Binding Cofactors with Triplex-Based DNA Motifs

Cofactors are pivotal compounds for the cell and many biotechnological processes. It is therefore interesting to ask how well cofactors can be bound by oligonucleotides designed not to convert but to store and release these biomolecules. Here we show that triplex‐based DNA binding motifs can be used...

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Veröffentlicht in:Chemistry : a European journal 2013-11, Vol.19 (47), p.15879-15887
Hauptverfasser: Kröner, Christoph, Göckel, Anja, Liu, Wenjing, Richert, Clemens
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Sprache:eng
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Zusammenfassung:Cofactors are pivotal compounds for the cell and many biotechnological processes. It is therefore interesting to ask how well cofactors can be bound by oligonucleotides designed not to convert but to store and release these biomolecules. Here we show that triplex‐based DNA binding motifs can be used to bind nucleotides and cofactors, including NADH, FAD, SAM, acetyl CoA, and tetrahydrofolate (THF). Dissociation constants between 0.1 μM for SAM and 35 μM for THF were measured. A two‐nucleotide gap still binds NADH. The selectivity for one ligand over the others can be changed by changing the sequence of the binding pocket. For example, a mismatch placed in one of the two triplets adjacent to the base‐pairing site changes the selectivity, favoring the binding of FAD over that of ATP. Further, changing one of the two thymines of an A‐binding motif to cytosine gives significant affinity for G, whereas changing the other does not. Immobilization of DNA motifs gives beads that store NADH. Exploratory experiments show that the beads release the cofactor upon warming to body temperature. Cofactor storage and release: DNA triplex motifs with a gap in the strand, such as the one depicted above (SAM=S‐adenosyl‐L‐methionine, THF=tetrahydrofolate), were found to bind key biochemical cofactors with dissociation constants down to the submicromolar range. When NADH is released, bioluminescence can be induced upon warming to body temperature.
ISSN:0947-6539
1521-3765
DOI:10.1002/chem.201303098