Oligonucleotide Analogues with Integrated Bases and Backbone. Part 17

Abstract: The formation of cyclic duplexes (pairing) of known oxymethylene‐linked self‐complementary U*[o]A(*) dinucleosides contrasts with the absence of pairing of the ethylene‐linked U*[ca]A(*) analogues. The origin of this difference, and the expected association of U*[x]A(*) and A*[x]U(*) dinucleosides with x=CH2, O, or S was analysed. According to this analysis, pairing occurs via constitutionally isomeric Watson–Crick, reverse Watson–Crick, Hoogsteen, or reverse Hoogsteen H‐bonded linear duplexes. Each one of the… Show more

“…This was shown by analysing the association in CDCl 3 of partially protected, self-complementary di-and tetranucleosides of the type U*[x]A ( * )1 ) and A*[x]U ( * ) , possessing a variety of linking elements [1 -9]. A conformational analysis of the diastereoisomers of the constitutionally isomeric cyclic duplexes of self-complementary ethylene-, oxymethylene-, thiomethylene-, and aminomethylene-linked dinucleosides rationalized the propensity of pairing, i.e., the formation of cyclic duplexes [7]. Pairing of partially protected, selfcomplementary dinucleosides in CDCl 3 depends on the structure of the linker, the synorientation of the nucleobases, and the conformation of the ribose unit [7].…”

“…A conformational analysis of the diastereoisomers of the constitutionally isomeric cyclic duplexes of self-complementary ethylene-, oxymethylene-, thiomethylene-, and aminomethylene-linked dinucleosides rationalized the propensity of pairing, i.e., the formation of cyclic duplexes [7]. Pairing of partially protected, selfcomplementary dinucleosides in CDCl 3 depends on the structure of the linker, the synorientation of the nucleobases, and the conformation of the ribose unit [7]. The resulting cyclic duplexes form Watson -Crick (WC), reverse-Watson -Crick (rWC), p-toluenesulfonate 6 with EtNH 2 in DMF (88%) [9], and the acetamide 9 (59%) by hydrogenation of 8 in the presence of Pd/C and Ac 2 O [9].…”

“…Reduction [7] [20] of aldehyde 10 gave 11 (93%) that was transformed into the (monomethoxy)trityl ether 12 (85%; Scheme 2). Desilylation of 12 with Bu 4 NF yielded 91% of the selectively protected alcohol 13 that provided the p-toluenesulfonate 15 (75%) under standard conditions [9].…”

“…Part). Debenzoylation [7] of 22 yielded 68% of dinucleoside 23 that was desilylated with (HF) 3 · Et 3 N in THF to the alcohol 24 (70%). Detritylation of 23 with Cl 2 CHCOOH and Et 3 SiH yielded 73% of the silyl ether 25; similarly, 24 yielded 78% of diol 26.…”

“…Similarly to 2 and 3, the monomethoxytrityl ethers 5 -9 adopt a syn-conformation. HOÀC(5') of 5 forms a partially persistent H-bond to C(2)¼O, leading to a more extensive population of the gg-conformer (J(4',5'a) þ J(4',5'b) ¼ 7.9 Hz) [7] and to a less pronounced (N)-conformation of the ribose ring of 5 than for the corresponding azides 3 and 8, p-toluenesulfonates 2 and 6, and acetamide 9. The syn-conformation is expected on account of the substitution at C (6).…”

Oligonucleotide Analogues with Integrated Bases and Backbones. Part 26

“…This was shown by analysing the association in CDCl 3 of partially protected, self-complementary di-and tetranucleosides of the type U*[x]A ( * )1 ) and A*[x]U ( * ) , possessing a variety of linking elements [1 -9]. A conformational analysis of the diastereoisomers of the constitutionally isomeric cyclic duplexes of self-complementary ethylene-, oxymethylene-, thiomethylene-, and aminomethylene-linked dinucleosides rationalized the propensity of pairing, i.e., the formation of cyclic duplexes [7]. Pairing of partially protected, selfcomplementary dinucleosides in CDCl 3 depends on the structure of the linker, the synorientation of the nucleobases, and the conformation of the ribose unit [7].…”

“…A conformational analysis of the diastereoisomers of the constitutionally isomeric cyclic duplexes of self-complementary ethylene-, oxymethylene-, thiomethylene-, and aminomethylene-linked dinucleosides rationalized the propensity of pairing, i.e., the formation of cyclic duplexes [7]. Pairing of partially protected, selfcomplementary dinucleosides in CDCl 3 depends on the structure of the linker, the synorientation of the nucleobases, and the conformation of the ribose unit [7]. The resulting cyclic duplexes form Watson -Crick (WC), reverse-Watson -Crick (rWC), p-toluenesulfonate 6 with EtNH 2 in DMF (88%) [9], and the acetamide 9 (59%) by hydrogenation of 8 in the presence of Pd/C and Ac 2 O [9].…”

“…Reduction [7] [20] of aldehyde 10 gave 11 (93%) that was transformed into the (monomethoxy)trityl ether 12 (85%; Scheme 2). Desilylation of 12 with Bu 4 NF yielded 91% of the selectively protected alcohol 13 that provided the p-toluenesulfonate 15 (75%) under standard conditions [9].…”

“…Part). Debenzoylation [7] of 22 yielded 68% of dinucleoside 23 that was desilylated with (HF) 3 · Et 3 N in THF to the alcohol 24 (70%). Detritylation of 23 with Cl 2 CHCOOH and Et 3 SiH yielded 73% of the silyl ether 25; similarly, 24 yielded 78% of diol 26.…”

“…Similarly to 2 and 3, the monomethoxytrityl ethers 5 -9 adopt a syn-conformation. HOÀC(5') of 5 forms a partially persistent H-bond to C(2)¼O, leading to a more extensive population of the gg-conformer (J(4',5'a) þ J(4',5'b) ¼ 7.9 Hz) [7] and to a less pronounced (N)-conformation of the ribose ring of 5 than for the corresponding azides 3 and 8, p-toluenesulfonates 2 and 6, and acetamide 9. The syn-conformation is expected on account of the substitution at C (6).…”

Oligonucleotide Analogues with Integrated Bases and Backbones. Part 26

Replacement of Water Molecules in a Phosphate Binding Site by Furanoside‐Appended lin‐Benzoguanine Ligands of tRNA‐Guanine Transglycosylase (TGT)

8‐Substituted, syn‐Configured Adenosine Derivatives as Potential Inhibitors of the Enzyme IspE from the Non‐Mevalonate Pathway of Isoprenoid Biosynthesis