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2. RNA-Dependent Cysteine Biosynthesis in Bacteria and Archaea

Author

Mukai, Takahito, Crnković, Ana, Umehara, Takuya, Ivanova, Natalia N, Kyrpides, Nikos C, Söll, Dieter, Ibba, Michael, and Whitman, William

Subjects
Rare Diseases, Human Genome, Genetics, Amino Acyl-tRNA Synthetases, Archaea, Archaeal Proteins, Bacteria, Computational Biology, Crystallography, X-Ray, Cysteine, Genetic Code, Genome, Archaeal, Genome, Bacterial, Phosphoserine, Protein Binding, Protein Biosynthesis, RNA, Archaeal, RNA, Bacterial, RNA, Transfer, Amino Acyl, RNA, Transfer, Cys, Sulfur, biochemistry, bioinformatics, cysteine biosynthesis, genetic code, translation, Microbiology
Abstract

The diversity of the genetic code systems used by microbes on earth is yet to be elucidated. It is known that certain methanogenic archaea employ an alternative system for cysteine (Cys) biosynthesis and encoding; tRNACys is first acylated with phosphoserine (Sep) by O-phosphoseryl-tRNA synthetase (SepRS) and then converted to Cys-tRNACys by Sep-tRNA:Cys-tRNA synthase (SepCysS). In this study, we searched all genomic and metagenomic protein sequence data in the Integrated Microbial Genomes (IMG) system and at the NCBI to reveal new clades of SepRS and SepCysS proteins belonging to diverse archaea in the four major groups (DPANN, Euryarchaeota, TACK, and Asgard) and two groups of bacteria ("Candidatus Parcubacteria" and Chloroflexi). Bacterial SepRS and SepCysS charged bacterial tRNACys species with cysteine in vitro Homologs of SepCysE, a scaffold protein facilitating SepRS⋅SepCysS complex assembly in Euryarchaeota class I methanogens, are found in a few groups of TACK and Asgard archaea, whereas the C-terminally truncated homologs exist fused or genetically coupled with diverse SepCysS species. Investigation of the selenocysteine (Sec)- and pyrrolysine (Pyl)-utilizing traits in SepRS-utilizing archaea and bacteria revealed that the archaea carrying full-length SepCysE employ Sec and that SepRS is often found in Pyl-utilizing archaea and Chloroflexi bacteria. We discuss possible contributions of the SepRS-SepCysS system for sulfur assimilation, methanogenesis, and other metabolic processes requiring large amounts of iron-sulfur enzymes or Pyl-containing enzymes.IMPORTANCE Comprehensive analyses of all genomic and metagenomic protein sequence data in public databases revealed the distribution and evolution of an alternative cysteine-encoding system in diverse archaea and bacteria. The finding that the SepRS-SepCysS-SepCysE- and the selenocysteine-encoding systems are shared by the Euryarchaeota class I methanogens, the Crenarchaeota AK8/W8A-19 group, and an Asgard archaeon suggests that ancient archaea may have used both systems. In contrast, bacteria may have obtained the SepRS-SepCysS system from archaea. The SepRS-SepCysS system sometimes coexists with a pyrrolysine-encoding system in both archaea and bacteria. Our results provide additional bioinformatic evidence for the contribution of the SepRS-SepCysS system for sulfur assimilation and diverse metabolisms which require vast amounts of iron-sulfur enzymes and proteins. Among these biological activities, methanogenesis, methylamine metabolism, and organohalide respiration may have local and global effects on earth. Taken together, uncultured bacteria and archaea provide an expanded record of the evolution of the genetic code.

Published
2017

3. Transfer RNAs with novel cloverleaf structures

Author

Mukai, Takahito, Vargas-Rodriguez, Oscar, Englert, Markus, Tripp, H James, Ivanova, Natalia N, Rubin, Edward M, Kyrpides, Nikos C, and Söll, Dieter

Subjects
Biological Sciences, Genetics, Anticodon, Bacteria, Bacterial Toxins, Nucleic Acid Conformation, Protein Biosynthesis, RNA, Bacterial, RNA, Transfer, RNA, Transfer, Amino Acid-Specific, RNA, Transfer, Cys, Environmental Sciences, Information and Computing Sciences, Developmental Biology, Biological sciences, Chemical sciences, Environmental sciences
Abstract

