Lecture – QCMS

April 12, 2026April 12, 2026

QCMS Online Seminar Series Continues May 28th, 2026

QCMS continues its Online Seminar Series with a new session to be held on May 28, 2026, from 4:00 to 6:15 pm (CET). Thanks to the efforts of the QCMS Webinar Organisation Team, this session brings together an outstanding lineup of invited speakers.

Invited Lecture 1

Entering the Era of Physical AI in Drug Discovery
WOODY SHERMAN
4:00-4:45 pm CET

Abstract: Artificial intelligence is changing how scientific work is performed, but the core challenges of drug discovery remain. Progress still depends on solving difficult predictive problems rooted in the physical world, including molecular interactions, conformational dynamics, binding energetics, chemical reactivity, and the multiparameter tradeoffs that determine whether a molecule can become a medicine. These grand challenges are unlikely to be solved by language-based AI alone. They will require advances in what may be called Physical AI: predictive systems that integrate machine learning with physics, simulation, experiment, and expert judgment. This talk will examine the emerging role of Physical AI in drug discovery and the conditions under which it can materially improve outcomes. It will outline a spectrum of problem types, ranging from those that may benefit primarily from large-scale data-driven learning to those that still require explicit physical modeling or tightly coupled hybrid approaches. It will also discuss the importance of closed-loop workflows that combine AI, simulation, and fit-for-purpose assays, as well as the implications for foundation models, open scientific infrastructure, and the measurable bottlenecks that must be addressed if AI is to improve candidate.

Biography: Woody Sherman is the Founder and Chief Innovation Officer of PsiThera, where he leads the development of a computational-first drug discovery platform advancing oral small-molecule medicines for high-value immunology and inflammation targets traditionally addressed by biologics. He is also Chair of the OpenFold Consortium Executive Committee, guiding a global open science effort to build next-generation foundation models for biomolecular structure and drug design that are shaping the future of the field. Across industry and academia, Woody has been a pioneer in applying physics-based simulation, AI/ML, and integrated experimental-computational workflows to solve real-world drug discovery problems. His career spans leadership roles as Chief Computational Scientist at Roivant Sciences, Chief Scientific Officer at Silicon Therapeutics, and Global Head of Applications Science at Schrödinger, where he helped translate advanced modeling technologies into widely adopted discovery tools. Woody has authored over 100 peer-reviewed publications spanning molecular simulation, free energy methods, protein structure and dynamics, machine learning, and structure-based drug design, and is an Adjunct Professor at the University of Massachusetts Amherst. His work bridges deep technical innovation with strategic vision for how computational technologies can materially transform the speed, cost, and probability of success in drug discovery.

Invited Lecture 2

Deep Learning for Structure-Based Drug Discovery: From Scoring to Generative Design
DAVID R. KOES
4:45-5:30 pm CET

Abstract: Structure-based drug discovery has been transformed by the integration of deep learning, enabling more accurate modeling of protein-ligand interactions and the scalable exploration of chemical space. In this talk, I will present our work developing and applying deep convolutional neural networks (CNNs) for protein-ligand scoring, docking, and virtual screening, with a focus on our open-source docking software GNINA. These models have demonstrated strong performance in both retrospective benchmarks and prospective applications, including results from the CACHE community wide assessment. We additionally describe SPRINT, a vector-based approach for rapidly screening large chemical libraries. We show how SPRINT can be productively incorporated into a deep docking pipeline for virtual screening. He will then discuss how these CNN architectures form the foundation for LiGAN, an early generative model that learns to propose 3D ligand structures directly within a protein binding site. Extending beyond CNNs, I will describe more recent efforts using graph-based deep generative models for both unconditional molecule generation and conditional design with a focus on our state-of-the-art FlowMol flow matching model and recently released OMTRA multi-task generative model.

Biography: David R. Koes is an Associate Professor at the University of Pittsburgh in the Department of Computational and Systems Biology, where he also serves as Vice Chair of Education and Co-Director of the joint Carnegie Mellon–University of Pittsburgh PhD Program in Computational Biology. He received his PhD in Computer Science from Carnegie Mellon University and completed postdoctoral training in computational biology. His research focuses on advancing computational drug discovery through the integration of machine learning, structural biology, and algorithm development. He is a leading contributor to widely used open-source tools such as GNINA and Pharmit, which enable structure-based virtual screening and molecular docking with deep learning. His work has significantly contributed to the application of 3D convolutional neural networks and generative models in drug design, as well as scalable methods for exploring large chemical spaces. Koes is actively involved in the scientific community through peer review, conference organization, and NIH study sections. He has mentored numerous graduate and undergraduate students and contributed extensively to education in computational biology. His research has been recognized with several awards, and his software tools are widely adopted in both academia and industry, supporting real-world drug discovery efforts.

Invited Lecture 3

Boltz: Towards Accurate Biomolecular Modeling and Design
GABRIELE CORSO
5:30-6:15 pm CET

Abstract: Accurately modeling biomolecular interactions is a central challenge in modern biology. Recent advances have substantially improved our ability to predict biomolecular complex structures, understand the strength of interactions and design novel binders. We will present some of our open-source (Boltz-1, Boltz-2 and BoltzGen) and proprietary work pushing the frontier across all of these tasks and how these come together in accurate pipelines for structure-based biologics and small-molecule design.

