The G protein-coupled receptor subset of the rat genome

<p>Abstract</p> <p>Background</p> <p>The superfamily of G protein-coupled receptors (GPCRs) is one of the largest within most mammals. GPCRs are important targets for pharmaceuticals and the rat is one of the most widely used model organisms in biological research. Accurate comparisons of protein families in rat, mice and human are thus important for interpretation of many physiological and pharmacological studies. However, current automated protein predictions and annotations are limited and error prone.</p> <p>Results</p> <p>We searched the rat genome for GPCRs and obtained 1867 full-length genes and 739 pseudogenes. We identified 1277 new full-length rat GPCRs, whereof 1235 belong to the large group of olfactory receptors. Moreover, we updated the datasets of GPCRs from the human and mouse genomes with 1 and 43 new genes, respectively. The total numbers of full-length genes (and pseudogenes) identified were 799 (583) for human and 1783 (702) for mouse. The rat, human and mouse GPCRs were classified into 7 families named the <it>Glutamate, Rhodopsin, Adhesion, Frizzled, Secretin, Taste2 and Vomeronasal1 </it>families. We performed comprehensive phylogenetic analyses of these families and provide detailed information about orthologues and species-specific receptors. We found that 65 human <it>Rhodopsin </it>family GPCRs are orphans and 56 of these have an orthologue in rat.</p> <p>Conclusion</p> <p>Interestingly, we found that the proportion of one-to-one GPCR orthologues was only 58% between rats and humans and only 70% between the rat and mouse, which is much lower than stated for the entire set of all genes. This is in mainly related to the sensory GPCRs. The average protein sequence identities of the GPCR orthologue pairs is also lower than for the whole genomes. We found these to be 80% for the rat and human pairs and 90% for the rat and mouse pairs. However, the proportions of orthologous and species-specific genes vary significantly between the different GPCR families. The largest diversification is seen for GPCRs that respond to exogenous stimuli indicating that the variation in their repertoires reflects to a large extent the adaptation of the species to their environment. This report provides the first overall roadmap of the GPCR repertoire in rat and detailed comparisons with the mouse and human repertoires.</p

Structure-activity relationships of constrained phenylethylamine ligands for the serotonin 5-ht2 receptors

Serotonergic ligands have proven effective drugs in the treatment of migraine, pain, obesity, and a wide range of psychiatric and neurological disorders. There is a clinical need for more highly 5-HT(2) receptor subtype-selective ligands and the most attention has been given to the phenethylamine class. Conformationally constrained phenethylamine analogs have demonstrated that for optimal activity the free lone pair electrons of the 2-oxygen must be oriented syn and the 5-oxygen lone pairs anti relative to the ethylamine moiety. Also the ethyl linker has been constrained providing information about the bioactive conformation of the amine functionality. However, combined 1,2-constriction by cyclization has only been tested with one compound. Here, we present three new 1,2-cyclized phenylethylamines, 9–11, and describe their synthetic routes. Ligand docking in the 5-HT(2B) crystal structure showed that the 1,2-heterocyclized compounds can be accommodated in the binding site. Conformational analysis showed that 11 can only bind in a higher-energy conformation, which would explain its absent or low affinity. The amine and 2-oxygen interactions with D3.32 and S3.36, respectively, can form but shift the placement of the core scaffold. The constraints in 9–11 resulted in docking poses with the 4-bromine in closer vicinity to 5.46, which is polar only in the human 5-HT(2A) subtype, for which 9–11 have the lowest affinity. The new ligands, conformational analysis and docking expand the structure-activity relationships of constrained phenethylamines and contributes towards the development of 5-HT(2) receptor subtype-selective ligands

The G protein-coupled receptor subset of the dog genome is more similar to that in humans than rodents

<p>Abstract</p> <p>Background</p> <p>The dog is an important model organism and it is considered to be closer to humans than rodents regarding metabolism and responses to drugs. The close relationship between humans and dogs over many centuries has lead to the diversity of the canine species, important genetic discoveries and an appreciation of the effects of old age in another species. The superfamily of G protein-coupled receptors (GPCRs) is one of the largest gene families in most mammals and the most exploited in terms of drug discovery. An accurate comparison of the GPCR repertoires in dog and human is valuable for the prediction of functional similarities and differences between the species.</p> <p>Results</p> <p>We searched the dog genome for non-olfactory GPCRs and obtained 353 full-length GPCR gene sequences, 18 incomplete sequences and 13 pseudogenes. We established relationships between human, dog, rat and mouse GPCRs resolving orthologous pairs and species-specific duplicates. We found that 12 dog GPCR genes are missing in humans while 24 human GPCR genes are not part of the dog GPCR repertoire. There is a higher number of orthologous pairs between dog and human that are conserved as compared with either mouse or rat. In almost all cases the differences observed between the dog and human genomes coincide with other variations in the rodent species. Several GPCR gene expansions characteristic for rodents are not found in dog.</p> <p>Conclusion</p> <p>The repertoire of dog non-olfactory GPCRs is more similar to the repertoire in humans as compared with the one in rodents. The comparison of the dog, human and rodent repertoires revealed several examples of species-specific gene duplications and deletions. This information is useful in the selection of model organisms for pharmacological experiments.</p

