Glycosylidene Carbenes. Part 20. Synthesis of deprotected,spiro-linked C-glycosides of C60

Mannosylidenation of buckminsterfullerene (C₆₀; 1 ) with the 2,3-di-O-benzyl-4,6-O-benzylidene-protected diazirine 7 and the 2,3:4,6-di-O-isopropylidene-protected diazirine 8 leads to the spiro-linked C -glycosides 6 and 10 in 44 and 31% yield, respectively (Scheme). The diazirine 8 was prepared in five steps from 2,3:4,6-di-O-iso-propylidene-α-D -mannopyranose ( 11 ) via the oximes 12 , the (Z)-hydroximolactone 13 , the mesylate 14 , and the diaziridines 15 . Deprotection of the mannosylidenated fullerenes 6 and 10 under acidic conditions gave the partially deprotected diol 9 (97%) and the unprotected mannosylidenated fullerene 16 (73%), respectively. The mannosylidene-fullerenes 6, 9, 10 , and 16 possess a 6–6 ring-bridged σ-homoaromatic structure.     

Photochemische Reaktionen. 87. Mitteilung. Zur Photolyse von 9-Oxabicyclo[3.3.1]nonan-2-on

Photolysis of Bicyclo[3.3.1]nonan-2-one. Disproportionations, the secondary processes available to the acyl-alkyl biradical b (X(9) = 0) formed from 9-oxabicyclo[3.3.1]-nonan-2-ones a (X(9) = 0) in a primary photochemical process by α-cleavage (Norrish type I cleavage) were studied. Special attention was paid to the selectivity between the two possible H-abstractions: the one at C(3) (→ ketene c , X(9)= 0) and the other one at C(8) (→ alkenal d , X(9) = 0) and to the selectivity of the H-abstraction at a definite methylene group (C(3) or C(8)). In the case of ketene formation (→ c , X(9) = 0) the specificity of the insertion of the migrating H-atom at C(1) was studied. endo-6-Hydroxy-9-oxabicyclo[3.3.1]nonan-2-one ( 6 ) and derivatives of it ( 7, 8, 16, 17, 19, 21, 30 and 38 ) as well as exo-6-hydroxy-9-oxabicyclo[3.3.1]-nonan-2-one ( 41 ) and its derivative 42 were used as substrates. UV.-irradiation of 6 in benzene yielded 1,5-dioxa-2-cis-decalone ( 44 ) by way of a ketene g (R = H) as demonstrated by the photolysis of 7 (→ 45 ), 8 (→ 43 ), and 17 (→ 47 ). Specific labellings with deuterium proved that H-abstraction occurs intramolecularly at C(3) (e.g. 16 → 54 ; 6 + 16 → 44 + 54 ), that one of the H-atoms at C(3) migrates specifically to C(1) ( 21 → 55 ; 19 → 56 ), endo-H–C(3) being favored by a factor of 6. The abstraction showed an unexpected primary isotope effect of about 2. UV-irradiation of 41 in benzene yielded in addition to the expected 1,5-dioxa-2-trans-clecalone ( 63 ) about 3% of an isomeric compound 67 which probably results from H-abstraction at C(8) (→ alkenal 65) followed by cyclisation.     

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.     

Glycosylidene Carbenes. Part 3. Synthesis of Spirocyclopropanes

Thermolysis of the glycosylidene-derived O-benzylated diazirine 1 in the presence of N-phenylmaleimide ( 2 ), acrylonitrile ( 3 ), dimethyl fumarate ( 4 ), or dimethyl maleate ( 5 ) led in good yields to mixtures of the spirocyclopropanes 6 / 7 , 8 – 11 , 12 / 13 , and 12 / 13 / 16 / 17 . The diastereoselectivity depends upon the alkene. The cycloaddition of 1 to 5 is not diastereospecific, in keeping with previous results. Deprotection of 12 , 13 , 16 , and 17 yielded the tetrols 14 , 15 , 18 , and 19 , respectively.     

