Quadruplex‐Templated and Catalyzed Ligation of Nucleic Acids

Template‐guided chemical reactions between nucleic acid strands are an important process in biomedical research. However, almost all of these reactions employ an oligonucleotide‐templated approach that is based on the double‐helix alignment. The moderate stability of the double helix makes this appr...

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Bibliographic Details
Published in:Chembiochem : a European journal of chemical biology 2021-04, Vol.22 (7), p.1261-1267
Main Author: Kankia, Besik
Format: Article
Language:English
Subjects:
Acids
Alignment
Carbodiimide
Catalysts
Chemical reactions
Complementarity
Deoxyribonucleic acid
DNA
ligation
Magnesium
Nucleic acids
Oligonucleotides
quadruplexes
RNA
Stability
Strands
Substrates
Tetrads
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Summary:Template‐guided chemical reactions between nucleic acid strands are an important process in biomedical research. However, almost all of these reactions employ an oligonucleotide‐templated approach that is based on the double‐helix alignment. The moderate stability of the double helix makes this approach unsuitable for many chemical reactions, so alternative nucleic acid alignment mechanisms, demonstrating higher thermal and chemical stability, are desirable. Earlier, we described a noncovalent coupling mechanism between DNA strands through a quadruplex‐and‐Mg2+ connection (QMC). QMC is based on G‐quadruplexes and allows unusually stable and specific interactions. Herein, a novel catalytic nucleic acid reaction, based on QMC, is described. This approach uses G‐tetrads as a structural and recognition element without employing Watson‐Crick complementarity rules at any stage of substrate/catalyst formation or interaction between them. Quadruplex‐templated ligation can be achieved through the self‐ligation of two nucleic acid strands, or through a quadruplex catalyst, which forms a G‐triplex and specifically connects the strands. The process is extraordinarily robust and efficient. For instance, the ligation of carbodiimide‐activated substrates can proceed in boiling solutions, and complete ligation is demonstrated within a minute. The quadruplex‐templated and catalyzed reactions will create new opportunities for chemical reactions requiring harsh experimental conditions. DNA catalytic system templated and catalyzed by quadruplexes. This system can create new opportunities for chemical reactions requiring harsh experimental conditions unsuitable for DNA duplex‐templated systems. The quadruplex‐templated system might represent initial DNA catalytic reaction involved in primordial evolution.
ISSN:1439-4227
1439-7633
DOI:10.1002/cbic.202000754