Pteridines. Part XLII. Synthesis and properties of 8-substituted 2,4-dithiolumazines

Condensation reactions of the 5-amino-6-(subst. amino)-2,4-dithiouracils 12 and 13 with diacetyl or benzil led to the 6,7,8-trisubstituted 2,4-dithiolumazines 14 – 16 . Methylation of these compounds affected both thio functions forming various types of 2,4-bis(methylthio)lumazine derivatives depending on the nature of the substituents at C(7) and N(8). The 6,7,8-trimethyl-2,4-dithiolumazine ( 14 ) was converted into 7,8-dihydro-6,8-dimethyl–7-methylidene-2,4-bis(methylthio)pteridine ( 17 ), whereas the 8-methyl-6,7-diphenyl-(15) and the 8-(2-hydroxyethyl)-6,7-diphenyl-2,4-dithiolumazine ( 16 ) yielded the corresponding covalent inter- or intramolecular 7,8-adducts 18 – 21 . The unusual structures were proven by spectroscopic means and those of the alcohol adducts 20 and 21 , furthermore, confirmed by X-ray analysis.     

Pteridines. Part XLI. Synthesis and properties of 6,7,8-trimethyl-4-thiolumazine

The first representative of the 8-substituted 4-thiolumazine series has been synthesized. In a sequence of reactions, 4,6-dichloropyrimidin-2-(1H)-one ( 1 ) is first converted into 4-chloro-6-(methylamino)pyrimidin-2(1H)-one ( 6 ), then the Cl-atom displaced by the thioxo group (→7) followed by a coupling reaction with 4-chlorophenyldiazonium chloride to introduce the necessary N-function into the 5-position (→ 9 ; Scheme 1). Reduction of the p-chlorophenylazo group leads to the 6-(methlyamino)-4-thiouracil-5-amine ( 10 ) which on condensation with diacetyl gives 6,7,8-trimethyl-4-thiolumazine ( 8 ). The physical properties of 8 are compared with the 2-thio analog and 6,7,8-trimethyllumazine indicating that 8 possesses the highest acidity and the longest UV absorption.     

Pteridines,LXXXIV. Synthesis,reactivity and properties of 1,3-dimethyllumazine-6- and 7-carboxaldehyde derivatives

Convenient syntheses of 1,3-dimethyllumazine-6- (7) and -7-carboxaldehyde ( 19 ) are described. The reactivity of the carboxaldehyde group has been investigated by oxidations, reductions and various carbonyl reactions forming a series of new derivatives. The newly synthesized compounds were characterized by elemental analysis, uv and ¹H-nmr spectra.     

