Constrained Mutational Sampling of Amino Acids in HIV-1 Protease Evolution

Overview

Journal Mol Biol Evol

Publisher Oxford University Press

Specialty Biology

Date 2019 Feb 6

PMID 30721995

Citations 6

Authors

Jeffrey I Boucher

Troy W Whitfield

Ann Dauphin

Gily Nachum

Carl Hollins

Konstantin B Zeldovich

Ronald Swanstrom

Celia A Schiffer

Jeremy Luban

Daniel N A Bolon

Affiliations

Soon will be listed here.

Abstract

The evolution of HIV-1 protein sequences should be governed by a combination of factors including nucleotide mutational probabilities, the genetic code, and fitness. The impact of these factors on protein sequence evolution is interdependent, making it challenging to infer the individual contribution of each factor from phylogenetic analyses alone. We investigated the protein sequence evolution of HIV-1 by determining an experimental fitness landscape of all individual amino acid changes in protease. We compared our experimental results to the frequency of protease variants in a publicly available data set of 32,163 sequenced isolates from drug-naïve individuals. The most common amino acids in sequenced isolates supported robust experimental fitness, indicating that the experimental fitness landscape captured key features of selection acting on protease during viral infections of hosts. Amino acid changes requiring multiple mutations from the likely ancestor were slightly less likely to support robust experimental fitness than single mutations, consistent with the genetic code favoring chemically conservative amino acid changes. Amino acids that were common in sequenced isolates were predominantly accessible by single mutations from the likely protease ancestor. Multiple mutations commonly observed in isolates were accessible by mutational walks with highly fit single mutation intermediates. Our results indicate that the prevalence of multiple-base mutations in HIV-1 protease is strongly influenced by mutational sampling.

Citing Articles

Kinetic coevolutionary models predict the temporal emergence of HIV-1 resistance mutations under drug selection pressure.

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Sequence dependencies and biophysical features both govern cleavage of diverse cut-sites by HIV protease.

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Analyses of HIV proteases variants at the threshold of viability reveals relationships between processing efficiency and fitness.

Schneider-Nachum G, Flynn J, Mavor D, Schiffer C, Bolon D Virus Evol. 2022; 7(2):veab103.

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Limits to detecting epistasis in the fitness landscape of HIV.

Biswas A, Haldane A, Levy R PLoS One. 2022; 17(1):e0262314.

PMID: 35041711 PMC: 8765623. DOI: 10.1371/journal.pone.0262314.

Predominance of positive epistasis among drug resistance-associated mutations in HIV-1 protease.

Zhang T, Dai L, Barton J, Du Y, Tan Y, Pang W PLoS Genet. 2020; 16(10):e1009009.

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