Receptors have well-conserved regions that are recognized and activated by hormones and neurotransmitters. Most drugs bind to these sites and mimic or block the action of the native ligands. Using a high-throughput functional screen, we identified a potent and selective M 1 muscarinic receptor agonist from a novel structural class. Using a series of chimeric receptors, we demonstrated that this ligand activates the receptor through a region that is not conserved among receptor subtypes, explaining its unprecedented selectivity. This region of the receptor is distinct from the conserved region that is recognized by traditional ligands. The finding that receptors for small-molecule transmitters can have multiple, structurally distinct activation sites has broad implications for the study of receptor structure/function and the potential for the discovery of novel ligands with high selectivity.G-protein-coupled receptors that bind monoamine ligands (e.g., serotonin, adrenaline, dopamine, histamine, and acetylcholine) comprise the most intensively studied and exploited receptor family for the development of therapeutic agents by the pharmaceutical industry. The natural ligands for monoamine receptors are believed to bind a highly conserved pocket located deep within the transmembrane (TM)-spanning regions and to mediate receptor activation primarily through TM3, TM5, TM6, and TM7 (Spalding et al., 1994;Baldwin et al., 1997;Gether, 2000;Lu et al., 2001). Of the amino acids in these regions, 74% are identical in all five muscarinic receptor subtypes (Bonner et al., 1988). Potent small-molecule agonists are also believed to bind monoamine receptors through the same highly conserved regions (Strader et al., 1989(Strader et al., , 1991Wess et al., 1991;Page et al., 1995;Spalding et al., 1998;Ward et al., 1999;Allman et al., 2000).The muscarinic M 1 receptor has been targeted for the discovery of therapeutics for Alzheimer's Disease, and several companies have developed M 1 -selective agonists (e.g., Tecle et al., 1998;Wood et al., 1999;Bartolomeo et al., 2000;Wienrich et al., 2001). Many potent compounds came out of these programs, and several were shown to improve cognition in animals (WAY-132983 and CI-1017; Bartolomeo et al., 2000;Weiss et al., 2000) and people (Xanomeline, Bodick et al., 1997). However, many of the compounds also produced classic muscarinic side effects such as sweating, nausea and diarrhea (Bodick et al., 1997, Bartolomeo et al., 2000Thal et al., 2000). In vitro assays have shown that these compounds activate the M 1 , M 3 , M 4 , and M 5 muscarinic receptor subtypes at similar concentrations (Table 1 and Tecle Wood et al., 1999;Bartolomeo et al., 2000;Wienrich et al., 2001). This may be a direct result of the ligands activating the receptors through regions where the amino acid sequence is almost identical. Since drug interactions with nontarget receptor subtypes are often responsible for the unwanted side effects of commercial pharmaceuticals, there is strong motivation to design more selec...
4'-Octyl-4-biphenylcarboxylic acid (1g, AC-55649) was identified as a highly isoform-selective agonist at the human RARbeta2 receptor in a functional intact cell-based screening assay. The subsequent hit to lead optimization transformed the lipophilic, poorly soluble hit into a more potent and orally available compound (2, AC-261066) with retained beta2 selectivity and greatly improved physiochemical properties. Being an isoform-selective RARbeta2 receptor agonist that discriminates between nuclear receptor isoforms having identical ligand binding domains, 2 will be useful as a pharmacological research tool but also a valuable starting point for drug development.
Proteinase activated receptor-2 plays a crucial role in a wide variety of conditions with a strong inflammatory component. We present the discovery and characterization of two structurally different, potent, selective, and metabolically stable small-molecule PAR-2 agonists. These ligands may be useful as pharmacological tools for elucidating the complex physiological role of the PAR-2 receptors as well as for the development of PAR-2 antagonists.
A functional cell-based screen identified 3-(4-chlorophenyl)-3-(2-(dimethylamino)ethyl)isochroman-1-one hydrochloride (AC-7954, 1) as a nonpeptidic agonist of the urotensin-II receptor. Racemic 1 had an EC50 of 300 nM at the human UII receptor and was highly selective. Testing of the enantiopure (+)- and (-)- 1 revealed that the UII receptor activity of racemic 1 resides primarily in (+)-1. Being a selective nonpeptidic druglike UII receptor agonist, (+)-1 will be useful as a pharmacological research tool and a potential drug lead.
