Molecular mechanisms and design principles for promiscuous inhibitors to avoid drug resistance: Lessons learned from HIV-1 protease inhibition

ABSTRACT Molecular recognition is central to biology and ranges from highly selective to broadly promiscuous. The ability to modulate specificity at will is particularly important for drug development, and discovery of mechanisms contributing to binding specificity is crucial for our basic understan...

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Published in:Proteins, structure, function, and bioinformatics structure, function, and bioinformatics, 2015-02, Vol.83 (2), p.351-372
Main Authors: Shen, Yang, Radhakrishnan, Mala L., Tidor, Bruce
Format: Article
Language:English
Subjects:
binding specificity
Catalytic Domain
Darunavir
drug cocktails
Drug Design
drug design principles
drug resistance
Drug Resistance, Viral
HIV Protease - chemistry
HIV Protease Inhibitors - chemistry
Human immunodeficiency virus 1
Hydrogen Bonding
Hydrophobic and Hydrophilic Interactions
Models, Molecular
molecular mechanisms
Protein Binding
Sulfonamides - chemistry
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container_title Proteins, structure, function, and bioinformatics
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creator Shen, Yang
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description ABSTRACT Molecular recognition is central to biology and ranges from highly selective to broadly promiscuous. The ability to modulate specificity at will is particularly important for drug development, and discovery of mechanisms contributing to binding specificity is crucial for our basic understanding of biology and for applications in health care. In this study, we used computational molecular design to create a large dataset of diverse small molecules with a range of binding specificities. We then performed structural, energetic, and statistical analysis on the dataset to study molecular mechanisms of achieving specificity goals. The work was done in the context of HIV‐1 protease inhibition and the molecular designs targeted a panel of wild‐type and drug‐resistant mutant HIV‐1 protease structures. The analysis focused on mechanisms for promiscuous binding to bind robustly even to resistance mutants. Broadly binding inhibitors tended to be smaller in size, more flexible in chemical structure, and more hydrophobic in nature compared to highly selective ones. Furthermore, structural and energetic analyses illustrated mechanisms by which flexible inhibitors achieved binding; we found ligand conformational adaptation near mutation sites and structural plasticity in targets through torsional flips of asymmetric functional groups to form alternative, compensatory packing interactions or hydrogen bonds. As no inhibitor bound to all variants, we designed small cocktails of inhibitors to do so and discovered that they often jointly covered the target set through mechanistic complementarity. Furthermore, using structural plasticity observed in experiments, and potentially in simulations, is suggested to be a viable means of designing adaptive inhibitors that are promiscuous binders. Proteins 2015; 83:351–372. © 2014 Wiley Periodicals, Inc.
doi_str_mv 10.1002/prot.24730
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Furthermore, structural and energetic analyses illustrated mechanisms by which flexible inhibitors achieved binding; we found ligand conformational adaptation near mutation sites and structural plasticity in targets through torsional flips of asymmetric functional groups to form alternative, compensatory packing interactions or hydrogen bonds. As no inhibitor bound to all variants, we designed small cocktails of inhibitors to do so and discovered that they often jointly covered the target set through mechanistic complementarity. Furthermore, using structural plasticity observed in experiments, and potentially in simulations, is suggested to be a viable means of designing adaptive inhibitors that are promiscuous binders. 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subjects binding specificity
Catalytic Domain
Darunavir
drug cocktails
Drug Design
drug design principles
drug resistance
Drug Resistance, Viral
HIV Protease - chemistry
HIV Protease Inhibitors - chemistry
Human immunodeficiency virus 1
Hydrogen Bonding
Hydrophobic and Hydrophilic Interactions
Models, Molecular
molecular mechanisms
Protein Binding
Sulfonamides - chemistry
title Molecular mechanisms and design principles for promiscuous inhibitors to avoid drug resistance: Lessons learned from HIV-1 protease inhibition
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