Pteridines. Part CXVII

A series of side chain reactions starting from the 6‐ and 7‐styryl‐substituted 1,3‐dimethyllumazines 1 and 21 as well as from the 6‐ and 7‐[2‐(methoxycarbonyl)ethenyl]‐substituted 1,3‐dimethyllumazine 2 and 22 were performed first by addition of Br₂ to the C?C bond forming the 1′,2′‐dibromo derivatives 3, 4, 24 , and 26 in high yields (Schemes 1 and 3) (lumazine=pteridine‐2,4(1H,3H)‐dione). Treatment of 3 with various nucleophiles gave rise to an unexpected tele‐substitution in 7‐position and elimination of the Br‐atoms generating 7‐alkoxy‐ (see 5 and 6 ), 7‐hydroxy‐ (see 7 ) and 7‐amino‐6‐styryl‐1,3‐dimethyllumazines (see 8 – 11 ) (Scheme 1). On the other hand, 4 underwent, with dilute DBU (1,8‐diazabicyclo[5.4.0]undec‐2‐ene), a normal HBr elimination in the side chain leading to 18 , whereas treatment with MeONa afforded a more severe structural change to 19 . Similarly, 24 and 26 reacted to 27, 32 , and 33 under mild conditions, whereas in boiling NaOMe/MeOH, 24 gave 7‐(2‐dimethoxy‐2‐phenylethyl)‐1,3‐dimethyllumazine ( 30 ) which was hydrolyzed to give 31 (Scheme 3). From the reactions of 4 and 24 with DBU resulted the dark violet substance 20 and 25 , respectively, in which DBU was added to the side chain (Scheme 2). The styryl derivatives 1 and 21 could be converted, by a Sharpless dihydroxylation reaction, into the corresponding stereoisomeric 6‐ and 7‐(1,2‐dihydroxy‐2‐phenylethyl)‐1,3‐dimethyllumazines 34 – 37 (Scheme 4). The dihydroxy compounds 34 and 35 were also acetylated to 38 and 39 which, on catalytic reduction followed by formylation, yielded the diastereoisomer mixtures 40 and 41 . Deacetylation to 42 and 45 allowed the chromatographic separation of the diastereoisomers resulting in the isolation of 43 and 44 as well as 46 and 47 , respectively. Introduction of a 6‐ or 7‐ethynyl side chains proceeded well by a Sonogashira reaction with 6‐ ( 48 ) or 7‐chloro‐1,3‐dimethyllumazine ( 55 ) yielding 49 – 51 and 56 – 58 (Scheme 5). The direction of H₂O addition to the triple bond is depending on the substituents since the 6‐ ( 49 ) and 7‐(phenylethynyl)‐1,3‐dimethyllumazine ( 56 ) showed attack at the 2′‐position yielding 53 and 60 , in contrast to the 6‐ ( 51 ) and 7‐ethynyl‐1,3‐dimethyllumazine ( 58 ) favoring attack at C(1′) and formation of 6‐ ( 52 ) and 7‐acetyl‐1,3‐dimethyllumazine ( 59 ).     

Pteridines. Part CXVIII

Our approach to achieve a partial synthesis of methanopterin ( 1 ) started from 6‐acetyl‐O⁴‐isopropyl‐7‐methylpterin ( 20 ) which was obtained either by condensation from 6‐isopropoxypyrimidine‐2,4,5‐triamine ( 19 ) and pentane‐2,3,4‐trione ( 6 ) or from 6‐isopropoxy‐5‐nitrosopyrimidine‐2,4‐diamine ( 21 ) and pentane‐2,4‐dione (=acetylacetone; 22 ) (Scheme 2). NaBH₄ reduction of 20 led to 6‐(1‐hydroxyethyl)‐O⁴‐isopropyl‐7‐methylpterin ( 23 ) which was converted into the corresponding 6‐(1‐chloroethyl) and 6‐(1‐bromoethyl) derivatives 24 and 25 . A series of nucleophilic displacement reactions in the side chain and at position 4 were performed as model reactions to give 26 – 29, 32 – 35 , and 39 – 41 . Hydrolysis of the substituents at C(4) led to the corresponding pterin derivatives 30, 31, 36 – 38 , and 42 . Analogously, 25 reacted with 1‐(4‐aminophenyl)‐1‐deoxy‐2,3: 4,5‐di‐O‐isopropylidene‐D ‐ribitol ( 43 ), prepared from N‐(4‐bromophenyl)benzamide ( 47 ) via 49 and 50 to give 1‐{4‐{{1‐[2‐amino‐7‐methyl‐4‐(1‐methylethoxy)pteridin‐6‐yl]ethyl}amino}phenyl}‐1‐deoxy‐D ‐ribitol ( 44 ) in 62% yield (Scheme 3). Acid cleavage of the isopropylidene groups at room temperature led to 45 and on boiling to 1‐{4‐{[1‐(2‐amino‐3,4‐dihydro‐7‐methyl‐4‐oxopteridin‐6‐yl)ethyl]amino}phenyl}‐1‐deoxy‐D ‐ribitol ( 46 ). The next step, however, attachment of the ribofuranosyl moiety with 55 or 56 to the terminal 1‐deoxy‐D ‐ribitol OH group could not been achieved. The second component, bis(4‐nitrobenzyl) 2‐{[(2‐cyanoethoxy)(diisopropylamino)phosphino]oxy}pentanedioate ( 61 ), to built‐up methanopterin ( 1 ) was synthesized from 2‐hydroxypentanedioic acid ( 59 ) and worked well in another model reaction on phosphitylation with N⁶‐benzoyl‐2′,3′‐O‐isopropylideneadenosine and oxidation to give 62 (Scheme 6).     

