Abstract
Herein, the excellent Na+ selectivity of a few RNA-cleaving DNAzymes was exploited, where Na+ can be around 3000-fold more effective than K+ for promoting catalysis. By using a double mutant based on the Ce13d DNAzyme, and by lowering the temperature, increased 2-aminopurine (2AP) fluorescence was observed with addition of both Na+ and K+. The fluorescence increase was similar for these two metals at below 10 mM, after which K+ took a different pathway. Since 2AP probes its local base stacking environment, K+ can be considered to induce misfolding. Binding of both Na+ and K+ was specific, since single base mutations could fully inhibit 2AP fluorescence for both metals. The binding thermodynamics was measured by temperature-dependent experiments revealing enthalpy-driven binding for both metals and less coordination sites compared to G-quadruplex DNA. Cleavage activity assays indicated a moderate cleavage activity with 10 mM K+, while further increase of K+ inhibited the activity, also supporting its misfolding of the DNAzyme. For comparison, a G-quadruplex DNA was also studied using the same system, where Na+ and K+ led to the same final state with only around 8-fold difference in Kd. This study provides interesting insights into strategies for discriminating Na+ and K+.
Highlights
Specific binding of metal ions is an interesting challenge
The products were suspended in 8 M urea and analyzed by 15% denaturing polyacrylamide gel electrophoresis (dPAGE)
This example further confirmed that the final Na+ and K+ binding states were different for the DNAzyme. We studied another DNAzyme named Tm7, which is lanthanide-dependent with a simple loop structure (Figure 1D)
Summary
Specific binding of metal ions is an interesting challenge. Li+, Na+ and K+ are very similar to each other. With the same charge and preference for oxygenbased ligands, they mainly differ by size. In addition to relying on size and charge for metal recognition
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