8-Aza-7-deazaadenine N8- and N8-(β-D-2′-Deoxyribofuranosides): Building blocks for automated DNA synthesis and properties of oligodeoxyribonucleotides

Oligonucleotides with alternating 8-aza-7-deaza-2′-deoxyadenosine (= c⁷z⁸A_d2) and dT residues (see 11, 14 and 16 ) or 4-aminopyrazolo [3,4-d] pyrimidine N²-(β-D -2′-deoxyribofuranoside) (= c⁷z⁸A′_d¹); ( 3 ) and dT residues (see 12 ) have been prepared by solid-phase synthesis using P(III) chemistry, Additionally, palindromic oligomers derived from d(C-T-G-G-A-T-C-C-A-G) but containing 2 or 3 instead of dA (see 18 – 22 ) have been synthesized. Benzoylation of 2 or 3 , followed by 4,4′-dimethoxytritylation and subsequent phosphitylation yielded the methyl or the cyanoethyl phosphoramidites 8a,b and 9 . They were employed in automated. DNA synthesis. Alternating oligomers containing 2 or 3 showed increase dT_m values compared to those with dA, in particular 12 with an unusual N²-glycosylic bond. The palindromic oligomers 18 - 22 containing 2 or 3 instead of dA outside of the enzymic recognition side reduced the hydrolysis rate, replacement within d(G-A-T-C) abolished phosphodiester hydrolysis.     

Oligonucleotides Containing 7‐Deaza‐2′‐deoxyinosine as Universal Nucleoside: Synthesis of 7‐Halogenated and 7‐Alkynylated Derivatives,Ambiguous Base Pairing,and Dye Functionalization by the Alkyne–Azide ‘Click’ Reaction

Oligonucleotides containing 7‐deaza‐2′‐deoxyinosine derivatives bearing 7‐halogen substituents or 7‐alkynyl groups were prepared. For this, the phosphoramidites 2b – 2g containing 7‐substituted 7‐deaza‐2′‐deoxyinosine analogues 1b – 1g were synthesized (Scheme 2). Hybridization experiments with modified oligonucleotides demonstrate that all 2′‐deoxyinosine derivatives show ambiguous base pairing, as 2′‐deoxyinosine does. The duplex stability decreases in the order C_d>A_d>T_d>G_d when 2b – 2g pair with these canonical nucleosides (Table 6). The self‐complementary duplexes 5′‐d(F⁷c⁷I‐C)₆, d(Br⁷c⁷I‐C)₆, and d(I⁷c⁷I‐C)₆ are more stable than the parent duplex d(c⁷I‐C)₆ (Table 7). An oligonucleotide containing the octa‐1,7‐diyn‐1‐yl derivative 1g , i.e., 27 , was functionalized with the nonfluorescent 3‐azido‐7‐hydroxycoumarin ( 28 ) by the Huisgen–Sharpless–Meldal cycloaddition ‘click’ reaction to afford the highly fluorescent oligonucleotide conjugate 29 (Scheme 3). Consequently, oligonucleotides incorporating the derivative 1g bearing a terminal C?C bond show a number of favorable properties: i) it is possible to activate them by labeling with reporter molecules employing the ‘click’ chemistry. ii) Space demanding residues introduced in the 7‐position of the 7‐deazapurine base does not interfere with duplex structure and stability (Table 8). iii) The ambiguous pairing character of the nucleobase makes them universal probes for numerous applications in oligonucleotide chemistry, molecular biology, and nanobiotechnology.     

