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Gate-based quantum computing for protein design

Mohammad Hassan Khatami, Udson C. Mendes, Nathan Wiebe, Philip M. Kim

2023PLoS Computational Biology25 citationsDOIOpen Access PDF

Abstract

Protein design is a technique to engineer proteins by permuting amino acids in the sequence to obtain novel functionalities. However, exploring all possible combinations of amino acids is generally impossible due to the exponential growth of possibilities with the number of designable sites. The present work introduces circuits implementing a pure quantum approach, Grover's algorithm, to solve protein design problems. Our algorithms can adjust to implement any custom pair-wise energy tables and protein structure models. Moreover, the algorithm's oracle is designed to consist of only adder functions. Quantum computer simulators validate the practicality of our circuits, containing up to 234 qubits. However, a smaller circuit is implemented on real quantum devices. Our results show that using [Formula: see text] iterations, the circuits find the correct results among all N possibilities, providing the expected quadratic speed up of Grover's algorithm over classical methods (i.e., [Formula: see text]).

Topics & Concepts

Quantum computerComputer scienceProtein designQuantumComputational biologyPhysicsProtein structureBiologyQuantum mechanicsNuclear magnetic resonanceQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum-Dot Cellular Automata
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