Biography: Gabriele Corso is the CEO and co-founder of Boltz PBC, a company aiming to advance biomolecular modeling and making it accessible to scientists. Gabriele received his PhD from MIT CSAIL where his research focused on developing novel ML frameworks to tackle challenging problems in drug discovery and he led the development of popular models in the space including DiffDock, Boltz-1 and Boltz-2.

The seminar will be held online, and the access link will be shared only with registered participants.
Please register here:

December 12, 2025April 1, 2026

QCMS Annual General Meeting 2025

On November 20th, the QSAR, Chemoinformatics and Modeling Society (QCMS) held its Annual General Meeting. The session was chaired by Prof. Rebecca Wade of the University of Heidelberg and featured the QCMS Invited Lecture delivered by Prof. Harel Weinstein, Maxwell Upson Professor of Physiology and Biophysics and Director of the Institute for Computational Biomedicine at Weill Cornell Medical College.

Prof. Weinstein presented an in-depth analysis of allosteric communication, outlining how intrinsic pathways within proteins can be identified and used to modulate function. He also discussed applications that employ AI and machine learning to investigate enzymatic and intracellular systems. The lecture offered a clear view of how quantitative approaches can support the development of new therapeutic strategies and the engineering of biological processes.

We are also pleased to announce that QCMS now has an official YouTube channel, where the full lecture is available for viewing. This platform will serve as a hub for future talks, events, and educational content.

Watch the lecture here.

October 3, 2025October 15, 2025

Announcement: Annual General Meeting of QCMS

The Annual General Meeting (AGM) of QCMS will take place online on November 20th, 2025, at 16:00 CET.

The meeting will be held on zoom. To attend, please register by sending a short email with “AGM2025” in the subject line to info _at_ qsar.org

The meeting will open with an invited lecture by Prof. Harel Weinstein, Maxwell M. Upson Professor of Physiology and Biophysics at Cornell University.

Following the lecture, the meeting will proceed according to the standard order of business:

Report of activities (Scientific Director and President)

Financial report (past year and budget forecast)

Other matters

We warmly encourage all members to participate in this important annual event.

QCMS Invited Lecture 2025

Biology’s ubiquitous mechanism of allosteric communication is a designer’s ally if treated with… intelligence

It is now well established that allostery – the propagation of information over long distances at the molecular and cellular scale formalized by Monod/Changeux/Jacob – is a common and pervasive mechanism in biology. Because allosteric communication underlies function in a vast number of biomolecular systems, it is not surprising that the quest for modulators of biological function at the molecular and systems levels stumbled eventually on “allosteric modulation”. Under this name hide two different concepts: one is the modulation of the action of one ligand (the “orthosteric binder”) by another (the “allosteric binder”); the other is the modulation of the intrinsic allosteric communication that underlies the functional process itself. These two different concepts are essential, each in its own way, for enabling the design of therapeutic modalities and of various means to repair, or to mimic in engineered systems, various biological processes and molecular machines.
This presentation will focus on approaches to discover the intrinsic allosteric communication pathways in proteins, and harness their allosteric communication mechanism to modulate their functional processes. Specific applications to enzymatic and intracellular traffic machines using AI and Machine Learning approaches will illustrate such quantitative treatments of allosteric communication that generalize to address the modulation of broad spectrum of biomolecular functions.

Harel Weinstein, D.Sc. is the Maxwell Upson Professor of Physiology and Biophysics and Director of the Institute for Computational Biomedicine at Weill Cornell Medical College of Cornell University in New York City.

As a Tri-Institutional Professor, he holds professorial appointments at Rockefeller University, Sloan-Kettering Institute and Cornell University. His lab is devoted to studies in molecular and computational biophysics that address complex systems in physiology, and to the development and application of bioinformatics and AI/ML approaches to systems biology. The biomedical endpoints are signaling and neurotransmission in health and disease mechanisms, cancer, and with a recent special emphasis on translational aspects in ligand design and novel therapeutic modalities in combating infection. As the founding director of the Institute for Computational Biomedicine he has developed an academic and research unit responsible for a novel approach to biomedicine that involves the mathematical, physical, and computational sciences in combination with engineering and medical informatics, to seek a quantitative understanding of physiological function and disease, in an integrative, multi-scale approach based on gene structure and defects responsible for properties and behaviors at all levels–from protein, to cell, tissue and organ. He has received numerous honors and awards including election to Fellow of the Biophysical Society (FBPS, 2018), of the Physiological Society (FAPS, 2019), and of the American Association for the Advancement of Science (FAAAS, 2022). He served on the Executive Board of the International Society for Computational Biology and various Committees, was elected President of the Biophysical Society (2008) and served as Past President till 2011. He also served as President of the Association of Chairmen of Departments of Physiology, President of the International Society for Quantum Biology and Pharmacology, Chair of the Biophysics Section of the New York Academy of Sciences and Councilor of the Biophysical Society and of the New York Academy of Medicine.