Drug Design in the Exascale Era: A Perspective from Massively Parallel QM/MM Simulations

Raghavan, Bharath; Paulikat, Mirko; Ahmad, Katya; Callea, Lara; Rizzi, Andrea; Ippoliti, Emiliano; Mandelli, Davide; Bonati, Laura; Vivo, Marco De; Carloni, Paolo

doi:10.1021/acs.jcim.3c00557

Cited by 20 publications

(7 citation statements)

References 126 publications

(216 reference statements)

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“…The hardware and software improvements—also considering the emerging era of quantum computing—together with the continuously evolving ML techniques will undoubtedly play a leading role in the coming years, hopefully making this kind of calculations less demanding and useful for ligand database screening protocols. In this regard, one could expect that even quantum mechanical calculations—now considered unfeasible for ligand binding studies 203 —might at least integrate the atomistic level description of LPB. In the present article, we have discussed three macro areas that could be further improved, which are molecular properties parametrization, sampling, and data openness.…”

Section: Discussionmentioning

confidence: 99%

Perspectives on Ligand/Protein Binding Kinetics Simulations: Force Fields, Machine Learning, Sampling, and User-Friendliness

Conflitti,

Raniolo,

Limongelli

2023

J. Chem. Theory Comput.

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Computational techniques applied to drug discovery have gained considerable popularity for their ability to filter potentially active drugs from inactive ones, reducing the time scale and costs of preclinical investigations. The main focus of these studies has historically been the search for compounds endowed with high affinity for a specific molecular target to ensure the formation of stable and long-lasting complexes. Recent evidence has also correlated the in vivo drug efficacy with its binding kinetics, thus opening new fascinating scenarios for ligand/protein binding kinetic simulations in drug discovery. The present article examines the state of the art in the field, providing a brief summary of the most popular and advanced ligand/protein binding kinetics techniques and evaluating their current limitations and the potential solutions to reach more accurate kinetic models. Particular emphasis is put on the need for a paradigm change in the present methodologies toward ligand and protein parametrization, the force field problem, characterization of the transition states, the sampling issue, and algorithms' performance, user-friendliness, and data openness.

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Section: Discussionmentioning

confidence: 99%

Perspectives on Ligand/Protein Binding Kinetics Simulations: Force Fields, Machine Learning, Sampling, and User-Friendliness

Conflitti,

Raniolo,

Limongelli

2023

J. Chem. Theory Comput.

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“…Further, many phenomena in biology, including enzyme catalysis, proton pumping, and electron transfer reactions, require a quantum mechanical treatment necessitating the use of QM/MM methods or quantum-based surrogate models . Some of them have been massively parallelized in order to exploit exascale resources for modeling large systems. , Finally, while extensive work has gone into optimizing molecular force fields that mimic the basic interactions between atoms, it is now accepted that electronic polarization and many-body dispersion forces can contribute substantially and can even qualitatively alter the equilibrium structures and self-assembly dynamics . These effects will move to the fore and require additional capabilities as we attempt to model large assemblies at an accurate level …”

Section: Scaling Up Biomolecular Simulationsmentioning

confidence: 99%

All-Atom Biomolecular Simulation in the Exascale Era

Beck,

Carloni,

Asthagiri

2024

J. Chem. Theory Comput.

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Exascale supercomputers have opened the door to dynamic simulations, facilitated by AI/ML techniques, that model biomolecular motions over unprecedented length and time scales. This new capability holds the potential to revolutionize our understanding of fundamental biological processes. Here we report on some of the major advances that were discussed at a recent CECAM workshop in Pisa, Italy, on the topic with a primary focus on atomic-level simulations. First, we highlight examples of current large-scale biomolecular simulations and the future possibilities enabled by crossing the exascale threshold. Next, we discuss challenges to be overcome in optimizing the usage of these powerful resources. Finally, we close by listing several grand challenge problems that could be investigated with this new computer architecture.

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“…Additionally, all of these processes occur over tens to hundreds of Å, a scale that significantly challenges the actual multiscale implementations. Furthermore, some of these phenomena still extend beyond current computational power as they would require QM simulations to span in the ns time scale, ,,, while the MM part should account for heavy atom motion occurring in the μs or ms time scales. In this regard, some promising results have been recently achieved using MLIPs techniques, as discussed in Sec…”

Section: Our Future Visionmentioning

confidence: 99%

A Vision for the Future of Multiscale Modeling

Capone,

Romanelli,

Castaldo

et al. 2024

ACS Phys. Chem Au

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The rise of modern computer science enabled physical chemistry to make enormous progresses in understanding and harnessing natural and artificial phenomena. Nevertheless, despite the advances achieved over past decades, computational resources are still insufficient to thoroughly simulate extended systems from first principles. Indeed, countless biological, catalytic and photophysical processes require ab initio treatments to be properly described, but the breadth of length and time scales involved makes it practically unfeasible. A way to address these issues is to couple theories and algorithms working at different scales by dividing the system into domains treated at different levels of approximation, ranging from quantum mechanics to classical molecular dynamics, even including continuum electrodynamics. This approach is known as multiscale modeling and its use over the past 60 years has led to remarkable results. Considering the rapid advances in theory, algorithm design, and computing power, we believe multiscale modeling will massively grow into a dominant research methodology in the forthcoming years. Hereby we describe the main approaches developed within its realm, highlighting their achievements and current drawbacks, eventually proposing a plausible direction for future developments considering also the emergence of new computational techniques such as machine learning and quantum computing. We then discuss how advanced multiscale modeling methods could be exploited to address critical scientific challenges, focusing on the simulation of complex light-harvesting processes, such as natural photosynthesis. While doing so, we suggest a cutting-edge computational paradigm consisting in performing simultaneous multiscale calculations on a system allowing the various domains, treated with appropriate accuracy, to move and extend while they properly interact with each other. Although this vision is very ambitious, we believe the quick development of computer science will lead to both massive improvements and widespread use of these techniques, resulting in enormous progresses in physical chemistry and, eventually, in our society.

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Drug Design in the Exascale Era: A Perspective from Massively Parallel QM/MM Simulations

Cited by 20 publications

References 126 publications

Perspectives on Ligand/Protein Binding Kinetics Simulations: Force Fields, Machine Learning, Sampling, and User-Friendliness

Perspectives on Ligand/Protein Binding Kinetics Simulations: Force Fields, Machine Learning, Sampling, and User-Friendliness

All-Atom Biomolecular Simulation in the Exascale Era

A Vision for the Future of Multiscale Modeling

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