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High-Efficiency Multi-site Genomic Editing of Pseudomonas putida through Thermoinducible ssDNA Recombineering

Tomás Aparicio, Ákos Nyerges, Esteban Martínez‐García, Vı́ctor de Lorenzo

2020iScience44 citationsDOIOpen Access PDF

Abstract

/cI857 system. Cycles of short thermal shifts followed by transformation with a suite of mutagenic oligos delivered different types of genomic changes at frequencies up to 10% per single modification. The same approach was instrumental to super-diversify short chromosomal portions for creating libraries of functional genomic segments-e.g., ribosomal-binding sites. These results enabled multiplexing of genome engineering of P. putida, as required for metabolic reprogramming of this important synthetic biology chassis.

Topics & Concepts

RecombineeringRecombinasePseudomonas putidaBiologyGenome editingComputational biologyGenomeGenome engineeringSynthetic biologyHomologous recombinationGeneticsDNARecombinationGeneCRISPR and Genetic EngineeringBacterial Genetics and BiotechnologyMicrobial Fuel Cells and Bioremediation
High-Efficiency Multi-site Genomic Editing of Pseudomonas putida through Thermoinducible ssDNA Recombineering | Litcius