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A dual gene-specific mutator system installs all transition mutations at similar frequencies <i>in vivo</i>

Daeje Seo, Bonghyun Koh, Ga-eul Eom, Hye Won Kim, Seokhee Kim

2023Nucleic Acids Research30 citationsDOIOpen Access PDF

Abstract

Targeted in vivo hypermutation accelerates directed evolution of proteins through concurrent DNA diversification and selection. Although systems employing a fusion protein of a nucleobase deaminase and T7 RNA polymerase present gene-specific targeting, their mutational spectra have been limited to exclusive or dominant C:G→T:A mutations. Here we describe eMutaT7transition, a new gene-specific hypermutation system, that installs all transition mutations (C:G→T:A and A:T→G:C) at comparable frequencies. By using two mutator proteins in which two efficient deaminases, PmCDA1 and TadA-8e, are separately fused to T7 RNA polymerase, we obtained similar numbers of C:G→T:A and A:T→G:C substitutions at a sufficiently high frequency (∼6.7 substitutions in 1.3 kb gene during 80-h in vivo mutagenesis). Through eMutaT7transition-mediated TEM-1 evolution for antibiotic resistance, we generated many mutations found in clinical isolates. Overall, with a high mutation frequency and wider mutational spectrum, eMutaT7transition is a potential first-line method for gene-specific in vivo hypermutation.

Topics & Concepts

BiologySomatic hypermutationGeneticsMutagenesisGenePolymeraseMutationTransition (genetics)Molecular biologyRNA polymeraseRNAB cellAntibodyCRISPR and Genetic EngineeringPlant Virus Research StudiesRNA and protein synthesis mechanisms