The investigation of the three-dimensional structure of the DNA aptamer d(G1G2T3-T4G5G6T7G8T9G10G11T12T13G14G15) which binds to and inhibits thrombin has been carried out by NMR methods. This DNA exhibits a number of long-range NOEs between residues which are not adjacent in sequence, which allowed the determination of the novel tertiary structure adopted. This DNA adopts a highly compact, highly symmetrical structure which consists of two tetrads of guanosine base pairs and three loops. The residues of the tetrads alternate anti-syn-anti-syn. This novel structural motif for DNA may also be relevant to the structure of telomere DNA.
Triethylammonium 1,2-di-O-hexadecyl-rac-glycero-3-H-phosphonate (2) was coupled to the 5' terminus of oligodeoxynucleotides via hydrogen phosphonate solid support DNA synthesis methodology. Duplex DNA oligomers with a single 5'-phospholipid melted at lower temperatures than the corresponding unmodified duplex, but duplexes bearing lipids at each 5' end had higher Tms. In uptake experiments with L929 cells, 8-10 times more lipid-DNA became cell-associated than did unmodified DNA. Unmodified antisense diesters were inactive in a VSV antiviral assay in L929 cells (at up to 200 microM). Attachment of a lipid to the oligomer, however, led to a greater than 90% at 150 microM (greater than 80% at 100 microM) reduction in viral protein synthesis. The antiviral activity depended on the sequence of the oligodeoxynucleotide, but some compounds having little or no base complementarity to the viral target were also effective. Phosphorothioate derivatives reduced viral protein synthesis by 20-30% at 100 microM in the VSV assay. The lipid-DNA compounds were not toxic to the cells at up to 100 microM.
2'-Deoxyguanosine (G) analogues carrying various hydrophobic substituents in the N2 and C8 positions were synthesized and introduced through solid-phase synthesis into 15-mer oligodeoxynucleotide, GGTTGGTGTGGTTGG, which forms a chairlike structure consisting of two G-tetrads and is a potent thrombin inhibitor. The effects of the substitutions at N2 and C8 of the G-tetrad-forming G residues on the thrombin inhibitory activity are relatively small, suggesting that these substitutions cause relatively small perturbations on the chairlike structure formed by the oligodeoxynucleotide. Introduction of a benzyl group into N2 of G6 and G11 and naphthylmethyl groups into N2 of G6 increased the thrombin inhibitory activity, whereas other substituents in these positions had almost no effect or decreased the activity. Particularly, the oligodeoxynucleotide carrying a 1-naphthylmethyl group in the N2 position of G6 showed an increase in activity by about 60% both in vitro and in vivo. Substitutions on the N2 position of other G residues had little effect or decreased the activity. Introduction of a relatively small group, such as methyl and propynyl, into the C8 positions of G1, G5, G10, and G14 increased the activity, presumably due to the stabilization of a chairlike structure, whereas introduction of a large substituent group, phenylethynyl, decreased the activity, probably due to the steric hindrance.
The syntheses of certain analogues of the DNA minor groove binding agent Hoechst 33258 designed to exhibit altered sequence recognition are described. The structural modifications include the following: substitution of pyridine for the benzene ring of the benzimidazole moiety, replacement of one benzimidazole unit by a benzoxazole in the two possible orientations with respect to the DNA receptor, and a synthesis of 2,2'-m-phenylene-bis[6-(4-methyl-1-piperazinyl)benzimidazole]. Sequence recognition of these agents on a HindIII/EcoRI fragment of pBR322 DNA was determined by MPE footprinting procedures. Some of the analogues exhibited altered DNA sequence preference compared with Hoechst 33258. In particular, a structure bearing a benzoxazole moiety with the oxygen oriented inward to the minor groove together with an inward-directed pyridine nitrogen appears to confer the property of recognition of a GC base pair within the binding sequence. The possible factors, structural, stereochemical, and electrostatic, contributing to the altered DNA sequence recognition properties are discussed.
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