Prediction of structure and function of G protein-coupled receptors

Vaidehi, Nagarajan; Floriano, Wely B.; Trabanino, Rene J.; Hall, Spencer E.; Freddolino, Peter L.; Choi, Eun Jung; Zamanakos, Georgios; Goddard, William A.

doi:10.1073/pnas.122357199

Cited by 278 publications

(277 citation statements)

References 47 publications

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“…In an explicit homology model, individual rotamer positions are assigned to all amino acids, and the model is then typically refined by molecular dynamics or stepwise relaxation steps folding the side chains around a number of known ligands. While there are various techniques described in the literature to arrive at state-of-the-art homology models, 23,24 they all stress the need of additional information from highly potent ligands 7,[23][24][25][26][27][28][29][30][31][32]34,35 and of several refinement cycles. There is no reference point by which the accuracy of such models can be judged, except for consistency with known rules about protein folding.…”

Section: Discussionmentioning

confidence: 99%

“…23,24 To obtain high-quality homology models suitable for docking experiments, additional, work-intensive refinement cycles are needed that explicitly take into account binding studies with highly potent ligands. 7,21,23,[25][26][27][28][29][30][31][32][33][34][35] This kind of approach is very valuable for optimizations of medicinal chemistry series in advanced projects on wellcharacterized targets, where mutational data and structureactivity relationships for the ligands are available and can be incorporated into validation cycles of the models. In earlystage GPCR projects, however, where often only the natural ligands are known and data from site-directed mutagenesis are missing, a traditional GPCR homology model with its focus on atomic details may turn out to be of only limited use.…”

Section: Introductionmentioning

confidence: 99%

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An Automated System for the Analysis of G Protein-Coupled Receptor Transmembrane Binding Pockets: Alignment, Receptor-Based Pharmacophores, and Their Application

Kratochwil

Malherbe

Lindemann

et al. 2005

J. Chem. Inf. Model.

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G protein-coupled receptors (GPCRs) share a common architecture consisting of seven transmembrane (TM) domains. Various lines of evidence suggest that this fold provides a generic binding pocket within the TM region for hosting agonists, antagonists, and allosteric modulators. Here, a comprehensive and automated method allowing fast analysis and comparison of these putative binding pockets across the entire GPCR family is presented. The method relies on a robust alignment algorithm based on conservation indices, focusing on pharmacophore-like relationships between amino acids. Analysis of conservation patterns across the GPCR family and alignment to the rhodopsin X-ray structure allows the extraction of the amino acids lining the TM binding pocket in a so-called ligand binding pocket vector (LPV). In a second step, LPVs are translated to simple 3D receptor pharmacophore models, where each amino acid is represented by a single spherical pharmacophore feature and all atomic detail is omitted. Applications of the method include the assessment of selectivity issues, support of mutagenesis studies, and the derivation of rules for focused screening to identify chemical starting points in early drug discovery projects. Because of the coarseness of this 3D receptor pharmacophore model, however, meaningful scoring and ranking procedures of large sets of molecules are not justified. The LPV analysis of the trace amine-associated receptor family and its experimental validation is discussed as an example. The value of the 3D receptor model is demonstrated for a class C GPCR family, the metabotropic glutamate receptors.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

An Automated System for the Analysis of G Protein-Coupled Receptor Transmembrane Binding Pockets: Alignment, Receptor-Based Pharmacophores, and Their Application

Kratochwil

Malherbe

Lindemann

et al. 2005

J. Chem. Inf. Model.

View full text Add to dashboard Cite

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“…This work builds upon our recent studies in which we first predicted the 3-D structures of mouse MrgC11 (mMrgC11) and MrgA1 (mMrgA1) receptors using the MembStruk computational method [9,10]. These structures were validated by predicting the binding sites and energies for several tetrapeptides, identifying key residues, and then experimentally confirming the expected changes in binding resulting from mutations of these residues.…”