We report the identification of novel tRNA species with 12-base pair amino-acid acceptor branches composed of longer acceptor stem and shorter T-stem. While canonical tRNAs have a 7/5 configuration of the branch, the novel tRNAs have either 8/4 or 9/3 structure. They were found during the search for selenocysteine tRNAs in terabytes of genome, metagenome and metatranscriptome sequences. Certain bacteria and their phages employ the 8/4 structure for serine and histidine tRNAs, while minor cysteine and selenocysteine tRNA species may have a modified 8/4 structure with one bulge nucleotide. In Acidobacteria, tRNAs with 8/4 and 9/3 structures may function as missense and nonsense suppressor tRNAs and/or regulatory noncoding RNAs. In δ-proteobacteria, an additional cysteine tRNA with an 8/4 structure mimics selenocysteine tRNA and may function as opal suppressor. We examined the potential translation function of suppressor tRNA species in Escherichia coli; tRNAs with 8/4 or 9/3 structures efficiently inserted serine, alanine and cysteine in response to stop and sense codons, depending on the identity element and anticodon sequence of the tRNA. These findings expand our view of how tRNA, and possibly the genetic code, is diversified in nature.

Published
2017

4. Leichte Neucodierung von Selenocystein in der Natur

Author

Mukai, Takahito, Englert, Markus, Tripp, H James, Miller, Corwin, Ivanova, Natalia N, Rubin, Edward M, Kyrpides, Nikos C, and Söll, Dieter

Subjects
Chemical Sciences, Organic Chemistry, Chemical sciences
Published
2016

5. Facile Recoding of Selenocysteine in Nature

Author

Mukai, Takahito, Englert, Markus, Tripp, H James, Miller, Corwin, Ivanova, Natalia N, Rubin, Edward M, Kyrpides, Nikos C, and Söll, Dieter

Subjects
Genetics, Bacteria, Base Sequence, Codon, Terminator, Evolution, Molecular, Genetic Code, Genome, Bacterial, Metagenome, Selenocysteine, genetic code, metagenome, selenocysteine, sense codon recoding, synthetic biology, Chemical Sciences, Organic Chemistry
Abstract

Selenocysteine (Sec or U) is encoded by UGA, a stop codon reassigned by a Sec-specific elongation factor and a distinctive RNA structure. To discover possible code variations in extant organisms we analyzed 6.4 trillion base pairs of metagenomic sequences and 24 903 microbial genomes for tRNA(Sec) species. As expected, UGA is the predominant Sec codon in use. We also found tRNA(Sec) species that recognize the stop codons UAG and UAA, and ten sense codons. Selenoprotein synthesis programmed by UAG in Geodermatophilus and Blastococcus, and by the Cys codon UGU in Aeromonas salmonicida was confirmed by metabolic labeling with (75) Se or mass spectrometry. Other tRNA(Sec) species with different anticodons enabled E. coli to synthesize active formate dehydrogenase H, a selenoenzyme. This illustrates the ease by which the genetic code may evolve new coding schemes, possibly aiding organisms to adapt to changing environments, and show the genetic code is much more flexible than previously thought.

Published
2016

9. The tRNA discriminator base defines the mutual orthogonality of two distinct pyrrolysyl-tRNA synthetase/tRNAPyl pairs in the same organism

Author

Zhang, Haolin, primary, Gong, Xuemei, additional, Zhao, Qianqian, additional, Mukai, Takahito, additional, Vargas-Rodriguez, Oscar, additional, Zhang, Huiming, additional, Zhang, Yuxing, additional, Wassel, Paul, additional, Amikura, Kazuaki, additional, Maupin-Furlow, Julie, additional, Ren, Yan, additional, Xu, Xun, additional, Wolf, Yuri I, additional, Makarova, Kira S, additional, Koonin, Eugene V, additional, Shen, Yue, additional, Söll, Dieter, additional, and Fu, Xian, additional

Published
2022
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12. Recoding UAG to selenocysteine in Saccharomyces cerevisiae

Author

Hoffman, Kyle S., Chung, Christina Z., Mukai, Takahito, Krahn, Natalie, Jiang, Han-Kai, Balasuriya, Nileeka, O'Donoghue, Patrick, and So¨ll, Dieter

