COSMOsar3D: Molecular Field Analysis Based on Local COSMO sigma-Profiles

Klamt, Andreas and Thormann, Michael and Wichmann, Karin and Tosco, Paolo (2012) COSMOsar3D: Molecular Field Analysis Based on Local COSMO sigma-Profiles. JOURNAL OF CHEMICAL INFORMATION AND MODELING, 52 (8). pp. 2157-2164. ISSN 1549-9596,

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Abstract

The COSMO surface polarization charge density sigma resulting from quantum chemical calculations combined with a virtual conductor embedding has been widely proven to be a very suitable descriptor for the quantification of interactions of molecules in liquids. In a preceding paper, grid based local histograms of sigma have been introduced in the COSMOsim3D method, resulting in a novel 3D-molecular similarity measure and going along with a novel property-based molecular alignment method. In this paper, we introduce under the name COSMOsar3D the usage of the resulting array of local sigma-profiles as a novel set of molecular interaction fields for 3D-QSAR, containing all information. required for quantifying the virtual ligand-receptor interactions, including desolvation. In contrast to currently used molecular interaction fields, we provide a theoretical rationale that the logarithmic binding Constants of ligands should be a linear function. Of the array of local sigma-profiles. This makes them especially suitable for linear regression analysis methods such as PLS. We demonstrate that the Usage-of local sigma profiles in molecular field analysis inverts the role. of ligands and receptor; while conventional 3D-QSAR. considers:the virtual receptor in potential energy fields provided by the ligands, our COSMOsar3D approach correspond the. calculation of the. free energy of the ligands in a virtual free energy field provided by the receptor. First applications of the COSMOsar3D method are presented, which demonstrate its ability to yield robust and predictive models that seem to be superior to the models generated on the basis of conventionally used molecular fields.

Item Type: Article
Uncontrolled Keywords: FORCE-FIELD; APPROXIMATION; TURBOMOLE; ENERGY;
Subjects: 500 Science > 540 Chemistry & allied sciences
Divisions: Chemistry and Pharmacy > Institut für Physikalische und Theoretische Chemie
Depositing User: Dr. Gernot Deinzer
Date Deposited: 11 May 2020 07:00
Last Modified: 11 May 2020 07:00
URI: https://pred.uni-regensburg.de/id/eprint/18323

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