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Polymerase-guided base editing enables in vivo mutagenesis and rapid protein engineering

Aaron Cravens, Osman K. Jamil, Deze Kong, Jonathan T. Sockolosky, Christina D. Smolke

2021Nature Communications112 citationsDOIOpen Access PDF

Abstract

Abstract Random mutagenesis is a technique used to generate diversity and engineer biological systems. In vivo random mutagenesis generates diversity directly in a host organism, enabling applications such as lineage tracing, continuous evolution, and protein engineering. Here we describe TRIDENT (TaRgeted In vivo Diversification ENabled by T7 RNAP), a platform for targeted, continual, and inducible diversification at genes of interest at mutation rates one-million fold higher than natural genomic error rates. TRIDENT targets mutagenic enzymes to precise genetic loci by fusion to T7 RNA polymerase, resulting in mutation windows following a mutation targeting T7 promoter. Mutational diversity is tuned by DNA repair factors localized to sites of deaminase-driven mutation, enabling sustained mutation of all four DNA nucleotides at rates greater than 10 −4 mutations per bp. We show TRIDENT can be applied to routine in vivo mutagenesis applications by evolving a red-shifted fluorescent protein and drug-resistant mutants of an essential enzyme.

Topics & Concepts

MutagenesisBiologyDirected evolutionT7 RNA polymeraseProtein engineeringGeneticsMutationGenome engineeringMutation rateMutantPolymeraseDirected mutagenesisComputational biologyCRISPRTranscription activator-like effector nucleaseDNAGenome editingGeneBacteriophageEnzymeBiochemistryEscherichia coliCRISPR and Genetic EngineeringAdvanced biosensing and bioanalysis techniquesRNA and protein synthesis mechanisms
Polymerase-guided base editing enables in vivo mutagenesis and rapid protein engineering | Litcius