Please note: This seminar will be given online.
Octavian Ganea, Postdoctoral researcher
Computer Science & Artificial Intelligence Laboratory, MIT
Understanding 3D structures and interactions of biological nano-machines, such as proteins or drug-like molecules, is crucial for assisting drug and therapeutics discovery. A core problem is molecular docking, i.e., determining how two proteins or a protein and a drug-molecule attach and create a molecular complex. Having access to very fast computational docking tools would enable applications such as fast virtual search for drugs inhibiting disease proteins, in silico molecular design, or rapid drug side-effect prediction. However, existing computer models follow a very time-consuming strategy of sampling a large number (e.g., millions) of molecular complex candidates, followed by scoring, ranking, and fine-tuning steps.
In this talk, I will show that geometry and deep learning (DL) can significantly reduce the enormous search space associated with the docking and molecular conformation problems. I will present my recent DL architectures, EquiDock and EquiBind, that perform a direct shot prediction of the molecular complex, and GeoMol, that models molecular flexibility. I will argue that the governing laws of geometry, physics, or chemistry that naturally constrain these 3D structures should be incorporated in DL solutions in a mathematically meaningful way. I will explain our key modeling concepts such as SE(3)-equivariant graph matching networks, attention keypoint sets, optimal transport for binding pocket prediction, and torsion angle neural networks. These approaches reduce the inference runtimes of open-source or commercial software from tens of minutes or hours to a few seconds, while being competitive or better in terms of quality. Finally, I will highlight a number of exciting on-going and future efforts in the space of artificial intelligence for structural biology and chemistry.
Bio: Octavian Ganea is a postdoctoral researcher at CSAIL-MIT working with Tommi Jaakkola and Regina Barzilay on AI solutions for drug discovery and structural biology using geometric and physical inductive biases. He is part of the Machine Learning for Pharmaceutical Discovery and Synthesis consortium, the Abdul Latif Jameel Clinic for Machine Learning in Health, the DARPA Accelerated Molecular Discovery program, and the ELLIS society. Octavian received his PhD from the Data Analytics Lab at ETH Zurich under the supervision of Thomas Hofmann working on non-Euclidean representation learning for graphs, hierarchical data, and natural language processing.