Litcius/Paper detail

Quantum Annealing Designs Nonhemolytic Antimicrobial Peptides in a Discrete Latent Space

Andrejs Tučs, Francois Berenger, Akiko Yumoto, Ryo Tamura, Takanori Uzawa, Koji Tsuda

2023ACS Medicinal Chemistry Letters27 citationsDOIOpen Access PDF

Abstract

Increasing the variety of antimicrobial peptides is crucial in meeting the global challenge of multi-drug-resistant bacterial pathogens. While several deep-learning-based peptide design pipelines are reported, they may not be optimal in data efficiency. High efficiency requires a well-compressed latent space, where optimization is likely to fail due to numerous local minima. We present a multi-objective peptide design pipeline based on a discrete latent space and D-Wave quantum annealer with the aim of solving the local minima problem. To achieve multi-objective optimization, multiple peptide properties are encoded into a score using non-dominated sorting. Our pipeline is applied to design therapeutic peptides that are antimicrobial and non-hemolytic at the same time. From 200 000 peptides designed by our pipeline, four peptides proceeded to wet-lab validation. Three of them showed high anti-microbial activity, and two are non-hemolytic. Our results demonstrate how quantum-based optimizers can be taken advantage of in real-world medical studies.

Topics & Concepts

Maxima and minimaPipeline (software)Computer scienceQuantumPeptideAntimicrobialSimulated annealingQuantum annealingAntimicrobial peptidesComputational biologyCombinatorial chemistryBiologyChemistryMachine learningMathematicsBiochemistryPhysicsQuantum computerMicrobiologyMathematical analysisQuantum mechanicsProgramming languageAntimicrobial Peptides and Activitiesvaccines and immunoinformatics approachesChemical Synthesis and Analysis