Section: Introductionmentioning

confidence: 84%

“…This protocol has been used for several GPCRs [9,10,13,14,16,27,28], outer membrane protein A [29], and globular proteins [15,[30][31][32][33][34]. In this paper we used the modified HierDock protocol (MSCdock) described in Cho et al 2005 [35].…”

Section: Docking Adenine and Guanine Into The Predicted Putative Bindmentioning

confidence: 99%

Prediction of the 3-D structure of rat MrgA G protein-coupled receptor and identification of its binding site

Heo

Vaidehi

Wendel

et al. 2007

Journal of Molecular Graphics and Modelling

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Mrg receptors are orphan G protein-coupled receptors (GPCRs) located mainly at the specific set of sensory neurons in the dorsal root ganglia, suggesting a role in nociception. We report here the 3-D structure of rat MrgA (rMrgA) receptor [obtained from homology modeling to the recently validated predicted structures of mouse MrgA1 and MrgC11] and the structure of adenine (a known agonist, K i =18nM) bound to rMrgA. This predicted binding site is located within transmembrane helical domains (TMs) 3, 4, 5 and 6, with Asn residues in TM3 and TM4 identified as the key residues for adenine binding. Here the side chain of Asn88 (TM3) forms two pairs of hydrogen bonds with N3 and N9 of adenine while Asn146 (TM4) makes two pairs of hydrogen bonds with N1 and N6 of adenine. These interactions lock adenine tightly in the binding pocket. We also predict the binding site of guanine (not an agonist) and seven other derivatives. Guanine cannot make the hydrogen bond to Asn146 (TM4), leading to binding too weak to be observed experimentally. The predicted binding affinity for other adenine derivatives correlates with the availability of the hydrogen bonds to these two Asn residues. These results validate the predicted structure for rat MrgA and suggest mutation experiments that could further validate the structure. Moreover the predicted structure and binding site should be useful for seeking other small molecule agonists and antagonists.

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“…Our standard model building protocols differ slightly from those previously established 36,53,54 , by independently predicting the TM regions followed by removing of rhodopsin structure specific biases. In the case of hOR17-210, we are breaking new ground because we have identified and attempt to model a novel TM (TM 7') that has not been sequence-structurally observed.…”

Section: Discussionmentioning

confidence: 99%

An Olfactory Receptor Pseudogene whose Function emerged in Humans

Lai

Bahl

Gremigni³

et al. 2007

Nat Prec

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Human olfactory receptor, hOR17-210, is identified as a pseudogene in the human genome. Experimental data has shown however, that the gene product of cloned hOR17-210 cDNA was able to bind an odorant-binding protein and is narrowly tuned for excitation by cyclic ketones. Supported by experimental results, we used the bioinformatics methods of sequence analysis, computational protein modeling and docking, to show that functionality in this receptor is retained due to sequence-structure features not previously observed in mammalian ORs. This receptor does not possess the first two transmembrane helical domains (of seven typically seen in GPCRs). It however, possesses an additional TM that has not been observed in other human olfactory receptors. By incorporating these novel structural features, we created two putative models for this receptor. We also docked odor ligands that were experimentally shown to bind hOR17-210 model. We show how and why structural modifications of OR17-210 do not hinder this receptor's functionality. Our studies reveal that novel gene rearrangement that result in sequence and structural diversity in has a bearing on OR and GPCR function and evolution.

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Prediction of structure and function of G protein-coupled receptors

Cited by 278 publications

References 47 publications

An Automated System for the Analysis of G Protein-Coupled Receptor Transmembrane Binding Pockets: Alignment, Receptor-Based Pharmacophores, and Their Application

An Automated System for the Analysis of G Protein-Coupled Receptor Transmembrane Binding Pockets: Alignment, Receptor-Based Pharmacophores, and Their Application

Prediction of the 3-D structure of rat MrgA G protein-coupled receptor and identification of its binding site

An Olfactory Receptor Pseudogene whose Function emerged in Humans

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