Abstract

Unique chemical and physical properties are introduced by inserting selenocysteine (Sec) at specific sites within proteins. Recombinant and facile production of eukaryotic selenoproteins would benefit from a yeast expression system; however, the selenoprotein biosynthetic pathway was lost in the evolution of the kingdom Fungi as it diverged from its eukaryotic relatives. Based on our previous development of efficient selenoprotein production in bacteria, we designed a novel Sec biosynthesis pathway in Saccharomyces cerevisiaeusing Aeromonas salmonicidatranslation components. S. cerevisiaetRNASerwas mutated to resemble A. salmonicidatRNASecto allow recognition by S. cerevisiaeseryl-tRNA synthetase as well as A. salmonicidaselenocysteine synthase (SelA) and selenophosphate synthetase (SelD). Expression of these Sec pathway components was then combined with metabolic engineering of yeast to enable the production of active methionine sulfate reductase enzyme containing genetically encoded Sec. Our report is the first demonstration that yeast is capable of selenoprotein production by site-specific incorporation of Sec.

Published
2023
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30. Transfer RNAs with novel cloverleaf structures

Author

Mukai, Takahito, primary, Vargas-Rodriguez, Oscar, additional, Englert, Markus, additional, Tripp, H. James, additional, Ivanova, Natalia N., additional, Rubin, Edward M., additional, Kyrpides, Nikos C., additional, and Söll, Dieter, additional

Published
2016
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31. Recoding of the selenocysteine UGA codon by cysteine in the presence of a non-canonical tRNACys and elongation factor SelB.

Author

Vargas-Rodriguez, Oscar, Englert, Markus, Merkuryev, Anna, Mukai, Takahito, and Söll, Dieter

Abstract

In many organisms, the UGA stop codon is recoded to insert selenocysteine (Sec) into proteins. Sec incorporation in bacteria is directed by an mRNA element, known as the Sec-insertion sequence (SECIS), located downstream of the Sec codon. Unlike other aminoacyl-tRNAs, Sec-tRNASec is delivered to the ribosome by a dedicated elongation factor, SelB. We recently identified a series of tRNASec-like tRNA genes distributed across Bacteria that also encode a canonical tRNASec. These tRNAs contain sequence elements generally recognized by cysteinyl-tRNA synthetase (CysRS). While some of these tRNAs contain a UCA Sec anticodon, most have a GCA Cys anticodon. tRNASec with GCA anticodons are known to recode UGA codons. Here we investigate the clostridial Desulfotomaculum nigrificans tRNASec-like tRNACys, and show that this tRNA is acylated by CysRS, recognized by SelB, and capable of UGA recoding with Cys in Escherichia coli. We named this non-canonical group of tRNACys as ‘tRNAReC’ (Recoding with Cys). We performed a comprehensive survey of tRNAReC genes to establish their phylogenetic distribution, and found that, in a particular lineage of clostridial Pelotomaculum, the Cys identity elements of tRNAReC had mutated. This novel tRNA, which contains a UCA anticodon, is capable of Sec incorporation in E. coli, albeit with lower efficiency relative to Pelotomaculum tRNASec. We renamed this unusual tRNASec derived from tRNAReC as ‘tRNAReU’ (Recoding with Sec). Together, our results suggest that tRNAReC and tRNAReU may serve as safeguards in the production of selenoproteins and - to our knowledge - they provide the first example of programmed codon-anticodon mispairing in bacteria. [ABSTRACT FROM AUTHOR]

Published
2018
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34. Protein stabilization utilizing a redefined codon

Author

Ohtake, Kazumasa, primary, Yamaguchi, Atsushi, additional, Mukai, Takahito, additional, Kashimura, Hiroki, additional, Hirano, Nobutaka, additional, Haruki, Mitsuru, additional, Kohashi, Sosuke, additional, Yamagishi, Kenji, additional, Murayama, Kazutaka, additional, Tomabechi, Yuri, additional, Itagaki, Takashi, additional, Akasaka, Ryogo, additional, Kawazoe, Masahito, additional, Takemoto, Chie, additional, Shirouzu, Mikako, additional, Yokoyama, Shigeyuki, additional, and Sakamoto, Kensaku, additional

Published
2015
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35. Genetic encoding of non-natural amino acids in Drosophila melanogaster Schneider 2 cells

