement of the benzodiazepine receptor site topology by structure-activity relationships of new N-(heteroarylmethyl)indol-3-ylglyoxylamides

Novel N-(arylalkyl)indol-3-ylglyoxylylamides targeted as ligands of the benzodiazepine receptor: synthesis, biological evaluation, and molecular modeling analysis of the structure-activity relationships

Novel N-substituted indol-3-ylglyoxylamides probing the LDi and L1/L2 lipophilic regions of the benzodiazepine receptor site in search for subtype-selective ligands

Adenosine signaling mediates osteogenic differentiation of human embryonic stem cells on mineralized matrices

Medicinal chemistry of indolylglyoxylamide GABAA/BzR high affinity ligands: identification of novel anxiolytic/non sedative agents

Purinergic signaling: impact of GPCR structures on rational drug design

The G(s)-coupled adenosine A 2B receptor recruits divergent pathways to regulate ERK1/2 and p38

Dysregulation of ectonucleotidase-mediated extracellular adenosine during postmenopausal bone loss

Identification of anxiolytic/nonsedative agents among indol-3-ylglyoxylamides acting as functionally selective agonists at the gammaaminobutyric acid-A (GABAA) alpha2 benzodiazepine receptor

Modulation of A 2B adenosine receptor by 1-Benzyl-3-ketoindole derivatives

Osteoblast differentiation and survival: a role for A 2B adenosine receptor allosteric modulators

Allosteric modulators of human A 2B adenosine receptor

Synthesis and characterization of novel 2-amino-3-benzoylthiophene derivatives as biased allosteric agonists and modulators of the adenosine A 1 receptor

Adenosine receptors and asthma in humans

Physiology and effects of nucleosides in mice lacking all four adenosine receptors

Synergy between A 2B adenosine receptors and hypoxia in activating human lung fibroblasts