Rearrangement nucleoside

Purines, N-alkyl-N-phenyl-synthesis, 5, 576 Purines, alkylthio-hydrolysis, 5, 560 Mannich reaction, 5, 536 Michael addition reactions, 5, 536 Purines, S-alkylthio-hydrolysis, 5, 560 Purines, amino-alkylation, 5, 530, 551 IR spectra, 5, 518 reactions, 5, 551-553 with diazonium ions, 5, 538 reduction, 5, 541 UV spectra, 5, 517 Purines, N-amino-synthesis, 5, 595 Purines, aminohydroxy-hydrogenation, 5, 555 reactions, 5, 555 Purines, aminooxo-reactions, 5, 557 thiation, 5, 557 Purines, bromo-synthesis, 5, 557 Purines, chloro-synthesis, 5, 573 Purines, cyano-reactions, 5, 550 Purines, dialkoxy-rearrangement, 5, 558 Purines, diazoreactions, 5, 96 Purines, dioxo-alkylation, 5, 532 Purines, N-glycosyl-, 5, 536 Purines, halo-N-alkylation, 5, 529 hydrogenolysis, 5, 562 reactions, 5, 561-562, 564 with alkoxides, 5, 563 synthesis, 5, 556 Purines, hydrazino-reactions, 5, 553 Purines, hydroxyamino-reactions, 5, 556 Purines, 8-lithiotrimethylsilyl-nucleosides alkylation, 5, 537 Purines, N-methyl-magnetic circular dichroism, 5, 523 Purines, methylthio-bromination, 5, 559 Purines, nitro-reactions, 5, 550, 551 Purines, oxo-alkylation, 5, 532 amination, 5, 557 dipole moments, 5, 522 H NMR, 5, 512 pJfa, 5, 524 reactions, 5, 556-557 with diazonium ions, 5, 538 reduction, 5, 541 thiation, 5, 557 Purines, oxohydro-IR spectra, 5, 518 Purines, selenoxo-synthesis, 5, 597 Purines, thio-acylation, 5, 559 alkylation, 5, 559 Purines, thioxo-acetylation, 5, 559... 

A similar rearrangement takes place with A,A-dibenzyl-L-serme benzyl ester [UO (equation 68) and with partially protected carbocyclic nucleosides, such as l-hydroxymethyl-4-(2,4-dinitroanilino)cyclopentane-2,3-diol [133]... 

O-isopropylidene derivative (57) must exist in pyridine solution in a conformation which favors anhydro-ring formation rather than elimination. Considerable degradation occurred when the 5-iodo derivative (63) was treated with silver fluoride in pyridine (36). The products, which were isolated in small yield, were identified as thymine and l-[2-(5-methylfuryl)]-thymine (65). This same compound (65) was formed in high yield when the 5 -mesylate 64 was treated with potassium tert-hx Xy -ate in dimethyl sulfoxide (16). The formation of 65 from 63 or 64 clearly involves the rearrangement of an intermediate 2, 4 -diene. In a different approach to the problem of introducing terminal unsaturation into pento-furanoid nucleosides, Robins and co-workers (32,37) have employed mild base catalyzed E2 elimination reactions. Thus, treatment of the 5 -tosylate (59) with potassium tert-butylate in tert-butyl alcohol afforded a high yield of the 4 -ene (60) (37). This reaction may proceed via the 2,5 ... 

C-Acyclic nucleoside analogs of inosine and guanosine 8-[(/ 5)-2,3-dihydroxypropyl]imidazo[l,5-fl]-l,3,5-triazin-4(3//)-ones were synthesized. The route involved the cyclization and rearrangement of 5-acylamino-5-allyl-6-amino-4,5-dihydropyrimidin-4-ones (1122) to 8-allylimidazo[l,5-a]-l,3,5-triazin-4(3//)-ones (1123). Osmium tetroxide hydroxylation gave 1124. None of these analogs showed appreciable antiviral or antitumor cell activity (84NAR263 87MI6). 

The reaction of 1-deoxy-l-isothiocyante-D-fructose with carbon disulfide was dependent on the conditions whereby acyclic nucleosides of type 2.7 (1199) or 1200 could be formed. The latter was rearranged to 1201 by the action of acid (94MI8). 

Acyclo-C-nucleoside analogs possessing oxazole rings were obtained from the rearrangement of lactoxime o-vinyl ethers or sugar lactoxime o-vinyl ethers [92JCS(P1)2127]. In some cases, epimerization took place at the C-2 position. 

Optically pure 7-oxanorbom-5-en-2-yl derivatives ("naked sugars") are readily available. Substitution of their centers C(3), C(5) and C(6) can be done with high stereo- and regioselectivity in a predictable fashion. The polysubstituted 7-oxanor-boman-2-ones so-obtained can be transformed into D- or L-carbohydrate derivatives, C-nucleoside precursors or polysubstituted cyclohex-2-enones and cyclohexenols (Scheme 12). Stereoselective rearrangements of the 7-oxanorbom-2-yl systems into polyhydroxylated cyclopentyl derivatives are also possible. 

The carbocyclic 434, precursor of nucleoside analogues, was synthesized from the commercially available (—)-/3-pinene 433. The Beckmann rearrangement was used to cleave the carbocyclic ring and cis stereochemistry of the ring substituents is guaranteed (equation 183). 

Stanovnik and co-workers (100,101) systematically investigated the cycloaddition reactions of diazoalkanes with unsaturated nitrogen heterocycles, such as azolo-[l,5-fl]pyridines, pyridazin-3(2/7)-ones, and [fo]-fused azolo- and azinopyridazines. The Stanovnik group have studied the further transformations of the products and reviews of this chemistry are available. In a typical example, the reaction of 6-chlorotetrazolo[l,5-/7]pyridazine (37) with 2-diazopropane yields the NH,NH-dihy-dro-pyrazolo[4,3-(i]tetrazolo[l,5-/7]pyridazine 38 (102) (Scheme 8.11). The latter substrate reacts with acetone to produce an azomethine imine 39 that thermally rearranges to give the fused dihydro-1,2-diazepine 40. The azomethine imine obtained with glucose can be trapped with methyl acrylate to furnish the C-nucleoside 41 (103). 

A unique acyclic C-nucleoside containing the pyrido[2,3-. ]pyrazine nucleus 675 was prepared by the action of AcOH, whereby rearrangement of 3 -keto-2 -deoxypyrazine C-nucleoside derivatives 673 occurs via the intramolecular aminal intermediate 674, followed by furanose ring opening and subsequent aromatization (Equation 56)... 

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