Author

Mukai, Takahito, Wakiyama, Motoaki, Sakamoto, Kensaku, and Yokoyama, Shigeyuki

Subjects
Monoiodotyrosine, Azides, Phenylalanine, Interleukin-8, Article, Cell Line, Drosophila melanogaster, Genetic Code, Tyrosine-tRNA Ligase, Protein Biosynthesis, Escherichia coli, Animals, Humans, Amino Acids, Codon, Promoter Regions, Genetic
Abstract

Insect cells are useful for the high-yield production of recombinant proteins including chemokines and membrane proteins. In this study, we developed an insect cell-based system for incorporating non-natural amino acids into proteins at specific sites. Three types of promoter systems were constructed, and their efficiencies were compared for the expression of the prokaryotic amber suppressor tRNA(Tyr) in Drosophila melanogaster Schneider 2 cells. When paired with a variant of Escherichia coli tyrosyl-tRNA synthetase specific for 3-iodo-L-tyrosine, the suppressor tRNA transcribed from the U6 promoter most efficiently incorporated the amino acid into proteins in the cells. The transient and stable introductions of these prokaryotic molecules into the insect cells were then compared in terms of the yield of proteins containing non-natural amino acids, and the "transient" method generated a sevenfold higher yield. By this method, 4-azido-L-phenylalanine was incorporated into human interleukin-8 at a specific site. The yield of the azido-containing IL-8 was 1 microg/1 mL cell culture, and the recombinant protein was successfully labeled with a fluorescent probe by the Staudinger-Bertozzi reaction.

Published
2010

39. Genetic-code evolution for protein synthesis with non-natural amino acids

Author

Mukai, Takahito, primary, Yanagisawa, Tatsuo, additional, Ohtake, Kazumasa, additional, Wakamori, Masatoshi, additional, Adachi, Jiro, additional, Hino, Nobumasa, additional, Sato, Aya, additional, Kobayashi, Takatsugu, additional, Hayashi, Akiko, additional, Shirouzu, Mikako, additional, Umehara, Takashi, additional, Yokoyama, Shigeyuki, additional, and Sakamoto, Kensaku, additional

Published
2011
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44. Bioinformatic Prediction of an tRNA Sec Gene Nested inside an Elongation Factor SelB Gene in Alphaproteobacteria.

Author

Mukai, Takahito and Stathopoulos, Constantinos

Subjects
*TRANSFER RNA, *SELENOPROTEINS, *BACTERIAL proteins, *GENES, *SELENOCYSTEINE, *OXIDATIVE stress, *NON-coding RNA
Abstract

In bacteria, selenocysteine (Sec) is incorporated into proteins via the recoding of a particular codon, the UGA stop codon in most cases. Sec-tRNASec is delivered to the ribosome by the Sec-dedicated elongation factor SelB that also recognizes a Sec-insertion sequence element following the codon on the mRNA. Since the excess of SelB may lead to sequestration of Sec-tRNASec under selenium deficiency or oxidative stress, the expression levels of SelB and tRNASec should be regulated. In this bioinformatic study, I analyzed the Rhizobiales SelB species because they were annotated to have a non-canonical C-terminal extension. I found that the open reading frame (ORF) of diverse Alphaproteobacteria selB genes includes an entire tRNASec sequence (selC) and overlaps with the start codon of the downstream ORF. A remnant tRNASec sequence was found in the Sinorhizobium melilotiselB genes whose products have a shorter C-terminal extension. Similar overlapping traits were found in Gammaproteobacteria and Nitrospirae. I hypothesized that once the tRNASec moiety is folded and processed, the expression of the full-length SelB may be repressed. This is the first report on a nested tRNA gene inside a protein ORF in bacteria. [ABSTRACT FROM AUTHOR]

Published
2021
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46. Recoding of the selenocysteine UGA codon by cysteine in the presence of a non-canonical tRNA Cys and elongation factor SelB.

