Oligodeoxynucleotides containing conformationally constrained abasic sites: a UV- and fluorescence spectroscopic investigation on duplex stability and structure

The synthesis and incorporation into oligodeoxy­nucleotides of two novel, conformationally restricted abasic (AB) site analogs are described. The stability of oligonucleotide 18mer duplexes containing one such AB site opposite any of the four natural DNA bases was investigated by UV melting curve analysis and compared to that of duplexes containing a conformationally flexible propanediol unit 1 or a tetrahydrofuran unit 2 as an AB site analog. No major differences in the melting temperatures (ΔT(m) 0–3°C) between the different abasic duplexes were observed. All AB duplexes were found to have T(m)s that were lower by 9–15°C relative to a fully matched 18mer control duplex, and by 4–10°C relative to the corresponding 19mer duplexes in which the AB site is replaced by a mismatched nucleobase. Thus we conclude that the loss of stability of a duplex that is encountered by removal of a nucleobase from the stack cannot be compensated with conformational restriction of the AB site. From the van’t Hoff transition enthalpies obtained from the melting curves, it appears that melting cooperativity is higher for the duplexes containing the conformationally rigid AB sites. Fluorescence quenching experiments with duplexes containing the fluorescent base 2-amino­purine (2AP) opposite the AB sites showed a weak tendency towards more efficient stacking of this base in duplexes containing the conformationally constrained AB sites. Thus, such AB sites may structurally stabilize the cavity formed by the removal of a base. Potential applications emerging from the properties of such conformationally constrained AB sites in DNA diagnostics are discussed

Propagation of melting cooperativity along the phosphodiester backbone of DNA

The role of the DNA phosphodiester backbone in the transfer of melting cooperativity between two helical domains was experimentally addressed with a helix-bulge-helix DNA model, in which the bulge consisted of a varying number of either conformationally flexible propanediol or conformationally constrained bicyclic anucleosidic phosphodiester backbone units. We found that structural communication between two double helical domains is transferred along the DNA backbone over the equivalent of ca. 12-20 backbone units, depending on whether there is a symmetric or asymmetric distribution of the anucleosidic units on both strands. We observed that extension of anucleosidic units on one strand only suffices to disrupt cooperativity transfer in a similar way as if extension occurs on both strands, indicating that the length of the longest anucleosidic inset determines cooperativity transfer. Furthermore, conformational rigidity of the sugar unit increases the distance of coopertivity transfer along the phosphodiester backbone. This is especially the case when the units are asymmetrically distributed in both strand