2′-Deoxy-β-D-ribofuranosides of N6-Methylated 7-Deazaadenine and 8-Aza-7-deazaadenine: Solid-phase synthesis of oligodeoxyribonucleotides and properties of self-complementary duplexes

The syntheses of 7-deaza-N⁶-methyladenine N⁹-(2′-deoxy-β-D -ribofuranoside) ( 2 ) as well as of 8-aza-7-deaza-N⁶-methyladenine N⁸? and N⁹?(2′-deoxyribofuranosides) ( 3 and 4 , resp.) are described. A 4,4′-dimeth-oxylritylation followed by phosphitylation yielded the methyl phosphoramidites 12–14 . They were employed together with the phosphoramidite of 2′-deoxy-N⁶v-methyladenosine ( 15 ) in automated solid-phase oligonucleotide synthesis. Alternating or palindromic oligonucleotides derived from d(A-T)₆ or d(A-T-G-C-A-G-A*-T-C-T-G-C-A) but containing one methylated pyrrolo[2,3-d]pyrimidine or pyrazolo[3,4-d]pyrimidine moiety in place of a N⁶-methylaminopurine (A*) were synthesized. Melting experiments showed that duplex destabilization induced by a N⁶-Me group of 2′-deoxy-N⁶-methyladenosine is reversed by incorporation of 8-aza-7-deaza-2′-deoxy-N⁶-meihyladenosine, whereas 7-deaza-2′-deoxy-N⁶-methyladenostne decreased the T_m value further. Regiospecific phosphodiester hydrolysis of d(A-T-G-C-A-G-m⁶A-T-C-T-G1-C-A) by the endodeoxyribonuclease Dpn I, yielding d(A-T-G-C-A-G-m⁶A) and d(pT-C-T-G-C-A), was prevented when the residue c⁷m⁶A_d ( 2 ), c⁷m⁶z⁸A_d ( 3 ), or c⁷m⁶z⁸A_d′ ( 4 ) replaced m⁶A_d ( 1 ) indicating that N(7) of N⁶-methyladenine is a proton-acceptor site for the endodeoxyribonuclease.     

7-Deazaguanine DNA: Oligonucleotides with hydrophobic or cationic side chains

The phosphoramidites 6b and 9 as well as the phosphonate 6a derived from 7-(hex-1-ynyl)- and 7-[5-(trifluoroacetamido)pent-1-ynyl]-substituted 7-deaza-2′-deoxyguanosines 1 and 10 , respectively, were prepared (Scheme 1). They were employed in solid-phase oligodeoxynucleotide synthesis of the alternating octamers d(hxy⁷c⁷G-C)₄ ( 12 ), d(C-hxy⁷c⁷G)₄ ( 13 ), and d(npey ⁷c⁷G-C)₄ ( 15 ) as well as of other oligonucleotides (see 22 – 25 ; Table 2; hxy = hex-1-ynyl, npey = 5-aminopent-1-ynyl). The T_m values and the thermodynamic data of duplex formation were determined and correlated with the major-groove modification of the DNA fragments. A hexynyl side chain introduced into the 7-position of a 7-deazaguanine residue (see 1 ) was found to fit into the major groove without any protrusion. The incorporation of the (5-aminopent-1-ynyl)-modified 7-deaza-2′-deoxyguanosine 2 into single-stranded oligomers of the type 24 and 25 did not lead to change in duplex stability compared to the parent oligonucleotides. The self-complementary oligomer 15 with alternating npey⁷c⁷G_d ( 2 ) and dC units did not lead to a cooperative melting, either due to orientational disorder or interaction of the 5-aminopent-1-ynyl moiety with a base or with phosphate residues nearby or on the opposite strand.     

Duplex Stabilization of DNA: Oligonucleotides containing 7-substituted 7-deazaadenines

The oligonucleotide building blocks 4b–d derived from 7-bromo-, 7-chloro-, and 7-methyl-substituted 7-deaza-2′-deoxyadenosines 3b–d were prepared. They were employed in the solid-phase synthesis of the oligonucleotides 7–25 . The dA residues of the homomer d(A₁₂), the alternating d[(A-T)₆], and the palindromic d(G-T-A-G-A-A-T-T-C-T-A-C) were replaced by 3b–d as well as by the parent 7-deaza-2′-deoxyadenosine ( 3a ). The melting profiles and CD spectra of oligonucleotide duplexes, showing this major groove modification, were measured, and the T_m values as well as the thermodynamic data were determined. It was found that small substituents such as Br, Cl, or Me introduced in the 7-position of a 7-deazaadenine residue increase the duplex stability compared to oligonucleotides containing adenine.     

