HIV-1 Protease Catalytic Efficiency Effects Caused by Random Single Amino Acid Substitutions

doi:10.1093/molbev/msl168

MBE Advance Access originally published online on November 7, 2006
Molecular Biology and Evolution 2007 24(2):382-387; doi:10.1093/molbev/msl168

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© The Author 2006. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oxfordjournals.org

Research Articles

HIV-1 Protease Catalytic Efficiency Effects Caused by Random Single Amino Acid Substitutions

Mariona Parera, Guerau Fernàndez, Bonaventura Clotet and Miguel Angel Martínez

Fundació irsiCaixa, Universitat Autònoma de Barcelona, Barcelona, Spain

E-mail: mmartinez{at}irsicaixa.es.

Accepted for publication November 2, 2006.

Protein evolution has occurred by successive fixation of individualmutations. The probability of fixation depends on the fitnessof the mutation, and the arising variant can be deleterious,neutral, or beneficial. Despite its relevance, only few studieshave estimated the distribution of fitness effects caused byrandom single mutations on protein function. The human immunodeficiencyvirus type 1 (HIV-1) protease was chosen as a model proteinto quantify protein's tolerability to random single mutations.After determining the enzymatic activity of 107 single randommutants, we found that 86% of single mutations were deleteriousfor the enzyme catalytic efficiency and 54% lethal. Only 2%of the mutations significantly increased the catalytic efficiencyof the enzyme. These data demonstrate the vulnerability of HIV-1protease to single random mutations. When a second random mutagenesislibrary was constructed from an HIV-1 protease carrying a highlydeleterious single mutation (D30N), a higher proportion of mutationswith neutral or beneficial effect were found, 26% and 9%, respectively.Importantly, antagonist epistasis was observed between deleteriousmutations. In particular, the mutation N88D, lethal for thewild-type protease, restored the wild-type catalytic efficiencywhen combined with the highly deleterious mutation D30N. Thelow tolerability to single random substitutions shown here forthe wild-type HIV-1 protease contrasts with its in vivo abilityto generate an adaptive variation. Thus, the antagonist epistasisbetween deleterious or lethal mutations may be responsible forincreasing the protein mutational robustness and evolvability.

Key Words: protein evolution • robustness • epistasis

Edward Holmes, Associate Editor

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