ph4 models (Molecular Dynamics Inc)
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Ph4 Models, supplied by Molecular Dynamics Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/ph4+models/pmc06478719-202-1-15?v=Molecular+Dynamics+Inc
Average 90 stars, based on 1 article reviews
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1) Product Images from "Computational modeling of the olfactory receptor Olfr73 suggests a molecular basis for low potency of olfactory receptor-activating compounds"
Article Title: Computational modeling of the olfactory receptor Olfr73 suggests a molecular basis for low potency of olfactory receptor-activating compounds
Journal: Communications Biology
doi: 10.1038/s42003-019-0384-8
Figure Legend Snippet: Workflow of virtual screening for new agonists of Olfr73. a Homology modelling of Olfr73 based on 3D structure-sequence alignment of Olfr73 to β 2 AR and Rho. b Refinement of ECL2 loop. c Molecular dynamics (MD) simulations of agonist bound Olfr73. d Docking agonist molecule into the 3D structural model of Olfr73. e Interaction fingerprint analysis by docking 25 reported compounds. This information was subsequently used for PH4 model building in virtual screening. f Virtual screening for Olfr73 agonists in the ZINC compound library composed of 1.58 million drug candidates. Applying stepwise selection filtering based on shape volume, ionization penalty and polarity, downscaled the chemical library successively to 204 compounds. The shape volume features are deduced from the results of MD simulations. Finally, quantitative structure–activity relationship evaluations reduced the chemical library to 64 compounds with predicted potential to activate Olfr73. Out of this final list, agonist binding modes were verified manually based on the activation mechanism deduced from MD simulations, and 25 available compounds were tested by cellular functional assays yielding 17 active compounds
Techniques Used: Sequencing, Drug discovery, Selection, Activity Assay, Binding Assay, Activation Assay, Functional Assay
Figure Legend Snippet: Hierarchical clustering of Olfr73 agonist molecules. Six different classes of agonists are identified (distinguished by a color code) according to their PH4 features. In the Hierarchical diagram, the links between the chemical compounds are represented as branched vertical lines. The height of the lines, coupled with merging distance (numbers showed in each node), indicate the normalized dissimilarity distance between the adjacent compounds. A higher line or a larger merging distance denotes a larger dissimilarity. A typical representative molecular structure of each class is shown below the dendrogram together with their molecular surfaces indicating hydrophobic moieties in grey and polar moieties in red. The commonly shared atoms within a certain class of molecules are labeled with colored dots accordingly. The molecular structures of the six classes of agonists are grouped in boxes. The 17 newly found agonists are represented as A1-A17 in blue. The 25 previously reported agonists are represented as B1-B25 in black. The agonist isoeugenol is B3 and p-isobutylphenol is A1. In all cases the corresponding micromolar EC 50 values are indicated in brackets. Names of A- and B-compounds are listed in Supplementary Tables and
Techniques Used: Labeling