Identification of the first surrogate agonists for the G protein-coupled receptor GPR132

This is the accepted manuscript. The final version is available at http://pubs.rsc.org/en/Content/ArticleLanding/2015/RA/c5ra04804d#!divAbstract.GPR132 is an orphan Class A G protein-coupled receptor. It has been proposed to be activated by protons\ud and to regulate apoptosis, atherosclerosis and inflammation, but these results are still preliminary. In the\ud current work, we now designed and screened a focused compound library using a ?-arrestin recruitment\ud assay, and thereby identified the first disclosed surrogate GPR132 agonist 1 with a potency of 3.4 ?M.\ud This constitutes the first available pharmacological tool for the in vitro characterization of the orphan\ud receptor GPR132. The testing of 32 analogs furthermore identified a number of compounds with lower\ud activity - of which six were agonists and two were antagonists - that were used to construct preliminary\ud structure-activity relationships. Docking followed by molecular dynamics simulation of compound 1 in a\ud structural model of GPR132 displayed the putative interactions for the key ligand functionalities.M.A.S. was supported by a research scholarship from the\ud Drug Research Academy and Novo Nordisk A/S. D.E.G.\ud and H.B.-O. gratefully acknowledge financial support by\ud the Carlsberg Foundation. D.E.G. and D.S.P. gratefully\ud acknowledges financial support by the Lundbeck\ud Foundation. Nils Nyberg is acknowledged for help with\ud NMR spectroscopy. NMR equipment used in this work\ud was purchased via a grant from The Lundbeck\ud Foundation (R77-A6742)

Chemogenomic discovery of allosteric antagonists at the GPRC6A receptor

SummaryGPRC6A is a Family C G protein-coupled receptor recently discovered and deorphanized by our group. This study integrates chemogenomic ligand inference, homology modeling, compound synthesis, and pharmacological mechanism-of-action studies to disclose two noticeable results of methodological and pharmacological character: (1) chemogenomic lead identification through the first, to our knowledge, ligand inference between two different GPCR families, Families A and C; and (2) the discovery of the most selective GPRC6A allosteric antagonists discovered to date. The unprecedented inference of pharmacological activity across GPCR families provides proof-of-concept for in silico approaches against Family C targets based on Family A templates, greatly expanding the prospects of successful drug design and discovery. The antagonists were tested against a panel of seven Family A and C G protein-coupled receptors containing the chemogenomic binding sequence motif where some of the identified GPRC6A antagonists showed some activity. However, three compounds with at least ∼3-fold selectivity for GPRC6A were discovered, which present a significant step forward compared with the previously published GPRC6A antagonists, calindol and NPS 2143, which both display ∼30-fold selectivity for the calcium-sensing receptor compared to GPRC6A. The antagonists constitute novel research tools toward investigating the signaling mechanism of the GPRC6A receptor at the cellular level and serve as initial ligands for further optimization of potency and selectivity enabling future ex vivo/in vivo pharmacological studies

Receptor selectivity between the G proteins Gα12 and Gα13 is defined by a single leucine-to-isoleucine variation

Despite recent advances in structural definition of GPCR–G protein complexes, the basis of receptor selectivity between G proteins remains unclear. The Gα12 and Gα13 subtypes together form the least studied group of heterotrimeric G proteins. G protein–coupled receptor 35 (GPR35) has been suggested to couple efficiently to Gα13 but weakly to Gα12. Using combinations of cells genome-edited to not express G proteins and bioluminescence resonance energy transfer–based sensors, we confirmed marked selectivity of GPR35 for Gα13. Incorporating Gα12/Gα13 chimeras and individual residue swap mutations into these sensors defined that selectivity between Gα13 and Gα12 was imbued largely by a single leucine-to-isoleucine variation at position G.H5.23. Indeed, leucine could not be substituted by other amino acids in Gα13 without almost complete loss of GPR35 coupling. The critical importance of leucine at G.H5.23 for GPR35–G protein interaction was further demonstrated by introduction of this leucine into Gαq, resulting in the gain of coupling to GPR35. These studies demonstrate that Gα13 is markedly the most effective G protein for interaction with GPR35 and that selection between Gα13 and Gα12 is dictated largely by a single conservative amino acid variation.—Mackenzie, A. E., Quon, T., Lin, L.-C., Hauser, A. S., Jenkins, L., Inoue, A., Tobin, A. B., Gloriam, D. E., Hudson, B. D., Milligan, G. Receptor selectivity between the G proteins Gα12 and Gα13 is defined by a single leucine-to-isoleucine variation