Methods for the site-specific incorporation of extra components into nucleic acids can be powerful tools for creating DNA and RNA molecules with increased functionality. We present an unnatural base pair system in which DNA containing an unnatural base pair can be amplified and function as a template for the site-specific incorporation of base analog substrates into RNA via transcription. The unnatural base pair is formed by specific hydrophobic shape complementation between the bases, but lacks hydrogen bonding interactions. In replication, this unnatural base pair exhibits high selectivity in combination with the usual triphosphates and modified triphosphates, gamma-amidotriphosphates, as substrates of 3' to 5' exonuclease-proficient DNA polymerases, allowing PCR amplification. In transcription, the unnatural base pair complementarity mediates the incorporation of these base substrates and their analogs, such as a biotinylated substrate, into RNA by T7 RNA polymerase (RNAP). With this system, functional components can be site-specifically incorporated into a large RNA molecule.
An unnatural base pair system for efficient PCR amplification and functionalization of DNA molecules
Toward the expansion of the genetic alphabet, we present an unnatural base pair system for efficient PCR amplification, enabling the site-specific incorporation of extra functional components into DNA. This system can be applied to conventional PCR protocols employing DNA templates containing unnatural bases, natural and unnatural base triphosphates, and a 3′→5′ exonuclease-proficient DNA polymerase. For highly faithful and efficient PCR amplification involving the unnatural base pairing, we identified the natural-base sequences surrounding the unnatural bases in DNA templates by an in vitro selection technique, using a DNA library containing the unnatural base. The system facilitates the site-specific incorporation of a variety of modified unnatural bases, linked with functional groups of interest, into amplified DNA. DNA fragments (0.15 amol) containing the unnatural base pair can be amplified 107-fold by 30 cycles of PCR, with <1% total mutation rate of the unnatural base pair site. Using the system, we demonstrated efficient PCR amplification and functionalization of DNA fragments for the extremely sensitive detection of zeptomol-scale target DNA molecules from mixtures with excess amounts (pmol scale) of foreign DNA species. This unnatural base pair system will be applicable to a wide range of DNA/RNA-based technologies.
An unnatural base pair of 2-amino-6-(2-thienyl)purine (denoted by s) and pyridin-2-one (denoted by y) was developed to expand the genetic code. The ribonucleoside triphosphate of y was site-specifically incorporated into RNA, opposite s in a template, by T7 RNA polymerase. This transcription was coupled with translation in an Escherichia coli cell-free system. The yAG codon in the transcribed ras mRNA was recognized by the CUs anticodon of a yeast tyrosine transfer RNA (tRNA) variant, which had been enzymatically aminoacylated with an unnatural amino acid, 3-chlorotyrosine. Site-specific incorporation of 3-chlorotyrosine into the Ras protein was demonstrated by liquid chromatography-mass spectrometry (LC-MS) analysis of the products. This coupled transcription-translation system will permit the efficient synthesis of proteins with a tyrosine analog at the desired position.
Toward the expansion of the genetic alphabet of DNA, we present highly efficient unnatural base pair systems as an artificial third base pair for PCR. Hydrophobic unnatural base pair systems between 7-(2-thienyl)imidazo[4,5-b]pyridine (Ds) and 2-nitro-4-propynylpyrrole (Px) were fine-tuned for efficient PCR, by assessing the amplification efficiency and fidelity using different polymerases and template sequence contexts and modified Px bases. Then, we found that some modifications of the Px base reduced the misincorporation rate of the unnatural base substrates opposite the natural bases in templates without reducing the Ds–Px pairing selectivity. Under optimized conditions using Deep Vent DNA polymerase, the misincorporation rate was extremely low (0.005%/bp/replication), which is close to that of the natural base mispairings by the polymerase. DNA fragments with different sequence contexts were amplified ∼1010-fold by 40 cycles of PCR, and the selectivity of the Ds–Px pairing was >99.9%/replication, except for 99.77%/replication for unfavorable purine-Ds-purine motifs. Furthermore, >97% of the Ds–Px pair in DNA survived in the 1028-fold amplified products after 100-cycle PCR (10 cycles repeated 10 times). This highly specific Ds–Px pair system provides a framework for new biotechnology.
Expansion of the genetic alphabet by an unnatural base pair system provides a powerful tool for modern biotechnology. As an alternative to previous unnatural base pairs, we have developed a new pair between 7-(2-thienyl)imidazo[4,5-b]pyridine (Ds) and 2-nitropyrrole (Pn), which functions in DNA amplification. Pn more selectively pairs with Ds in replication than another previously reported pairing partner, pyrrole-2-carbaldehyde (Pa). The nitro group of Pn efficiently prevented the mispairing with A. High efficiency and selectivity of the Ds-Pn pair in PCR amplification were achieved by using a substrate mixture of the gamma-amidotriphosphate of Ds and the usual triphosphates of Pn and the natural bases, with Vent DNA polymerase as a 3' to 5' exonuclease-proficient polymerase. After 20 cycles of PCR, the total mutation rate of the Ds-Pn site in an amplified DNA fragment was approximately 1%. PCR amplification of DNA fragments containing the unnatural Ds-Pn pair would be useful for expanded genetic systems in DNA-based biotechnology.
