N 2 -Alkyl analogues of 8-oxo-7,8-dihydro-2′-deoxyguanosine (OG) were synthesized (alkyl = propyl, benzyl) via reductive amination of the protected OG nucleoside and incorporated into various positions of an RNA strand. Thermal stability studies of duplexes containing A or C opposite a single modified base revealed only moderate destabilization. Both OG as well as its N 2 -alkyl analogues can pair opposite A or C with nearly equal stability, potentially offering a new means of modulating RNA-protein interactions in the minor vs. major grooves.Chemical modification of nucleosides has been a successful strategy for antiviral, 1 antimetabolite, 2 antitumor, 3,4 and diagnostic agents. 4 Modified nucleosides in oligomers exist naturally due to cellular reactions on both the bases and the sugars of DNA and RNA and have also been introduced into oligomers synthetically. Modified nucleosides are common in the RNA field due to applications in investigating reaction mechanisms, 5,6 imparting favorable properties on siRNAs, 7,8 probing RNA structure and function, 9-11 and exploring interactions between RNA and proteins or small molecules. 1 Both sugar and backbone modifications have been explored to improve nuclease stability and target identification in antisense and siRNA approaches; 12,13 however, examples of base modification in these applications are few by comparison. [14][15][16] The ability to alter the hydrophobicity and steric properties of the major and minor groove appeared to us as a possible means of modulating both interstrand interactions as well as nucleic acid-protein interactions 7,17,18 thereby expanding the range of nucleic acid modifications in the design of DNA and RNA therapeutics.Inspiration for the present work came from one of the major products of oxidative damage to the DNA, namely 8-oxo-7,8-dihydro-2′-deoxyguanosine (OG). 19- group at C8 of the purine increases the propensity of the purine to flip from the normal anti conformation to syn, where it exposes the Hoogsteen face of the purine to base pairing. Like its parent guanine, OG(anti) accepts cytosine as a Watson-Crick partner, while the complementary base for OG(syn) is adenosine ( Figure 1). During the anti-syn conformational change, the N 2 -amino group and the C8-oxo groups exchange positions between the minor and major grooves ( Figure 1). As a result, addition of an alkyl or aryl group to the exocyclic amine should enable the placement of the substituent in either groove, in a way that will be governed by the identity of the base opposite.OG can be synthetically incorporated into DNA and RNA oligomers via the corresponding phosphoramidite. While we, among others, have been studying OG and its incorporation into oligomers, including chemical characterization and enzymology with DNA processing enzymes, 22,23 OG is rarely studied in RNA. Thermal denaturation studies, 22,24,25 NMR studies, 26 and x-ray crystallographic structures 23,27,28 of the OG(syn):A(anti) base pair show that the B-form DNA helix is only very slightly perturb...
