Abstract
Publicly available kinase inhibitors provide a large source of information for structure–activity relationship analysis and kinase drug design. In this study, publicly available inhibitors of the human kinome were collected and analog series formed by kinase inhibitors systematically identified. Then, alternative scaffold concepts were applied to assess diversity and promiscuity of kinase inhibitors. Over the past two years, the number of publicly available kinase inhibitors with high-confidence activity data more than doubled, but coverage of the human kinome only slightly increased. Approximately 70% of current kinase inhibitors belonged to analog series. However, the detectable degree of promiscuity among these kinase inhibitors remained low. Approximately 76% of all inhibitors were only annotated with a single kinase, compared to ~70% two years ago. For many kinases, the assessment of scaffold diversity among their inhibitors and the distribution of differently defined scaffolds over analog series made it possible to assess scaffold hopping potential. Our analysis revealed that the consideration of conventional compound-based scaffolds most likely leads to an overestimation of scaffold hopping frequency, at least for compounds forming analog series.
Highlights
In medicinal chemistry, structural diversity of compound collections is frequently assessed at the level of core structures or scaffolds [1]
Our analysis revealed that the consideration of conventional compound-based scaffolds most likely leads to an overestimation of scaffold hopping frequency, at least for compounds forming analog series
Structural diversity of compound collections is frequently assessed at the level of core structures or scaffolds [1]
Summary
Structural diversity of compound collections is frequently assessed at the level of core structures or scaffolds [1]. The term scaffold hopping refers to the computational search for active compounds containing different core structures [3,4]. For the majority of pharmaceutically relevant targets, active compounds are available that contain large numbers of different BM scaffolds [5,6]. In these cases, active compounds represent many scaffold hops and newly identified hits may likely contain additional scaffolds. We have introduced a different scaffold concept for computational analysis to further increase the utility of scaffolds for medicinal chemistry applications [14] As indicated by their name, analog series-based (ASB) scaffolds were designed to represent compound series and take reaction information into account [14]. Hopping potential for different kinases evaluated on the basis of alternative scaffolds concepts
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