The T−A and C−G base pairing and stacking allow the formation of the stable DNA duplex structure for genetic information storage, transcription, and replication. To replace the oxygen of the nucleotide nucleobases with selenium for the studies of the base-pair recognition, the duplex stability, and the nuclei acid crystal structures, we have synthesized for the first time the 4-Se thymidine phosphoramidite and incorporated it into oligonucleotides via solid-phase synthesis with high coupling yield (99%). The Se modification on the nucleobase is relatively stable under the elevated temperature. Using the dUSe (2‘-Se-dU) to facilitate the crystallization, we have successfully crystallized the DNA containing the 4-Se−T substitution and determined its structure at 1.50 Å resolution. The UV-melting and X-ray crystal structure studies have indicated that the Se substitution on the nucleobase does not cause a significant structure perturbation, the large Se atom on the thymine can be successfully accommodated by the DNA duplex, and the Se-mediated hydrogen bond (longer than the usual hydrogen bond) is formed within the modified T−A base pair. In addition, the Se derivatization on the nucleobases further facilitates X-ray crystal structure determination of nucleic acids and their protein complexes via Se MAD phasing.
The boronic acid moiety is a versatile functional group useful in carbohydrate recognition, glycoprotein pull-down, inhibition of hydrolytic enzymes and boron neutron capture therapy. The incorporation of the boronic-acid group into DNA could lead to molecules of various biological functions. We have successfully synthesized a boronic acid-labeled thymidine triphosphate (B-TTP) linked through a 14-atom tether and effectively incorporated it into DNA by enzymatic polymerization. The synthesis was achieved using the Huisgen cycloaddition as the key reaction. We have demonstrated that DNA polymerase can effectively recognize the boronic acid-labeled DNA as the template for DNA polymerization, that allows PCR amplification of boronic acid-labeled DNA. DNA polymerase recognitions of the B-TTP as a substrate and the boronic acid-labeled DNA as a template are critical issues for the development of DNA-based lectin mimics via in vitro selection.
By differentiating the functional groups on nucleosides, we have designed and developed a one-pot synthesis of deoxyribonucleoside 5′-triphosphates without any protections on the nucleosides. A facile synthesis is achieved by generating an in situ phosphitylating reagent that reacts selectively with the 5′-hydroxyl groups of the unprotected nucleosides. The synthesized triphosphates are of high quality and can be effectively incorporated into DNAs by DNA polymerase. This novel approach is straightforward and cost-effective for triphosphate synthesis.
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