Oligodeoxyribonucleotides Containing 4-Aminobenzimidazole in Place of Adenine: Solid-phase synthesis and base pairing

Oligonucleotides containing 4-aminobenzimidazole 2′-deoxyribofuranoside (1,3-dideaza-2′-deoxyadenosine; c¹c³A_d, 1 ) were synthesized. For this purpose, various NH₂-protecting groups were investigated, and the [(9H-fluoren-9-yl)methoxy]carbonyl group was selected for phosphoramidite protection (→ 4c ). Apart from the phosphoramidite 3 , the phosphonate 2 was prepared. Compound 1 was incorporated in a homooligonuclectide as well as in oligomers containing naturally occurring nucleosides. The T_m values and the thermodynamic data of various duplexes ( 11 · 10 , 17 · 10 , 18 · 10 ) containing 4-aminobenzimidazole were determined. Although d[(c¹c³A)₂₀] ( 11 ) does not form a Hoogsteen duplex with d(T₂₀) ( 10 ) as observed with d[(c¹A)₂₀], it destabilizes the Watson-Crick duplexes to a much smaller extent than it was expected from a bulged loop structure. Apparently, 4-aminobenz-imidazole interacts with regular nucleoside residues within a Watson-Crick duplex structure, most likely by vertical stacking. According to the low basicity of the amino group, only weak H-bonding is expected.     

Hoogsteen-Duplex DNA: Synthesis and base pairing of oligonucleotides containing 1-deaza-2′-deoxyadenosine

Oligodeoxyribonucleotides containing 1-deaza-2′-deoxyadenosine ( = 7-amino-3-(2-deoxy-β-D -erythro-pentofuranosyl)-3H-imidazo[4, 5-b]pyridine; 1b ) form Hoogsteen duplexes. Watson-Crick base pairs cannot be built up due to the absence of N(1). For these studies, oligonucleotide building blocks – the phosphonate 3a and the phosphoramidite 3b – were prepared from 1b via 4a and 5 , as well as the Fractosil-linked 6b , and used in solid-phase synthesis. The applicability of various N-protecting groups (see 4a – c ) was also studied. The Hoogsteen duplex d[(c¹A)₂₀] · d(T₂₀) ( 11 · 13 ; T_m 15°) is less stable than d(A₂₀) · d(T₂₀) ( 12 · 13 ; T_m 60°). The block oligomers d([c¹A)₁₀–;T₁₀] ( 14 ) and d[T₁₀–(c¹A)₁₀] ( 15 ) containing purine and pyrimidine bases in the same strand are also able to form duplexes with each other. The chain polarity was found to be parallel.     

N6-(Carbamoylmethyl)-2′-deoxyadenosine,a rare DNA Constituent: Phosphoramidite Synthesis and Properties of Palindromic Dodecanucleotides

N⁶-(Carbamoylmethyl)-2′-deoxyadenosine ( 1 ), a modified nucleoside occurring in bacteriophage Mu, was synthesized by two different routes. Glycinamide was introdued by nucleophilic displacement of(2,4,6,-triisopro-pylphenyl)sulfonyloxy or ethylsulfinyl groups at C(6) of the purine moiety. Compound 1 was converted into the protected phosphoramidite 6b and employed in solid-phase synthesis of the self-complementary oligonucleotides 7–14 . Replacement of 2′-deoxyadenosine by 1 led to a strong decrease of the T_m values of the oligomers d(A-T)₆ ( 7 ) and d(A-T-G-A-A-G-C-T-T-C-A-T)( 10 ), respectively. As the oligemer 10 contains the recognition site d(A-A-G-C-T-T) of the endodeoxyribonuclease Hind III, it was subjected to sequence-specific hydrolysis experiments. Replacement of the first or second A_d by 1 prevented enzymatic phosphodiester hydrolysis (results with 11 and 12 ). In contrast, slow hydrolysis was observed if the less bulky N⁶-methyl-2′-deoxyadenosine replaced the second A _d residue (results with 14 ).     

