Abstract
BackgroundQSAR is an established and powerful method for cheap in silico assessment of physicochemical properties and biological activities of chemical compounds. However, QSAR models are rather complex mathematical constructs that cannot easily be interpreted. Medicinal chemists would benefit from practical guidance regarding which molecules to synthesize.Another possible approach is analysis of pairs of very similar molecules, so-called matched molecular pairs (MMPs). Such an approach allows identification of molecular transformations that affect particular activities (e.g. toxicity). In contrast to QSAR, chemical interpretation of these transformations is straightforward. Furthermore, such transformations can give medicinal chemists useful hints for the hit-to-lead optimization process.ResultsThe current study suggests a combination of QSAR and MMP approaches by finding MMP transformations based on QSAR predictions for large chemical datasets. The study shows that such an approach, referred to as prediction-driven MMP analysis, is a useful tool for medicinal chemists, allowing identification of large numbers of “interesting” transformations that can be used to drive the molecular optimization process. All the methodological developments have been implemented as software products available online as part of OCHEM (http://ochem.eu/).ConclusionsThe prediction-driven MMPs methodology was exemplified by two use cases: modelling of aquatic toxicity and CYP3A4 inhibition. This approach helped us to interpret QSAR models and allowed identification of a number of “significant” molecular transformations that affect the desired properties. This can facilitate drug design as a part of molecular optimization process.Graphical Molecular matched pairs and transformation graphs facilitate interpretable molecular optimisation process.
Highlights
Quantitative Structure Activity Relationships (QSAR) is an established and powerful method for cheap in silico assessment of physicochemical properties and biological activities of chemical compounds
We demonstrate the additional knowledge gained from the predictiondriven transformations and the practical value of such knowledge for the molecular optimization procedure
We suggested a new concept of prediction-driven Matched Molecular Pair (MMP), utilizing predictions given by QSARs for large chemical libraries to generate simple transformation rules that affect the activity of interest
Summary
QSAR is an established and powerful method for cheap in silico assessment of physicochemical properties and biological activities of chemical compounds. Medicinal chemists would benefit from practical guidance regarding which molecules to synthesize Another possible approach is analysis of pairs of very similar molecules, so-called matched molecular pairs (MMPs). Such an approach allows identification of molecular transformations that affect particular activities (e.g. toxicity). While interpretation of simple linear regressions can be straightforward, the most powerful algorithms like neural networks are similar to “black boxes”, which provide predictions that cannot be interpreted. This undermines trust in such predictions and prevents the creation of an “action plan” by a decision maker, for example a medicinal chemist.
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