Genomically Recoded Organisms Expand Biological Functions

Lajoie, Marc J.; Rovner, Alexis J.; Goodman, Daniel B.; Aerni, Hans R.; Haimovich, Adrian D.; Kuznetsov, Gleb; Mercer, Jaron A. M.; Wang, Harris H.; Carr, Peter A.; Mosberg, Joshua A.; Rohland, Nadin; Schultz, Peter G.; Jacobson, Joseph M.; Rinehart, Jesse; Church, George M.; Isaacs, Farren J.

doi:10.1126/science.1241459

articleScienceOct 17, 2013GREEN OA

Genomically Recoded Organisms Expand Biological Functions

MJMarc J. LajoieAJAlexis J. Rovner DBDaniel B. Goodman HRHans R. Aerni ADAdrian D. Haimovich

Harvard University · Yale University · +8 more institutions

PubMed

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Abstract

Changing the Code Easily and efficiently expanding the genetic code could provide tools to genome engineers with broad applications in medicine, energy, agriculture, and environmental safety. Lajoie et al. (p. 357 ) replaced all known UAG stop codons with synonymous UAA stop codons in Escherichia coli MG1655, as well as release factor 1 (RF1; terminates translation at UAG), thereby eliminating natural UAG translation function without impairing fitness. This made it possible to reassign UAG as a dedicated codon to genetically encode nonstandard amino acids while avoiding deleterious incorporation at native UAG positions. The engineered E. coli incorporated nonstandard amino acids into its proteins and showed…

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Biology

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