Synthesis,Base Pairing,and Structural Transitions of Oligodeoxyribonucleotides Containing 8-Aza-2′-deoxyguanosine

The synthesis of oligonucleotides containing 8-aza-2′-deoxyguanosine (z⁸G_d; 1 ) or its N⁸-regioisomer z⁸G_d^* ( 2 ) instead of 2′-deoxyguanosine (G_d) is described. For this purpose, the NH₂ group of 1 and 2 was protected with a (dimethylamino)methylidene residue (→ 5, 6 ), a 4,4′-dimethoxytrityl group was introduced at 5′-OH (→ 7, 8 ), and the phosphonates 3a and 4 as well as the phosphoramidite 3b were prepared. These building blocks were used in solid-phase oligonucleotide synthesis. The oligonucleotides were characterized by enzymatic hydrolysis and melting curves (T_m values). The thermodynamic data of the oligomers 12–15 indicate that duplexes were stabilized when 1 was replacing G_d. The aggregation of d(T-G-G-G-G-T) ( 18 ) was studied by RP 18 HPLC, gel electrophoresis and CD spectroscopy and compared with that of oligonucleotides containing an increasing number of z⁸G_d residues instead of G_d. Similarly to [d(C-G)]₃ ( 12a ), the hexamer d(C-z⁸G-C-z⁸G-C-G) ( 14 ) underwent salt-dependent B-Z transition.     

N7-DNA: Synthesis and Base Pairing of Oligonucleotides containing 7-(2-Deoxy-β -D-erythro-pentofuranosyl)adenine (N7Ad)

The synthesis of oligonucleotides containing 7-(2-deoxy-β -D -erythro-pentofuranosyl)adenine (N⁷A_d; 1 ) is described. Compound 1 was obtained from the precursor 4-amino-1H -imidazole-5-carbonitrile 2-deoxyribonucleoside 6 and was found to be much more labile than A_d. The N⁶-benzoyl protecting group (see 8 ) destabilized the N-glycosylic bond further and was difficult to remove by NH₃-catalyzed hydrolysis. Therefore, a (dimethyl-amino)methylidene residue was introduced (→ 9 ). Amidine 9 was blocked at OH? C(5′) with the dimethoxytrityl residue ((MeO)₂Tr), and phosphonate 4 as well as phosphoramidite 5 were prepared under standard conditions. Phosphonate 4 was employed in solid-phase oligonucleotide synthesis. Homooligonucleotides as well as self-complementary oligonucleotides were prepared. The oligomer d[(N⁷A)₁₁-A] ( 11 ) formed a duplex with d(T₁₂) ( 13 ). Antiparallel chain polarity and reverse Watson-Crick base pairing was deduced from duplex formation of the self-complementary d[(N⁷A)₈-T₈] ( 14 ).     

Duplex Stability of 7-Deazapurine DNA: Oligonucleotides containing 7-bromo- or 7-iodo-7-deazaguanine

The oligonucleotide building blocks, the phosphonates 1a, b and the phosphoramidites 2a, b derived from 7-iodo- and 7-bromo-7-deaza-2′-deoxyguanosines 3a, b were prepared. They were employed in solid-phase oligonucleotide synthesis of the alternating octamers d(Br⁷c⁷G-C)₄ ( 8 ) and d(I⁷c⁷G-C)₄ ( 9 ) as well as the homo-oligonucleotides d[(Br⁷c⁷G)₅-G] ( 11 ) and d[(I⁷c⁷G)₅-G] ( 12 ). The melting profiles and CD spectra of oligonucleotide duplexes were measured. The T_m values as well as the thermodynamic data were determined and correlated to the major-groove modification of this DNA. The self-complementary octamers 8 and 9 form more stable duplexes compared to the parent oligomer d(G-C)₄. The heteroduplex of d[(I⁷c⁷G)₅-G] ( 12 ) with d(C₆) is slightly destabilized (ΔT_m = ?12°) over that of d[(c⁷G)₅-G] with d(C₆). However, the complex of 12 with poly(C) is more stable than that of d[(c⁷G₅-G)] with poly(C).     

