RESUMEN

In 8-17 DNAzyme, the end loop A6G7C8 is a highly conserved motif. Here we reported an activation approach by specific chemical modifications on A6 and C8 for more efficient Ca2+-mediated reaction. The importance of the end loop was further highlighted and its critical conservation broken for more powerful catalysts.

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RESUMEN

10-23 DNAzyme is a catalytic DNA molecule from in vitro selection, the 15-mer catalytic core was investigated for more DNAzyme variants by block deletions. DNAzyme DZM01 was selected with metal ion dependence of Pb2+ â‰« Mn2+, with no activity in the presence of Mg2+ (20 mM), Ca2+ (20 mM), Zn2+ (20 mM, pH 6). The unique binding properties of Pb2+ with nucleic acids might be responsible for the formation of the catalytic core, which is different from that of other divalent metal ions. More DNAzyme variants are expected to be derived for specific metal ion dependence by various nucleobase sequences and modifications.

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RESUMEN

8-17 and 17E DNAzyme are being explored as biosensors for metal ions and RNA motifs of interest, more sensitive and efficient DNAzymes are required to meet the practical applications. Their similarity in the catalytic cores and differences in catalytic efficiency and metal ion dependence initiated great interest about the contribution of the catalytic residues. Functionalization of four adenine residues in the catalytic cores of 8-17 DNAzyme and 17E was conducted with amino, guanidinium, and imidazolyl groups. In the bulge loops of 8-17 and 17E, N6-(3-aminopropyl)-2'-deoxyadenosine (residue 1) at A15 led to new DNAzymes 8-17DZ-A15-1 and 17E-A15-1, with much more efficient cleavage ability in the Ca2+-mediated reaction and the greater preference for Ca2+ over Mg2+ than 8-17 DNAzyme and 17E, respectively, especially with a concentration-dependent increase of the selectivity, which is different from most DNAzymes with the similar dependence on both Mg2+ and Ca2+. With this kind of post-selection modification on 8-17 DNAzymes, for the first time, the catalytic efficiency and metal ion selectivity could be positively modulated. It is also helpful for the catalyic mechanistic studies of these DNAzymes, especially, the role of the unconserved A15 should be emphasized.

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RESUMEN

10-23 DNAzyme has been extensively explored as a therapeutic and biotechnological tool, as well as in DNA computing. Faster cleavage or transformation is always needed. The present research displays a rational modification approach for a more efficient DNAzyme. In the catalytic core, amino, guanidinium and imidazolyl groups were introduced for its chemical activation through the adenine base. Among the six adenine residues, A9 is the unique residue that realizes all the positive effects; the 6-amino and 8-position of adenine and the 7-position of 8-aza-7-deaza-adenine could be used for the introduction of the functional groups. A12 is a new choice for catalytic improvement with an 8-substituent. Therefore, more active DNAzymes could be expected by this nucleobase-modified activation approach.

RESUMEN

TBA is a 15-mer DNA aptamer for human α-thrombin, and its three T-rich loops are involved in the binding interactions with thrombin differently. In order to clarify their specific spatial locations in the binding interactions and search for more favourable positions, here a systematic investigation of all the loop residues was conducted with 3'-inverted thymidine (iT), by which both unnatural 3'-3'- and 5'-5'-linkages for each incorporation were introduced in the tertiary structure. The changes in Tm values and CD spectra revealed that motifs T3T12 and T4T13 are structurally distinct. Longer anti-clotting time was obtained for the T3 and T12 modifications, respectively, while T4 and T13 were completely intolerant with such changes, in terms of stability and binding to thrombin. In particular, the increased affinity bindings and longer anti-clotting time were obtained with the replacement on the central loop T7G8T9, which were closely related to the existence of a monovalent ion, K+ or Na+, consistently with the supposed binding site of these ions in TBA. It is worthwhile to note that both the subtle variations of the loop residues induced by iT and the monovalent ions determined the interacting residues of TBA and the binding strength rather than the thermal stability of the TBA structure.

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