Pteridines. Part CXIX.

A variety of pyrimidine precursors 12 – 25 were converted into a series of new 7‐hydroxylumazines (=7‐hydroxypteridine‐2,4(1H,3H)‐diones) 26 – 35 which functioned as starting materials for the transformation into the corresponding 7‐chlorolumazines 36 – 45 . Subsequent reaction with hydrazine led to the 7‐hydrazinolumazines 46 – 55 which gave on nitrosation the 7‐azidolumazines 1 and 56 – 64 . These compounds were subjected to short heating in xylene whereby 1 and 56 – 61 showed a new pteridine–purine interconversion in forming a new type of 1,3‐disubstituted or 3‐substituted xanthin‐8‐amine‐derived nitrilium ylides (2,3,6,7‐tetrahydro‐N‐methylidyne‐2,6‐dioxo‐1H‐purin‐8‐aminium ylides) 11 and 65 – 70 . The presence of an additional 6‐alkyl substituent in the 7‐azidolumazines 63 and 64 or of an unsubstituted N(3) position in 62 caused further rearrangement to xanthine‐9‐carbonitriles 71 – 73 . Prolonged heating of 7‐azido‐1,3‐dimethyllumazine ( 1 ) also afforded theophylline‐9‐carbonitrile (=1,2,3,6‐tetrahydro‐1,3‐dimethyl‐2,6‐dioxo‐9H‐purine‐9‐carbonitrile; 5 ). The nitrilium ylide function was established by NMR and UV spectra as well as by elemental analyses. Confirmation of the nitrilium ylide structures was suggested by the result of the heating of 1,3‐dimethyl‐N‐methylidynexanthin‐8‐aminium ylide 11 in EtOH or of 1 in pentan‐1‐ol leading to 8‐aminotheophylline (=8‐amino‐3,7‐dihydro‐1,3‐dimethyl‐1H‐purin‐2,6‐dione; 74 ).     

Pteridines. Part LXXXVII. Synthesis and Properties of 8-Substituted 2-Thiolumazines

Various 8-substituted 2,8-dihydro-2-thioxopteridin-4(3H)-ones ( 14 – 21 ) and 2-(methylthio)pteridin-4(8H)-ones ( 27 – 32 ) have been synthesized by condensation of the appropriate 5-amino-6-(substituted amino)-1,2-dihydro-2-thioxopyrimidin-4(3H)-ones ( 22 – 34 ) and 5-amino-6-(substituted amino)-2-(methylthio)pyrimidin-4(3H)-ones ( 25 , 26 ), respectively, with glyoxal, biacetyl, and benzil. The presence of a quinonoid cross-conjugated π-electron system makes this type of compounds susceptible to nucleophilic additions in position 7, which leads to intramolecular ( 43 , 45 ) and intermolecular ( 44 ) covalent adducts. The newly synthesized compounds have been characterized by elemental analyses, pK_a determinations, ¹H-NMR and UV spectra. UV-Spectral changes in dependence of the pH are associated with the most appropriate molecular species including the monocations, neutral forms, covalent adducts, mono- and dianions.     

Pteridines. 52. A Convenient Synthesis of 6-Formylpterin1

6-Formylpterin has been prepared by a new and highly efficient procedure involving palladium-catalyzed coupling of 2-pivaloyl-6-chloropterin with styrene, followed by ozonolysis of the resulting 6-styryl derivative and acid hydrolysis of the 2-pivaloyl gorup.     