Monomers for adhesive polymers. XV. Synthesis,photopolymerization, and adhesive properties of polymerizable β‐ketophosphonic acids

The novel polymerizable β‐ketophosphonic acids 4 , 8 , 10 , and 16 as well as the 9‐(methacryloyloxy)‐nonylphosphonic acid 20 were synthesized in four to eight steps. They were characterized by ¹H NMR, ¹³C NMR, and ³¹P NMR spectroscopy and by high‐resolution mass spectra. The free‐radical polymerization of 4 , 8 , 10 , and 16 was carried out in a water/ethanol solution, using 2,2′‐azo(2‐methylpropionamidine)dihydrochloride as initiator. To evaluate the reactivity of the acidic monomers 4 , 8 , 10 , 16 , and 20 , their photopolymerization behavior was investigated by photodifferential scanning calorimeter. Copolymerizations with 2‐hydroxyethyl methacrylate, glycol dimethacrylate, and N,N′‐diethyl‐1,3‐bis‐(acrylamido)propane were studied. The homopolymerization of the corresponding β‐ketophosphonates and their copolymerization with hydroxyethyl methacrylate were also carried out. Self‐etch adhesives based on the β‐ketophosphonic acids 4 , 8 , 10 , and 16 were able to provide high shear bond strengths (SBSs) of dimethacrylate‐based composite to dentin and enamel. The β‐ketophosphonic acid 8 was also shown to exhibit significantly better adhesive properties than the corresponding phosphonic acid 20 . Indeed, the presence of the carbonyl moiety in the β‐position of the phosphonic acid group led to a strong improvement of the composite SBS to dentin and enamel. © 2014 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2014 , 52, 3550–3563     

Purines. Part XVI

A series of N‐substituted 8‐aminoxanthines (=8‐amino‐3,7(or 3,9)‐dihydro‐1H‐purine‐2,6‐diones) 8 – 16 and 34 – 37 were synthesized from the corresponding 8‐nitroxanthines 1 – 7, 30 – 33 , and 8‐(phenylazo)xanthines 17 and 18 by catalytic reduction. Another approach was derived from 6‐amino‐5‐(cyanoamino)uracils (=N‐(6‐amino‐1,2,3,4‐tetrahydro‐2,4‐dioxopyrimidin‐5‐yl)cyanamides) 23, 24 , and 27 by base‐catalyzed cyclization yielding 25 – 28 . All 8‐aminoxanthines 8 – 29 and 34 – 37 were acetylated to the corresponding 8‐(acetylamino)xanthines 40 – 57 , and prolonged heating led to 8‐(diacetylamino)xanthines 58 and 59 . Several 8‐aminoxanthines 8 – 13 were diazotized forming 8‐diazoxanthines 60 – 64 . Coupling reactions of isolated 62 and 64 and intermediary formed 8‐diazoxanthines with 1,3‐dimethylbarbituric acid (=1,3‐dimethylpyrimidine‐2,4,6(1H,3H,5H)‐trione; 66 ) resulted in 5‐[(xanthin‐8‐yl)diazenyl]‐1,3‐dimethylbarbituric acids=3,7(or 3,9)‐dihydro‐8‐[2‐(1,2,3,4‐tetrahydro‐1,3‐dimethyl‐2,4‐dioxopyrimidin‐5‐yl)diazenyl]‐1H‐purine‐2,6‐diones) 67 – 80 . The newly synthesized xanthine derivatives were characterized by the determination of their pK_a values, the UV‐ and NMR spectra, as well as elemental analyses.     

Approaches to the synthesis of cytochalasans. Part 7. Synthesis of some building blocks for the construction of the macrocyclic moiety

The synthesis of ethyl (2E, 4E, 8R)-8-methyl-10-[(2H-tetrahydropyran-2-yl)oxy]-2,4-decadienoate ( 11 ), methyl (2E, 8R)-8-methyl-10-[(2H-tetrahydropyran-2-yl)oxy]-2-decenoate ( 16 ), synthons for the construction of the macrocyclic moieties of the cytochalasins A, B and F, and of (3R)-[7-(1,3-dioxolan-2-yl)-3-methylheptyl]triphenyl-phosphonium bromide ( 24 ), a C₈-building block for deoxaphomin, proxiphomin and protophomin is described. In all instances (+)-(R)-pulegone ( 5 ) served as starting material.     

