Design and application of scalable machine learning algorithms in molecular recognition structure prediction and drug discovery

Abstract

Starting with the problem of structure prediction we leveraged machine learning to predict DNA conformation from its sequence accurately We developed an end to end data driven approach using machine learning and free energy calculations to offer a fresh perspective on this long standing problem Besides accurately predicting the DNA conformation our model also explains why certain sequences adopt a particular conformation Transitioning from the DNA to the world of proteins we employed unsupervised learning called hierarchical clustering and our algebraic fitting algorithm to study the surface curvature of protein surfaces We later used surface curvature to assess the shape complementarity among the interacting biomolecules intending to devise a scoring algorithm for the fast selection of binders with complimentary curvature for a particular active site To find out the binding mechanism at the molecular level one needs to identify the appropriate reaction coordinate Therefore our next endeavour was to devised a novel approach based on regularized sparse autoencoders 8211 an energy based model to predict a useful and physically intuitive set of reaction coordinates Although finding strong binders is the first step towards finding a drug it is not the most crucial step since all the binders to a receptor can not be characterized as drugs which have to satisfy certain conditions called ADME condition Therefore finally we tried to address this significant problem 8211 8220 what makes a molecule a putative drug 8221 We used representation learning in conjunction with modern graph neural network architectures to learn and predict crucial attributes behind the prospective drug like activity Overall the goal of the studies carried out in the thesis is to find a fast selection of putative drugs newline newline