1-(2′-Deoxy-β-D-xylofuranosyl)thymine Building Blocks for Solid-Phase Synthesis and Properties of Oligo(2′-Deoxyxylonucleotides)

1-(2′-Deoxy-β-D -threo-pentofuranosyl)thymine (= 1-(2′-deoxy-β-D -xylofuranosyl)thymine; xT_d; 2 ) was converted into its phosphonate 3b as well as its 2-cyanoethyl phosphoramidite 3c . Both compounds were used for solid-phase synthesis of d[(xT)₁₂-T] ( 5 ), representing the first DNA fragment build up from 3′–5′-linked 2′-deoxy--β-D -xylonucleosides. Moreover, xT_d was introduced into the innermost part of the self-complementary dodecamer d(G-T-A-G-A-A-xT-xT-C-T-A-C)₂ (9). The CD spectrum of d[(xT)₁₂–T] ( 5 ) exhibits reversed Cotton effects compared to d(T₁₂) ( 6 ; see Fig. 1), implying a left-handed single strand. With d(A₁₂) ( 7 ) it could be hybridized to form a propably Left-handed double strand d(A₁₂) · d[(xT)₁₂–T] ( 7 · 5 ) which was confirmed by melting experiments in combination with temperature-dependent CD spectroscopy. While 5 was hydrolyzed by snake-venom phosphodiesterase, it was resistant towards calf-spleen phosphodiesterase. The modified, self-complementary duplex 9 was hydrolyzed completely by snake-venom phosphodiesterase, at a twelvefold slower rate compared to unmodified 8 ; calf-spleen phosphodiesterase hydrolyzed 9 only partially.     

1-(2′-Deoxy-β-D-xylofuranosyl)cytosine: Base pairing of oligonucleotides with a configurationally altered sugar-phosphate backbone

Solid-phase synthesis of the oligo(2′-deoxynucleotides) 19 and 20 containing 2′-deoxy-β-D -xylocytidine ( 4 ) is described. For this purpose, 1-(2-deoxy-β-D -threo-pentofuranosyl)cytosine ( = 1-(2-deoxy-β-D -xylofuranosyl)-cytosine; 4 ) was protected at its 4-NH₂ group with a benzoyl (→ 5 ) or an isobutyryl (→ 8 ) residue, and a dimethoxytrityl group was introduced at 5′-OH (→ 7, 10 ; Scheme 2). Compounds 7 and 10 were converted into the 3′-phosphonates 11a,b . While 19 could be hybridized with 21 and 22 under formation of duplexes with a two-nucleotide overhang on both termini ( 19 · 21 : T_m 29°; 19 · 22 : T_m 22°), the decamer 20 bearing four xC_d residues could no longer be hybridized with one of the opposite strands. Moreover, the oligonucleotides d[(xC)₈? C] ( 13 ), d[(xC)₄? C] ( 14 ), d[C? (xC)₄? C] ( 15 ), and d[C? (xC)₃? C] ( 16 ) were synthesized. While 13 exhibits an almost inverted CD spectrum compared to d(C₉) ( 17 ), the other oligonucleotides show CD spectra typical for regular right-handed single helices. At pH 5, d[(xC)₈? C] forms a stable hemi-protonated duplex which exhibits a T_m of 60° (d[(CH⁺)₉] · d(C₉): T_m 36°). The thermodynamic parameters of duplex formation of ( 13H ⁺ · 13 ) and ( 17H ⁺ · 17 ) were calculated from their melting profiles and were found to be identical in ΔH but differ in ΔS ( 13H ⁺ · 13 : ΔS = ?287 cal/K mol; 17H ⁺ · 17 : ΔS = ?172 cal/K mol).     

