Abstract
To investigate the effect of sugar pucker conformation on DNA-protein interactions, we used 2′-O-methyl nucleotide (2′-OMeN) to modify the EcoRI recognition sequence -TGAATTCT-, and monitored the enzymatic cleavage process using FRET method. The 2′-O-methyl nucleotide has a C3′-endo sugar pucker conformation different from the C2′-endo sugar pucker conformation of native DNA nucleotides. The initial reaction velocities were measured and the kinetic parameters, Km and Vmax were derived using Michaelis-Menten equation. Experimental results showed that 2′-OMeN substitutions for the EcoRI recognition sequence decreased the cleavage efficiency for A2, A3 and T4 substitutions significantly, and 2′-OMeN substitution for T5 residue inhibited the enzymatic activity completely. In contrast, substitutions for G1 and C6 could maintain the original activity. 2′-fluoro nucleic acid (2′-FNA) and locked nucleic acid (LNA) having similar C3′-endo sugar pucker conformation also demonstrated similar enzymatic results. This position-dependent enzymatic cleavage property might be attributed to the phosphate backbone distortion caused by the switch from C2′-endo to C3′-endo sugar pucker conformation, and was interpreted on the basis of the DNA-EcoRI structure. These 2′-modified nucleotides could behave as a regulatory element to modulate the enzymatic activity in vitro, and this property will have potential applications in genetic engineering and biomedicine.
Highlights
Nucleic acid chemistry has seen a remarkable progress in developing novel nucleotide derivatives [1]
We have demonstrated that the enzymatic cleavage activity can be modulated by 29-O-methyl nucleotide (29-OMeN) substitutions for the EcoRI recognition sequence
Mechanisms have been proposed to interpret the unusual enzymatic behavior on the basis of the crystal structure of EcoRI-DNA complex. These results suggested that 29-OMeN substitution could be used as a regulatory element to regulate the EcoRI enzymatic activity in vitro
Summary
Nucleic acid chemistry has seen a remarkable progress in developing novel nucleotide derivatives [1]. With chemical modifications on bases, ribose or phosphate group, these nucleotide derivatives have demonstrated many unusual properties. Typical examples include 29-O-methyl nucleotide (29-OMeN) and locked nucleic acid (LNA). LNA demonstrates an enhanced binding affinity toward their complementary DNA targets, whereas 29-OMeN binds to complementary RNA nucleotides more favorably [4,5,6]. 29-OMeN exhibits a faster hybridization dynamics than usual nucleotides [10]. Both LNA and 29-OMeN demonstrate the capability of modulating structure transitions of the G-quadruplexes between the parallel and the anti-parallel folding topologies [11]
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