Red and Near-Infrared Light-Directed Cytosolic Delivery of Two Different RNAs Using Photosensitive RNA Carriers.

Many cellular events are thought to be controlled by the temporal upregulation of multiple RNAs; the timing of the upregulation of these RNAs is not always the same. In this study, we first show that our light-directed intracellular RNA delivery method induced high concentrations of RNA in a short period. This effect was beneficial for the temporal control of cellular events by functional RNAs. Next, we stimulated the short-term upregulation of two different RNAs at different time points. Cytosolic delivery of a first RNA was induced by red light; thereafter, cytosolic delivery of a second RNA was induced by near-infrared light. The time difference between the introduction of the first and second RNA can be short (0.5-4 h) or long (>8 h). This strategy shows the potential for future applications of the deliberate control of time-dependent RNA concentration to guide various cellular functions by multiple RNAs.

Biosynthesis of proteins containing modified lysines and fluorescent labels using non-natural amino acid mutagenesis.

The preparation of posttranslationally modified proteins is required to investigate the function and structure of modified proteins. However, homogeneously modified proteins are not easily isolated from natural sources or prepared using modification enzymes. Non-natural amino acid mutagenesis has enabled us to incorporate modified amino acids into specific positions of proteins in both cell-free and in-cell translation systems using tRNAs that are aminoacylated with modified amino acids. Here, we developed a method of double incorporation of modified amino acids and fluorescent non-natural amino acids in a quantitative, position-specific manner to obtain modified and fluorescently labeled proteins. To introduce methyllysine, dimethyllysine, trimethyllysine, and acetyllysine, frameshift and amber suppressor tRNAs aminoacylated with modified lysines were synthesized by chemical aminoacylation and supplied to an Escherichia coli cell-free translation system. The immunodetection of the translation products indicated that the modified lysines were incorporated into streptavidin and histone H3 in a quantitative, position-specific manner. Calmodulin derivatives containing a fluorescent non-natural amino acid at the N-terminal region and modified lysines at the Lys115 position were also synthesized, and their binding activity to a calmodulin-binding peptide was analyzed by fluorescence correlation spectroscopy. The results obtained here demonstrate that this method is useful in preparing and analyzing naturally occurring and non-natural modified proteins.

Incorporation of fluorescent non-natural amino acids into N-terminal tag of proteins in cell-free translation and its dependence on position and neighboring codons.

Fluorescence labeling is a useful technique for structural and functional analyses of proteins. In a previous study, we developed position-specific incorporation of visible wavelength fluorescent non-natural amino acids carrying relatively small BODIPY fluorophores into proteins, in response to a four-base codon CGGG. Here, we have expanded this position-specific fluorescence labeling method to include relatively large non-natural amino acids carrying photostable rhodamine dyes. TAMRA-linked aminophenylalanine was synthesized and attached to a tRNA having a four-base anticodon, and its incorporation into proteins was examined in an Escherichia coli cell-free translation system. TAMRA-labeled amino acids were successfully incorporated into proteins, although incorporation was allowed only at the N-terminal region. Insertion of two codons encoding a stop codon in the +1 frame before four-base codon suppressed the expression of non-labeled proteins that may have been produced by spontaneous +1 frameshift upstream of the four-base codon. Alternation of the incorporation position affected the expression level of the TAMRA-labeled protein. In addition, alternation of upstream and downstream codons affected the efficiency and accuracy of TAMRA-labeled amino acid incorporation. Based on these results, a novel tag peptide was developed; it contained the four-base codon at the 9th position with optimized upstream and downstream codons. This tag peptide was effective for producing proteins with various fluorescent labels at the N-terminal region.

Comprehensive screening of amber suppressor tRNAs suitable for incorporation of non-natural amino acids in a cell-free translation system.

Incorporation of non-natural amino acids into proteins in response to amber or four-base codons is a useful technology for protein research. In the case of the amber codon, however, release factor 1 can competitively decode the same codon, and consequently inhibit the incorporation of non-natural amino acids. To improve amber codon-mediated incorporation, we carried out a comprehensive screening of amber suppressor tRNAs derived from all tRNAs encoded in the genomes of Escherichia coli K12 and Mycoplasma capricolum. The amber suppressor tRNAs were synthesized from synthetic genes, aminoacylated with a fluorescent non-natural amino acid, and added to an E. coli cell-free translation system. Fluorescent SDS-PAGE analysis indicated that Trp tRNAs showed high suppressor activity in both organisms. Further mutagenesis and screening revealed that M. capricolum Trp(1) tRNA with G1C72A73 mutation is the most suitable for efficient and specific incorporation of non-natural amino acids into proteins in response to the amber codon.

Incorporation of fluorescently labeled nonnatural amino acids into proteins in an E. coli in vitro translation system.

Various nonnatural amino acids has been incorporated into proteins by using four-base codons in an E. coli in vitro translation system. Here, design and synthesis of novel fluorescently labeled nonnatural amino acids and their incorporation into proteins were investigated. Transfer RNAs that contained a CCCG anticodon and were aminoacylated with BODIPY FL-labeled amino acids were prepared by a chemical aminoacylation method, and added to an in vitro translation system in the presence of a streptavidin mRNA containing a CGGG codon. SDS-PAGE and Western blot analysis of the synthesized proteins indicate that BODIPY FL-labeled aminophenylalanine derivatives are efficiently incorporated into proteins through the four-base codon decoding.