Nucleotides. Part. XXXII. Synthesis of 2′–5′ Connected oligonucleotides. Prodrugs for antiviral and antitumoral nucleosides

The cytotoxically and antivirally active compounds bvU_d ( 1 ), flU_d ( 4 ), acyclovir ( 7 ), and A_a ( 12 ) have chemically been combined with the appropriately protected (2′–5′)diadenylate 20 by the phosphotriester approach to give the 2′–5′ oligonucleotide trimers 21 – 24 . The deprotection of the various blocking groups by chemical means afforded the 2′–5′ trimers 25 – 28 , which can be regarded as new type of a potential prodrug form delivering nucleotides to the targets inside cells. In an analogous series of reactions, 9-(3′-azido-3′-deoxy-β-D-xylofuranosyl)adenine was coupled with 7 to the 2′–5′ trimer 31 . The antiviral screening of the oligonucleotides 25–27 and 31 showed biological activities closely related to the parent nucleosides, possibly indicating their release by enzymatic cleavage of the oligomers.     

9-(2′-Deoxy-β-D-xylofuranosyl)adenine Building Blocks for Solid-Phase Synthesis and Properties of Oligo(2′-deoxy-xylonucleotides)

The 9-(2′-deoxy-à-D -threo-pentofuranosyl)adenine (=9-(2′-deoxy-à-D -xylofuranosyl)adeninc, xA_d; 2) was protected at its 6-NH₂ group with cither a benzoyl ( 5a ) or a (dimethyfamino)methylidcnc ( 6a ) residue and with a dimethoxytntyl group at 5′-OH ( 5b, 6b ). Compounds 5b and 6b were then converted into the 3′-phosphonates 5c and 6c ; moreover, the 2-cyanoethyl phosphoramidite 6d was synthesized starting from fib. The DNA building blocks were used for solid-phase synthesis of d[(xA)₁₂2-A] ( 8 ). The latter was hybridized with d[(xT)12-T] (T_m = 35°); in contrast, with d(T₁₂), complex formation was not observed. Moreover, xAd and xTd were introduced into the self-complementary dodccamcr d(G-T-A-G-A-A-T-T-C-T-A-C) ( 12 ) at different positions lo give the oligomcrs 13 – 16 . All oligonucleotides were characterised by temperature-dependent CD and UV spectroscopy, and in addition, 14 by T-jump experiments. From concentration-dependent T_m measurements, the thermodynamic paraneters of the melting as well as the tendency of hairpin formation of the oligonucleotides were deduced. Oligemer 14 was hydrolyzed by snake-venom phosphodiesterase in a discontinuous way implying a fast hydrolysis of unmodified 3′- and 5′-flanks followed by a slow hydrolysis of the remaining modified tetramer. In contrast to this, oligonucleotide 16 was hydrolyzed in a continuous reaction. In both cases, calf-spleen phosphodiesterase hydrolyzed the oligomer only marginally.     

Aromatic vs. Carbohydrate Residues in the Major Groove: Synthesis of 5‐[(Benzyloxy)methyl]pyrimidine Nucleosides and Their Incorporation into Oligonucleotides

The synthesis of 5‐[(benzyloxy)methyl]‐substituted pyrimidine 2′‐deoxynucleosides 14 and 15 starting from the uracil derivative 6 and tetra‐O‐acetyl‐D ‐ribose is described (Schemes 1 – 3). These nucleosides were converted to the corresponding cyanoethyl phosphoramidites 18 and 19 , respectively, and incorporated into oligodeoxynucleotide decamers. The 5‐[(benzyloxy)methyl]‐nucleoside building blocks ^boT_d and ^bomC_d (bo=benzyloxy, bom=(benzyloxy)methyl) – shape analogs of the naturally occurring glucosylated nucleosides 1 and 2 (see Fig. 1) – lead to weaker binding affinities of oligodeoxynucleotides pairing to DNA as well as RNA complements. The modification is more destabilizing in the case of ^boT_d than ^bomC_d. Analysis of the thermodynamics of duplex formation shows that ^boT_d and ^bomC_d incorporation leads to a smaller entropy change in duplex formation that is, however, overcompensated by a less favorable enthalpy term. Molecular‐modeling studies suggest that the benzyl groups reside in the major groove which would explain the improved pairing entropy as a result of the exclusion of ordered H₂O.     