Pteridines. Part LXXXV. Chemical synthesis of deoxysepiapterin and 6-acylpteridines by acyl radical substitution reactions

A new synthesis of deoxysepiapterin ( 2 ), one of the two yellow eye pigments of the Drosophila mutant sepia, is described. The synthetic approach makes use of a homolytic nucleophilic acylation of 7-(alkylthio)pteridine derivatives ( 11, 13, 15, 18, 20 ) leading to the corresponding 6-acyl derivatives ( 21–27 ). Desulfurizations have been achieved for the first time in the pteridine series using Raney-Co,Raney-Cu, or Cu? Al alloy in alkaline medium. Besides cleavage of the C(7)? S bond, further reductions of the C?O group at C(6) and the C(7)?N(8) bond are detected as side reactions leading to 6-(1-hydroxyalkyl) ( 34, 35, 42, 43 ) and 6-acyl-7,8-dihydro derivatives ( 2, 36, 37 ), respectively, The newly synthesized compounds have been characterized by elemental analysis, p_K determination, UV and ¹H-NMR spectra.     

Pteridines. Part C. Structure and nonenzymatic synthesis of aurodrosopterin

The nonenzymatic synthesis of aurodrosopterin ( 5 ) from 6-acetyl-2-amino-3, 7, 8, 9-tetrahydro-4H-pyrimido-[4,5-b][1,4]diazepin-4-one ( 3 ) and 7,8-dihydrolumazine ( 4 ) at pH 3 (HCl) was performed. The identity of the synthesized compound with the natural eye pigment isolated from drosophila heads was confirmed by thin-layer chromatography on cellulose and by comparisons of the ¹H-NMR and UV/VIS spectra. The nonenzymatic synthesis of a neodrosopterin-like red pigment from 3 and 2,4-diamino-7,8-dihydropteridine was also carried out, but its identity could not be established. This pigment, called aminodrosopterin, has an absorption peak at 489 nm, which is very close to that of neodrosopterin.     

A New Synthesis of Pteridines

A new synthesis of pteridines possessing a (substituted) (Z)‐3‐hydroxyprop‐1‐enyl group at C(6) is based on the acylation of 4‐amino‐5‐nitrosopyrimidines with dienoic acid chlorides, followed by a high‐yielding intramolecular hetero‐Diels–Alder cycloaddition and cleavage of the N? O bond leading to 4 . Thermolysis of the resulting pteridines 4 possessing a benzyloxy group at C(4) led to the products 5 , resulting from isomerisation of the 3‐hydroxyprop‐1‐enyl to an 3‐oxopropyl side chain, while the analogous pteridine 8 possessing an NH₂ group at C(4) remained unaffected.     

252. Synthesis and reactions of droso- and isodrosopterin. Pteridines. LIV

The synthesis of the Drosophila pigments droso- and isodrosopterin ( 7 ) from 7.8-dihydropterin ( 3 ) and 2-hydroxy-3-oxobutyric acid ( 4 ) is described. A reaction mechanism is discussed and proven by isotope experiments. Droso- and isodrosopterin form in weak acidic medium in the presence of NH ions two red reaction products each one of which seems to be identical with neodrosopterin.     

Synthesis of 6S, 7S-anhydro-serricornine.

Diastereoselective and enantioselective reduction of the β-ketoester $\text{3}$ by yeast to $\text{4}$ provided the chiral starting material for a synthesis of 4RS,6S,7S-serricornine, having the same configuration as the natural product. This material was converted into optically active and diastereomerically pure 6S,7S-anhydro-serricornine ($\text{2}$).     

Synthesis of 7-methyl-6-indolopterin and 7-methyl-6-indoloquinoxaline

The first syntheses of indolopterin and indoloquinoxaline, two important and dissimilar diheterocycles linking C-2 of indole with C-6 of pterin (significant positions for showing biological activity), and quinoxaline, respectively, have been achieved based on two classical reactions. The introduction of a keto methyl group on to the 6-position of pterin and quinoxaline followed by Fischer indole synthesis led to these target diheterocycles. These indole-substituted diheterocycles will significantly increase the electron density on the pterin-5-N and quinoxazoline-2-N, which may change the redox properties of pterin and quinoxaline, and also the electron-withdrawing pterin or quinoxazoline should make the indole NH more acidic.     

Diazocarbonyl derivatives of heterocycles. 7. Synthesis,properties, and structure of 2,4-diazido-6-diazoacetylpyrimidine

The reaction of 2,4-dichloro-6-diazoacetylpyrimidine with sodium azide to give 2,4-diazido-6-diazoacetylpyrimidine has been examined, and the crystal structure of the latter, and its 1,3-dipolar cycloadditions at the carbonyl group, studied.For Communication 6, see [1].Translated from Khimiya Geterotsiklicheskikh Soedinenii, No. 4, pp. 515–519, April, 1990.     

