Playing with the Molecules of Life

Young, Douglas D.; Schultz, Peter G.

doi:10.1021/acschembio.7b00974

Cited by 304 publications

(283 citation statements)

References 311 publications

(659 reference statements)

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“…(Chin, 2017; Dumas et al, 2015; Italia et al, 2017b; Mukai et al, 2017; Young and Schultz, 2018) To co-translationally incorporate an Uaa, it is encoded by a repurposed nonsense codon, which is suppressed by an orthogonal (i.e., does not cross-react with its host counterparts) Uaa-selective aminoacyl-tRNA synthetase (aaRS)/tRNA pair. (Chin, 2017; Dumas et al, 2015; Italia et al, 2017b; Mukai et al, 2017; Young and Schultz, 2018) Eukaryote or archaea derived aaRS/tRNA pairs are orthogonal in bacteria and used for Uaa incorporation, while those derived from bacteria are typically orthogonal in eukaryotes (Figure 1A). (Chin, 2017; Dumas et al, 2015; Italia et al, 2017b; Mukai et al, 2017; Young and Schultz, 2018) To create Uaa-specific variants of aaRS/tRNA pairs through directed evolution, two cell-based selection systems have been developed, using Escherichia coli(Santoro et al, 2002; Wang et al, 2001) or Saccharomyces cerevisiae (yeast)(Chin et al, 2003a; Chin et al, 2003b) as selection hosts, for engineering pairs that are orthogonal in bacteria or eukaryotes, respectively.…”

Section: Introductionmentioning

confidence: 99%

Resurrecting the Bacterial Tyrosyl-tRNA Synthetase/tRNA Pair for Expanding the Genetic Code of Both E. coli and Eukaryotes

Italia

Latour

Wrobel

et al. 2018

Cell Chemical Biology

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The bacteria-derived tyrosyl-tRNA synthetase (TyrRS)/tRNA pair was first used for unnatural amino acid (Uaa) mutagenesis in eukaryotic cells over 15 years ago. It provides an ideal platform to genetically encode numerous useful Uaas in eukaryotes. However, this pair has been engineered to charge only a small collection of Uaas to date. Development of Uaa-selective variants of this pair has been limited by technical challenges associated with a yeast-based directed evolution platform, which is currently required to alter its substrate specificity. Here we overcome this limitation by enabling its directed evolution in an engineered strain of E. coli (ATMY), where the endogenous TyrRS/tRNA pair has been functionally replaced with an archaeal counterpart. The facile E. coli-based selection system enabled rapid engineering of this pair to develop variants that selectively incorporate various Uaas, including p-boronophenylalanine, into proteins expressed in mammalian cells as well as in the ATMY strain of E. coli.

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Section: Introductionmentioning

confidence: 99%

Resurrecting the Bacterial Tyrosyl-tRNA Synthetase/tRNA Pair for Expanding the Genetic Code of Both E. coli and Eukaryotes

Italia

Latour

Wrobel

et al. 2018

Cell Chemical Biology

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“…Almost 20 years ago, Peter Schultz increased the diversity available to living organisms by expanding the genetic code using the amber stop codon (UAG) to encode ncAAs in Escherichia coli [••2,••3]. This landmark accomplishment was achieved using a tRNA–amino acid tRNA synthetase (aaRS) pair from Methanococcus jannaschii, in which the tRNA was recoded to suppress the stop codon and the aaRS was evolved to charge the tRNA with an ncAA.…”

Section: Introductionmentioning

confidence: 99%

Expansion of the genetic code via expansion of the genetic alphabet

Dien

Morris

Karadeema

et al. 2018

Current Opinion in Chemical Biology

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Current methods to expand the genetic code enable site-specific incorporation of non-canonical amino acids (ncAAs) into proteins in eukaryotic and prokaryotic cells. However, current methods are limited by the number of codons possible, their orthogonality, and possibly their effects on protein synthesis and folding. An alternative approach relies on unnatural base pairs to create a virtually unlimited number of genuinely new codons that are efficiently translated and highly orthogonal because they direct ncAA incorporation using forces other than the complementary hydrogen bonds employed by their natural counterparts. This review outlines progress and achievements made towards developing a functional unnatural base pair and its use to generate semi-synthetic organisms with an expanded genetic alphabet that serves as the basis of an expanded genetic code.

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“…[1–3] This technology has experienced remarkable progress over the last decade, facilitating its application to various domains of life. [1–3] Using this approach, over 150 different Uaas with novel sidechains have been genetically encoded to date, providing an exciting new toolset in the arsenal of synthetic biology.…”

Section: Introductionmentioning

confidence: 99%

Synthesis at the interface of virology and genetic code expansion

Kelemen

Erickson

Chatterjee

2018

Current Opinion in Chemical Biology

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How a virus efficiently invades its host cell and masterfully engineers its properties provides valuable lessons and resources for the emerging discipline of synthetic biology, which seeks to create engineered biological systems with novel functions. Recently, the toolbox of synthetic biology has also been enriched by the genetic code expansion technology, which has provided access to a large assortment of unnatural amino acids with novel chemical functionalities that can be site-specifically incorporated into proteins in living cells. The synergistic interplay of these two disciplines holds much promise to advance their individual progress, while creating new paradigms for synthetic biology. In this review we seek to provide an account of the recent advances at the interface of these two research areas.

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Playing with the Molecules of Life

Cited by 304 publications

References 311 publications

Resurrecting the Bacterial Tyrosyl-tRNA Synthetase/tRNA Pair for Expanding the Genetic Code of Both E. coli and Eukaryotes

Resurrecting the Bacterial Tyrosyl-tRNA Synthetase/tRNA Pair for Expanding the Genetic Code of Both E. coli and Eukaryotes

Expansion of the genetic code via expansion of the genetic alphabet

Synthesis at the interface of virology and genetic code expansion

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