QSAR and Chemical Read-Across Analysis of 370 Potential MGMT Inactivators to Identify the Structural Features Influencing Inactivation Potency

Guohui Sun; Peiying Bai; Tengjiao Fan; Lijiao Zhao; Rugang Zhong; R Stanley McElhinney; T Brian H McMurry; Dorothy J Donnelly; Joan E McCormick; Jane Kelly; Geoffrey P Margison

doi:10.3390/pharmaceutics15082170

QSAR and Chemical Read-Across Analysis of 370 Potential MGMT Inactivators to Identify the Structural Features Influencing Inactivation Potency

Pharmaceutics. 2023 Aug 21;15(8):2170. doi: 10.3390/pharmaceutics15082170.

Authors

Affiliations

¹ Beijing Key Laboratory of Environmental and Viral Oncology, Faculty of Environment and Life, Beijing University of Technology, Beijing 100124, China.
² Department of Medical Technology, Beijing Pharmaceutical University of Staff and Workers, Beijing 100079, China.
³ Chemistry Department, Trinity College, D02 PN40 Dublin, Ireland.
⁴ Carcinogenesis Department, Paterson Institute for Cancer Research, Manchester M20 9BX, UK.
⁵ Epidemiology and Public Health Group, School of Health Sciences, University of Manchester, Stopford Building, Oxford Road, Manchester M13 9PG, UK.

Abstract

O⁶-methylguanine-DNA methyltransferase (MGMT) constitutes an important cellular mechanism for repairing potentially cytotoxic DNA damage induced by guanine O⁶-alkylating agents and can render cells highly resistant to certain cancer chemotherapeutic drugs. A wide variety of potential MGMT inactivators have been designed and synthesized for the purpose of overcoming MGMT-mediated tumor resistance. We determined the inactivation potency of these compounds against human recombinant MGMT using [³H]-methylated-DNA-based MGMT inactivation assays and calculated the IC₅₀ values. Using the results of 370 compounds, we performed quantitative structure-activity relationship (QSAR) modeling to identify the correlation between the chemical structure and MGMT-inactivating ability. Modeling was based on subdividing the sorted pIC₅₀ values or on chemical structures or was random. A total of nine molecular descriptors were presented in the model equation, in which the mechanistic interpretation indicated that the status of nitrogen atoms, aliphatic primary amino groups, the presence of O-S at topological distance 3, the presence of Al-O-Ar/Ar-O-Ar/R..O..R/R-O-C=X, the ionization potential and hydrogen bond donors are the main factors responsible for inactivation ability. The final model was of high internal robustness, goodness of fit and prediction ability (R²_pr = 0.7474, Q²_Fn = 0.7375-0.7437, CCC_pr = 0.8530). After the best splitting model was decided, we established the full model based on the entire set of compounds using the same descriptor combination. We also used a similarity-based read-across technique to further improve the external predictive ability of the model (R²_pr = 0.7528, Q²_Fn = 0.7387-0.7449, CCC_pr = 0.8560). The prediction quality of 66 true external compounds was checked using the "Prediction Reliability Indicator" tool. In summary, we defined key structural features associated with MGMT inactivation, thus allowing for the design of MGMT inactivators that might improve clinical outcomes in cancer treatment.

Keywords: MGMT; MGMT activity determination; QSAR; inactivating agents; methyltransferase assay; pseudosubstrates; read-across.

Abstract

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