2′, 3′-Dideoxy-3′-fluorotubercidin and Related Dideoxyribonucleosides:. Synthesis via a 2′-deoxy-3′-oxoribofuranoside intermediate and conformation studies

An efficient synthesis of the unknown 2′-deoxy-D-threo-tubercidin ( 1b ) and 2′, 3′-dideoxy-3′-fluorotubercidin ( 2 ) as well as of the related nucleosides 9a, b and 10b is described. Reaction of 4-chloro-7-(2-deoxy-β-D-erythro-pentofuranosyl)-7H-pyrrolo[2,3-d]pyrimidine ( 5 ) with (tert-butyl)diphenylsilyl chloride yielded 6 which gave the 3′-keto nucleoside 7 upon oxidation at C(3′). Stereoselective NaBH₄ reduction (→ 8 ) followed by deprotection with Bu₄NF(→ 9a )and nucleophilic displacement at C(6) afforded 1b as well as 7-deaza-2′-deoxy-D-threo-inosine ( 9b ). Mesylation of 4-chloro-7-{2-deoxy-5-O-[(tert-butyl)diphenylsilyl]-β-D-threo-pentofuranosyl}-7H-pyrrolo[2,3-d]-pyrimidine ( 8 ), treatment with Bu₄NF (→ 12a ) and 4-halogene displacement gave 2′, 3′-didehydro-2′, 3′-dideoxy-tubercidin ( 3 ) as well as 2′, 3′-didehydro-2′, 3′-dideoxy-7-deazainosne ( 12c ). On the other hand, 2′, 3′-dideoxy-3′-fluorotubercidin ( 2 ) resulted from 8 by treatment with diethylamino sulfurtrifluoride (→ 10a ), subsequent 5′-de-protection with Bu₄NF (→ 10b ), and Cl/NH₂ displacement. ¹H-NOE difference spectroscopy in combination with force-field calculations on the sugar-modified tubercidin derivatives 1b , 2 , and 3 revealed a transition of the sugar puckering from the ^3′T_2′ conformation for 1b via a planar furanose ring for 3 to the usual ^2′T_3′ conformation for 2.     

Stereoselective synthesis of pyrrolo[2,3-d]pyrimidine α- and β-D-ribonucleosides from anomerically pure D-ribofuranosyl chlorides: Solid-Liquid Phase-Transfer Glycosylation and 15N-NMR Spectra

Solid-liquid phase-transfer glycosylation (KOH, tris[2-(2-methoxyethoxy)ethye]amine ( = TDA-1), MeCN) of pyrrolo[2,3-d]pyrimidines such as 3a and 3b with an equimolar amount of 5-O-[(1,1 -dimethylethyl)dimethylsilyl]-2,3-O-(1-methylethylidene)-α-D -ribofuranosyl chloride (1) [6] gave the protected β-D -nucleosides 4a and 4b , respectively, stereoselectively (Scheme). The β-D -anomer 2 [6] yielded the corresponding α-D -nucleosides 5a and 5b with traces of the β-D -compounds. The 6-substituted 7-deazapurine nucleosides 6a , 7a , and 8 were converted into tubercidin (10) or its α-D -anomer (11) . Spin-lattice relaxation measurements of anomeric ribonucleosides revealed that T₁ values of H? C(8) in the α-D -series are significantly increased compared to H? C(8) in the β-D -series while the opposite is true for T₁ of H? C(1′). ¹⁵N-NMR data of 6-substituted 7-deazapurine D -ribofuranosides were assigned and compared with those of 2′-deoxy compounds. Furthermore, it was shown that 7-deaza-2′deoxyadenosine ( = 2′-deoxytubercidin; 12 ) is protonated at N(1), whereas the protonation site of 7-deaza-2′-deoxyguanosine ( 20 ) is N(3).