Chemical genomics is a drug discovery strategy that relies heavily on high-throughput screening (HTS) and therefore benefits from functional assay platforms that allow HTS against all relevant genomic targets. Receptor Selection and Amplification Technology (R-SAT) is a cell-based, high-throughput functional assay where the receptor stimulus is translated into a measurable cellular response through an extensive signaling cascade occurring over several days. The large biological and chronological separation of stimulus from response provides numerous opportunities for enabling assays and increasing assay sensitivity. Here we review strategies for building homogeneous assay platforms across large gene families by redirecting and/or amplifying signal transduction pathways.
A novel class of CB1 inverse agonists was discovered. To efficiently establish structure-activity relationships (SARs), new synthetic methodologies amenable for parallel synthesis were developed. The compounds were evaluated in a mammalian cell-based functional assay and in radioligand binding assays expressing recombinant human cannabinoid receptors (CB1 and CB2). In general, all of the compounds exhibited high binding selectivity at CB1 vs CB2 and the general SAR revealed a lead compound 11-(4-chlorophenyl)dibenzo[b,f][1,4]thiazepine-8-carboxylic acid butylamide (12e) which showed excellent in vivo activity in pharmacodynamic models related to CB1 receptor activity. The low solubility that hampered the development of 12e was solved leading to a potential preclinical candidate 11-(3-chloro-4-fluorophenyl)dibenzo[b,f][1,4]thiazepine-8-carboxylic acid butylamide (12h).
Current therapeutic options for recurrent neuroblastoma have poor outcomes that warrant the development of novel therapeutic strategies. Specificity protein (Sp) transcription factors regulate several genes involved in cell proliferation, survival, and angiogenesis. Sp1 regulates genes believed to be important determinants of the biological behavior of neuroblastoma. Tolfenamic acid (TA), a non-steroidal anti-inflammatory drug, is known to induce the degradation of Sp proteins and may serve as a novel anti-cancer agent. The objective of this investigation was to examine the anti-cancer activity of TA using established human neuroblastoma cell lines. We tested the anti-proliferative effect of TA using SH-SY5Y, CHLA90, LA1 55n, SHEP, Be2c, CMP 13Y, and SMS KCNR cell lines. Cells were treated with TA (0/25/50/100 µM) and cell viability was measured at 24, 48, and 72 h post-treatment. Selected neuroblastoma cell lines were treated with 50 µM TA for 24 and 48 h and tested for cell apoptosis using Annexin-V staining. Caspase activity was measured with caspase 3/7 Glo kit. Cell lysates were prepared and the expression of Sp1, survivin, and c-PARP were evaluated through Western blot analysis. TA significantly inhibited the growth of neuroblastoma cells in a dose/time-dependent manner and significantly decreased Sp1 and survivin expression. Apart from cell cycle (G0/G1) arrest, TA caused significant increase in the apoptotic cell population, caspase 3/7 activity, and c-PARP expression. These results show that TA effectively inhibits neuroblastoma cell growth potentially through suppressing mitosis, Sp1, and survivin expression, and inducing apoptosis. These results show TA as a novel therapeutic agent for neuroblastoma.
Ras and rac are each members of the superfamily of monomeric GTPases and both function as molecular switches to link cell-surface signals to intracellular responses. Using a novel assay of cellular proliferation called R-SAT TM (Receptor Selection and Ampli®cation Technology), we examined the roles of ras and rac in mediating the proliferative responses to a variety of cellsurface receptors. Activated, wild-type and dominantnegative mutants of rac and ras were tested for their e ects on cellular proliferation either alone or in combination with receptors. Activated rac (rac Q61L, henceforth rac*) and ras (ras G12V, henceforth ras*) each induced strong proliferative responses. Dominantnegative rac (rac T17N, henceforth rac (7)) dramatically suppressed proliferative responses to G-protein coupled receptors (GPCR's) including the m5 muscarinic receptor and the a1B adrenergic receptor. In contrast, rac(7) had little or no e ect upon responses to the tyrosine kinase receptor TrkC, and only partially suppressed responses to the Janus kinase (JAK/STAT) linked granulocyte macrophage colony stimulating factor (GM-CSF) receptor. Dominant-negative ras (ras T17N, henceforth ras(7)) blocked the proliferative responses to all of the tested receptors. Compared to rac(7) and ras(7), wild-type rac and ras had only modest e ects on the tested receptors. Overall these results demonstrate that rac mediates the proliferative e ects of G-protein coupled receptors through a pathway that is distinct from the proliferative signaling pathway utilized by tyrosine kinase linked and JAK-linked receptors.
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