A series of four hairpin deoxyoligonucleotides was synthesized with a four-nucleotide central loop (either C or G) flanked by the complementary sequences d(T)10 and d(A)10. Two of the molecules contain either a 3'-p-3' or 5'-p-5' linkage in the loop, so that the strands in the stem have the same, that is, parallel (ps) polarity. The pair of reference oligonucleotides have normal phosphodiester linkages throughout and antiparallel (aps) stem regions. All the molecules adopt a duplex helical structure in that (i) the electrophoretic mobilities in polyacrylamide gels of the ps and aps oligomers are similar. (ii) The ps hairpins are substrates for T4 polynucleotide kinase, T4 DNA ligase, and Escherichia coli exonuclease III. (iii) Salt-dependent thermal transitions are observed for all hairpins, but the ps molecules denature 10 degrees C lower than the corresponding aps oligomers. (iv) The ultraviolet absorption and circular dichroism spectra are indicative of a base-paired duplex in the stems of the ps hairpins but differ systematically from those of the aps counterparts. (v) The bis-benzimidazole drug Hoechst-33258, which binds in the minor groove of B-DNA, exhibits very little fluorescence in the presence of the ps hairpins but a normal, enhanced emission with the aps oligonucleotides. In contrast, the intercalator ethidium bromide forms a strongly fluorescent complex with all hairpins, the intensity of which is even higher for the ps species. (vi) The pattern of chemical methylation is the same for both the ps and aps hairpins. The combined results are consistent with the prediction from force field analysis of a parallel stranded right-handed helical form of d(A)n.d(T)n with a secondary structure involving reverse Watson-Crick base pairs and a stability not significantly different from that of the B-DNA double helix. Models of the various hairpins optimized with force field calculations are described.
We have recently shown that DNA containing homopolymeric A-T base pairs can form a parallel-stranded intramolecular duplex [van de Sande et al. (1988) Science (Washington, D.C.) 241, 551-557]. In the present paper, we demonstrate that parallel-stranded DNA can also be formed in unconstrained bimolecular DNA of appropriate sequence homology. Three deoxyoligonucleotides, a 21-mer [dCCCATATATATTTTTTTTCCC], a ps-15-mer [dTATATATAAAAAAAA], and an aps-15-mer [dAAAAAAAATATATAT], have been synthesized. Annealing of 21-mer and aps-15-mer results in the formation of a conventional antiparallel duplex (aps); however, the combination of 21-mer and ps-15-mer forms a duplex in which the two strands are in a parallel orientation (ps). The parallel-stranded structure was established from the following criteria: (i) The parallel-stranded structure shows a 1:1 stoichiometry of the constituent strands. (ii) Gel electrophoretic mobility of the ps and aps duplexes are similar under native conditions. (iii) Spectroscopic properties of the ps duplex are characteristics for a base-paired structure but are different from the aps structure. (iv) Both duplexes undergo a thermally induced helix to coil transition; however, the melting temperature for the ps duplex is 22 degrees C lower. (v) The minor groove binding drug Hoechst 33258 shows a reduced affinity for the ps compared to the aps duplex. (vi) The parallel-stranded duplex is not a substrate for DNA Escherichia coli polymerase I (Klenow fragment) or AMV reverse transcriptase. Parallel-stranded DNA can exist under normal solution conditions, but competition experiments show it to be thermodynamically less favorable than the conventional antiparallel form.
We report a comparative spectroscopic study of a novel self-complementary duplex decamer, d(GCGAAT-3'-3'-(alpha T)-5'-5'-CGC)2, in which an alpha-anomeric nucleotide has been inserted into the sequence in a parallel orientation via 3'-3' and 5'-5' phosphodiester bonds, and its unmodified B-DNA analog, d(GCGAATTCGC)2. Plots of the hyperchromicity and circular dichroism of these oligonucleotides are virtually identical, indicating that the overall base stacking and handedness are preserved in the alpha duplex. Thermodynamic parameters extracted from UV melting experiments show that the alpha duplex is only slightly less stable than the control. A near complete set of 1H and 31P nuclear magnetic resonance (NMR) assignments were obtained for both duplexes using classical one- and two-dimensional approaches. Several lines of evidence, in particular, imino 1H, 31P, nuclear Overhauser enhancement, and deoxyribose ring proton spin-spin coupling data, convincingly demonstrate that the overall structural integrity of the alpha and control duplexes are quite comparable, with any perturbations in the former localized to the regions of the construct encompassing the alpha-nucleotide and the unique backbone linkages. Specifically, the alpha duplex exhibits normal Watson-Crick type base pairing, it remains antiparallel except at the inverted nucleotide, all bases are in the anti orientation, and the sugar ring puckering is predominantly "S"-type. However, the J-coupling information for the alpha-nucleotide and the neighboring (3') cytidine are notably different, and reflect a decrease in the amplitude of the sugar pucker in alpha T7, and a significant shift in the conformational equilibrium of the furanose ring in C8 toward the "N"-type pucker. The feasibility of synthesizing oligodeoxynucleotides containing a combination of alpha sugars and short parallel stranded segments, their propensity for forming stable duplexes, and the structural insights into such complexes reported here are of potential importance in the area of antisense therapy.
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