Toward the site-specific incorporation of amino acid analogues into proteins, a two-unnatural-base-pair system was developed for coupled transcription-translation systems with the expanded genetic code. A previously designed unnatural base pair between 2-amino-6-(2-thienyl)purine (denoted by s) and pyridin-2-one (denoted by y) was used for the site-specific incorporation of yTP into RNA opposite s in templates by T7 RNA polymerase. For the site-specific incorporation of sTP into RNA, a newly developed unnatural base, imidazolin-2-one (denoted by z), is superior to y as a template base for pairing with s in T7 transcription. The combination of the s-y and s-z pairs provides a powerful tool to prepare both y-containing mRNA and s-containing tRNA for efficient coupled transcription-translation systems, in which the genetic code is expanded by the codon-anticodon interactions mediated by the s-y pair. In addition, the nucleoside of s is strongly fluorescent, and thus the s-z pair enables the site-specific fluorescent labeling of RNA molecules. These unnatural-base-pair studies provide valuable information for understanding the mechanisms of replication and transcription.
An unnatural hydrophobic base, pyrrole-2-carbaldehyde (denoted as Pa), was developed as a specific pairing partner of 9-methylimidazo[(4,5)-b]pyridine (Q). The Q base is known to pair with 2,4-difluorotoluene (F) as an isostere of the A-T pair, and F also pairs with A efficiently in replication. In contrast, the Q-Pa pair showed specific selectivity in replication, and the five-membered-ring base Pa paired efficiently with Q but paired poorly with A. In addition, the interaction of Pa with DNA polymerases was superior, in comparison to that of F. The aldehyde group of Pa was recognized well by the Klenow fragment of Escherichia coli DNA polymerase I and the reverse transcriptase of Avian myeloblastosis virus. The structural features of the Q-Pa pair in a DNA duplex were analyzed by NMR, showing the shape complementarity of the Pa fitting with Q. The structurally unique base Pa provides valuable information for the development of unnatural base pairs toward the expansion of the genetic alphabet.
An unnatural base pair of 2-amino-6-(N,N-dimethylamino)purine (designated as x) and pyridin-2-one (designated as y) has been developed for specific transcription. The ribonucleoside triphosphates of y and a modified y, 5-methylpyridin-2-one, are selectively incorporated into RNA opposite x in the templates by T7 RNA polymerase. In addition, the sequences of the DNA templates containing x can be confirmed by a dideoxynucleotide chainterminator method supplemented with the deoxynucleoside triphosphate of y. The bulky dimethylamino group of x in the templates effectively eliminates noncognate pairing with the natural bases. These results enable RNA biosynthesis for the specific incorporation of unnatural nucleotides at the desired positions.T ranscription involving specific, unnatural base pairs, in addition to the A⅐U and G⅐C pairs, would be a method for the site-directed incorporation of unnatural bases into RNAs, to achieve new functionality as ligands or catalysts (1-5) or novel codon-anticodon interactions between transfer and messenger RNAs in translation (6-9). Compared with the chemical synthesis of RNA, transcription is more efficient to produce and amplify RNAs with long chain lengths from DNA templates, which can be constructed by chemical synthesis in combination with enzymatic ligation. Thus, many efforts have been made to develop unnatural bases that are recognized by RNA polymerases as substrates and are specifically incorporated into RNA opposite the pairing bases in the DNA templates.Previous efforts to create unnatural base pairs for replication and transcription have relied on nonstandard hydrogen-bonding schemes that differ from those of the Watson-Crick base pairs (2, 10 -16). Unnatural pairs of nucleotides, such as isoguanosine⅐isocytidine and xanthosine⅐2,4-diaminopyrimidine nucleoside, are complementarily incorporated into DNA and RNA by polymerases with moderate selectivity (11-15). In addition, in vitro translation for the site-specific incorporation of an unnatural amino acid into a peptide has been demonstrated by using an extra codon-anticodon interaction between isoguanine and isocytosine (6, 7). These studies indicate that the unnatural, nonstandard hydrogen-bonded base pairs can also function in replication and transcription. However, some misincorporations resulting in noncognate pairings with natural bases cannot be ignored for the practical usage of these unnatural base pairs. For instance, a 14% misincorporation of adenosine into RNA opposite 2,4-diaminopyrimidine is observed at a xanthosine triphosphate-to-ATP ratio of 1:1 in transcription by T7 RNA polymerase (2). Isoguanine tautomerization also causes the misincorporation of T or U opposite this base (11,12). In addition, the isocytidine and 5-methylisocytidine nucleoside derivatives are chemically unstable, and gradually decompose in solution (11,16). Furthermore, nucleoside triphosphates of 2-aminopyrimidines, such as isocytosine and 2,4-diaminopyrimidine, are not recognized as substrates by some polymerases (11,14,15) becau...
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