Author

Vargas-Rodriguez O, Englert M, Merkuryev A, Mukai T, and Söll D

Subjects
Amino Acyl-tRNA Synthetases metabolism, Anticodon genetics, Anticodon metabolism, Bacterial Proteins metabolism, Codon, Terminator chemistry, Codon, Terminator metabolism, Desulfotomaculum genetics, Desulfotomaculum metabolism, Escherichia coli metabolism, Genetic Code, Models, Molecular, Mutation, Nucleic Acid Conformation, Peptide Elongation Factor Tu genetics, Peptide Elongation Factor Tu metabolism, Peptococcaceae genetics, Peptococcaceae metabolism, Protein Biosynthesis, RNA, Transfer, Cys metabolism, Ribosomes genetics, Ribosomes metabolism, Selenoproteins biosynthesis, Amino Acyl-tRNA Synthetases genetics, Bacterial Proteins genetics, Cysteine metabolism, Escherichia coli genetics, RNA, Transfer, Cys genetics, Selenocysteine metabolism, Selenoproteins genetics
Abstract

In many organisms, the UGA stop codon is recoded to insert selenocysteine (Sec) into proteins. Sec incorporation in bacteria is directed by an mRNA element, known as the Sec-insertion sequence (SECIS), located downstream of the Sec codon. Unlike other aminoacyl-tRNAs, Sec-tRNA Sec is delivered to the ribosome by a dedicated elongation factor, SelB. We recently identified a series of tRNA Sec -like tRNA genes distributed across Bacteria that also encode a canonical tRNA Sec . These tRNAs contain sequence elements generally recognized by cysteinyl-tRNA synthetase (CysRS). While some of these tRNAs contain a UCA Sec anticodon, most have a GCA Cys anticodon. tRNA Sec with GCA anticodons are known to recode UGA codons. Here we investigate the clostridial Desulfotomaculum nigrificans tRNA Sec -like tRNA Cys , and show that this tRNA is acylated by CysRS, recognized by SelB, and capable of UGA recoding with Cys in Escherichia coli. We named this non-canonical group of tRNA Cys as 'tRNA ReC ' (Recoding with Cys). We performed a comprehensive survey of tRNA ReC genes to establish their phylogenetic distribution, and found that, in a particular lineage of clostridial Pelotomaculum, the Cys identity elements of tRNA ReC had mutated. This novel tRNA, which contains a UCA anticodon, is capable of Sec incorporation in E. coli, albeit with lower efficiency relative to Pelotomaculum tRNA Sec . We renamed this unusual tRNA Sec derived from tRNA ReC as 'tRNA ReU ' (Recoding with Sec). Together, our results suggest that tRNA ReC and tRNA ReU may serve as safeguards in the production of selenoproteins and - to our knowledge - they provide the first example of programmed codon-anticodon mispairing in bacteria.

Published
2018
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47. Bioinformatic Analysis Reveals Archaeal tRNA Tyr and tRNA Trp Identities in Bacteria.

Author

Mukai T, Reynolds NM, Crnković A, and Söll D

Abstract

The tRNA identity elements for some amino acids are distinct between the bacterial and archaeal domains. Searching in recent genomic and metagenomic sequence data, we found some candidate phyla radiation (CPR) bacteria with archaeal tRNA identity for Tyr-tRNA and Trp-tRNA synthesis. These bacteria possess genes for tyrosyl-tRNA synthetase (TyrRS) and tryptophanyl-tRNA synthetase (TrpRS) predicted to be derived from DPANN superphylum archaea, while the cognate tRNA Tyr and tRNA Trp genes reveal bacterial or archaeal origins. We identified a trace of domain fusion and swapping in the archaeal-type TyrRS gene of a bacterial lineage, suggesting that CPR bacteria may have used this mechanism to create diverse proteins. Archaeal-type TrpRS of bacteria and a few TrpRS species of DPANN archaea represent a new phylogenetic clade (named TrpRS-A). The TrpRS-A open reading frames (ORFs) are always associated with another ORF (named ORF1) encoding an unknown protein without global sequence identity to any known protein. However, our protein structure prediction identified a putative HIGH-motif and KMSKS-motif as well as many α-helices that are characteristic of class I aminoacyl-tRNA synthetase (aaRS) homologs. These results provide another example of the diversity of molecular components that implement the genetic code and provide a clue to the early evolution of life and the genetic code.

Published
2017
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49. Reassignment of a rare sense codon to a non-canonical amino acid in Escherichia coli.