Glycosylidene Carbenes. Part 6. Synthesis of alkyl and fluoroalkyl glycosides

The syntheses of glycosides from the diazirine 1 and a range of alcohols under thermal and/or photolytic conditions are described. Yields and diastereoselectivities depend upon the pK_HA values of the alcohols, the solvent, and the reaction temperature. The glycosidation of weakly acidic alcohols (MeOH, EtOH, i-PrOH, and t-BuOH, 1 equiv. each) in CH₂Cl₂ at room temperature leads to the glycosides 2–5 in yields between 60 and 34% (Scheme 1 and Table 1). At ?70 to ?60°, yields are markedly higher. In CH₂Cl₂, diastereoselectivities are very low. In THF, at ?70 to ?60°, however, glycosidation of i-PrOH leads to α-D -/β-D - 4 in a ratio of 8:92. More strongly acidic alcohols, such as CF₃CH₂OH, (CF₃)₂ CHOH, and (CF₃)₂C(Me)OH, and the highly fluorinated long-chain alcohols CF₃(CF₂)₅(CH₂)₂OH ( 11 ) and CHF₂(CF₂)₉CH₂OH ( 13 ) react (CH₂Cl₂, r.t.) in yields between 73 and 85% and lead mainly to the β-D -glucosides β-D - 6 to β-D - 8 , β-D - 12 , and β-D - 14 (d.e. 14–68%). Yields and diastereoselectivities are markedly improved, when toluene, dioxane, 1,2-dimetoxyethane, or THF are used, as examined for the glycosidation of (CF₃)₂C(Me)OH, yielding (1,2-dimethoxyethane, 25°) 80% of α-D -/ β-D - 8 in a ratio of 2:98 (d.e. 96%; Table 4). In EtCN, (CF₃)₂C(Me)OH yields up to 55% of the imidate 10 . Glycosidation of di-O-isopropylideneglucose 15 leads to 16 (CH₂Cl₂, r.t.; 65%, α-D / β-D = 33:67). That glycosidation occurs by initial protonation of the intermediate glycosylidene carbene is evidenced, for strongly acidic alcohols, by the formation of 10 , derived from the attack of (CF₃)₂MeCO^? on an intermediate nitrilium ion (Scheme 4), and for weakly acidic alcohols, by the formation of α-D - 9 and β-D - 9 , derived by attack of i-PrO^? on intermediate tetrahydrofuranylium ions. A working hypothesis is presented (Scheme 3). The diastereoselectivities are rationalized on the basis of a protonation in the σ plane of the intermediate carbene, the stabilization of the thereby generated ion pair by interaction with the BnO? C(2) group, with the solvent, and/or with the alcohol, and the final nucleophilic attack by RO^? in the π plane of the (solvated) oxonium ion.     

Microbial metabolism. Part 6. Metabolites of 3- and 7-hydroxyflavones

Fermentation of 3-hydroxyflavone (1) with Beauveria bassiana (ATCC 13144) yielded 3,4'-dihdroxyflavone (3), flavone 3-O-beta-D-4-O-methylglucopyranoside (4) and two minor metabolites. 7-Hydroxyflavone (2) was transformed by Nocardia species (NRRL 5646) to 7-methoxyflavone (5) whilst Aspergillus alliaceus (ATCC 10060) converted it to 4',7-dihydroxyflavone (6). Flavone 7-O-beta-D-4-O-metylglucopyranoside (7) and 4'-hydroxyflavone 7-O-beta-D-4-O-methylglucopyranoside (8) were the metabolic products of 7-hydroxyflavone (2) when fermented with Beauveria bassiana (ATCC 7159). One of the minor metabolites of 3-hydroxyflavone (1) was tentatively assigned a beta'-chalcanol structure (9). Compounds 4, 7 and 8 are reported as new compounds. Structure elucidation of the metabolites was based on spectroscopic data.