Author

Mukai T, Yamaguchi A, Ohtake K, Takahashi M, Hayashi A, Iraha F, Kira S, Yanagisawa T, Yokoyama S, Hoshi H, Kobayashi T, and Sakamoto K

Subjects
Amino Acids analysis, Amino Acyl-tRNA Synthetases genetics, Amino Acyl-tRNA Synthetases metabolism, Arginine chemistry, Escherichia coli metabolism, Escherichia coli Proteins biosynthesis, Escherichia coli Proteins chemistry, Genes, Bacterial, Genes, Essential, Homoarginine chemistry, Lysine analogs & derivatives, Lysine chemistry, Lysine metabolism, Protein Engineering, Proteome metabolism, RNA, Transfer metabolism, Suppression, Genetic, Codon, Escherichia coli genetics, Homoarginine metabolism, Protein Biosynthesis
Abstract

The immutability of the genetic code has been challenged with the successful reassignment of the UAG stop codon to non-natural amino acids in Escherichia coli. In the present study, we demonstrated the in vivo reassignment of the AGG sense codon from arginine to L-homoarginine. As the first step, we engineered a novel variant of the archaeal pyrrolysyl-tRNA synthetase (PylRS) able to recognize L-homoarginine and L-N(6)-(1-iminoethyl)lysine (L-NIL). When this PylRS variant or HarRS was expressed in E. coli, together with the AGG-reading tRNA(Pyl) CCU molecule, these arginine analogs were efficiently incorporated into proteins in response to AGG. Next, some or all of the AGG codons in the essential genes were eliminated by their synonymous replacements with other arginine codons, whereas the majority of the AGG codons remained in the genome. The bacterial host's ability to translate AGG into arginine was then restricted in a temperature-dependent manner. The temperature sensitivity caused by this restriction was rescued by the translation of AGG to L-homoarginine or L-NIL. The assignment of AGG to L-homoarginine in the cells was confirmed by mass spectrometric analyses. The results showed the feasibility of breaking the degeneracy of sense codons to enhance the amino-acid diversity in the genetic code., (© The Author(s) 2015. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2015
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50. Multiple site-specific installations of Nε-monomethyl-L-lysine into histone proteins by cell-based and cell-free protein synthesis.

Author

Yanagisawa T, Takahashi M, Mukai T, Sato S, Wakamori M, Shirouzu M, Sakamoto K, Umehara T, and Yokoyama S

Subjects
Amino Acids genetics, Amino Acids metabolism, Cell-Free System, Genetic Code genetics, Humans, Lysine chemistry, Models, Molecular, Molecular Structure, Escherichia coli cytology, Escherichia coli metabolism, Histones chemistry, Histones metabolism, Lysine analogs & derivatives, Lysine metabolism, Protein Biosynthesis
Abstract

Lysine methylation is one of the important post-translational modifications of histones, and produces an N(ε) -mono-, di-, or trimethyllysine residues. Multiple and site-specific lysine methylations of histones are essential to define epigenetic statuses and control heterochromatin formation, DNA repair, and transcription regulation. A method was previously developed to build an analogue of N(ε)-monomethyllysine, with cysteine substituting for lysine. Here, we have developed a new method of preparing histones bearing multiple N(ε)-monomethyllysine residues at specified positions. Release factor 1-knockout (RFzero) Escherichia coli cells or a cell-free system based on the RFzero cell lysate was used for protein synthesis, as in RFzero cells UAG is redefined as a sense codon for non-canonical amino acids. During protein synthesis, a tert-butyloxycarbonyl-protected N(ε)-monomethyllysine analogue is ligated to Methanosarcina mazei pyrrolysine tRNA (tRNA(Pyl)) by M. mazei pyrrolysyl-tRNA synthetase mutants, and is translationally incorporated into one or more positions specified by the UAG codon. Protecting groups on the protein are then removed with trifluoroacetic acid to generate N(ε)-monomethyllysine residues. We installed N(ε)-monomethyllysine residues at positions 4, 9, 27, 36, and/or 79 of human histone H3. Each of the N(ε)-monomethyllysine residues within the produced histone H3 was recognized by its specific antibody. Furthermore, the antibody recognized the authentic N(ε)-monomethyllysine residue at position 27 better than the N(ε)-monomethyllysine analogue built with cysteine. Mass spectrometry analyses also confirmed the lysine modifications on the produced histone H3. Thus, our method enables the installation of authentic N(ε)-monomethyllysines at multiple positions within a protein for large-scale production., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2014
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