Anti- and syn-Tricyclo [4.2.1.12,5]decane. Preliminary communication

The two novel tricyclic C₁₀H₁₆ compounds anti- and syn-tricyclo [4.2.1.1^2,5]- decane ( 16 and 17 , respectively) were synthesized starting either from the photodimer 2 (anti) or the two cycloaddition products 8 (anti) and 9 (syn).     

Hydrogenation of the ansa-Chain of Rifamycins. X-ray crystal structure of (16S)-16,17,18,19-tetrahydrorifamycin S

The catalytic hydrogenation of rifamycin S ( 2 ) over Pd/C, followed by oxidation with K₃[Fe(CN)₆], generates a pair of 16,17,18,19-tetrahydrorifamycins S ( 3/4 ), epimeric at C (16). The use of PtO₂ as catalyst leads to the hydrogenation also of the C(28)?C(29) bond giving, after oxidation by K₃[Fe(CN)₆], a mixture of the epimers (16R)- and (16S)-16,17,18,19,28,29-hexahydrorifamycins S ( 5/6 ). Furthermore, we synthesized the (16R)- and (16S)-3-bromo derivatives 7/8 and (16R)- and (16S)-3-(piperidin-1-yl) derivatives 9/10 . The determination of the X-ray crystal structure of the most abundant epimer 4 of the tetrahydrorifamycins allowed the assignment of the absolute configuration at C(16) of all derivative. A Structure-activity relationship study showed that in general the (16R)-epimers are more potent inhibitors of bacterial RNA polymerase than the (16S)-epimers.     

Alkaloid studies. VI. lithium aluminum hydride reduction of apoyohimbine and the synthesis of 3,4,5,6-tetradehydroyohimbane-16-methanols

Catalytic reduction of apoyohimbine ( 1 ), prepared from yohimbine and thionyl chloride in pyridine, gives methyl yohimbane-16α-carboxylate ( 2 ) after equilibration with methoxide. LAH reduction of 2 or β-yohimbine O-tosylate ( 3 ) gives yohimbane-16α-methanol ( 4a ). LAH reduction of 1 affords yohimbane-16α-carboxaldehyde ( 5 ), yohimb-16-ene-16-methanol ( 6a ) and yohimbane-16β-methanol ( 7a ). Structural assignments 6a and 7a are confirmed by mass spectral measurements. Pmr spectra of 4a, 6a and 7a and their O-acetates 4b, 6b and 7b are discussed. LAH reduction of apo-α-yohimbine ( 8 ) affords alloyohimb-16-ene-16-methanol ( 9 ). Dehydrogenation of 4a with palladium black and maleic acid gives 3,5,4,5,6-tetradehydroyohimbane-16α-methanol ( 10 ) iodide, and 7a gives 3,4,5,6-tetradehydroyohimbane-16β-methanol ( 11 ) iodide and picrate. Properties of 10 and 11 differ from those of melinonine E.     

The effects of hydrophobic-lipophilic interactions on chemical reactivity: 2. Solvent effects on the aggregation and self-coiling of long-chain molecules

The kinetics of the hydrolysis of p-nitrophenyl esters of straight chain carboxylic acids with various chain lengths, viz., acetate (C 2), octanoate (C 8) dodecanoate (C 12) and hexadecanoate (C 16) was investigated in ten aquiorgano binary solvent systems. In the Φ = 0.50 (50% v/v) solvent mixtures, aggregation and coiling-up of C 16 occur only in HOCH₂CH₂OH-H₂O and Me₂SOH₂O, in which kC₈/kC₁₆ >> 1, whereas the hydrolytic behaviors of C 16 and C 8 are similar in all other solvents. But at Φ =0.30, C 16 aggregates and coils-up in all solvent mixtures except the t-BuOH-H₂O system. If the kC₈/kC₁₆ values in the Φ =0.30 media are taken as an arbitrary standard, the order of decreasing hydrophobic-lipophilic interactions between the solvent and substrate molecules for the various solvents are as follows : HOCH₂CH₂OH > Me₂SO > CH₃OCH₂CH₂OH > DMF ? CH₂OCH₂CH₂OCH₃ > dioxane > ethanol ? acetone ? acetonitrile > t-BuOH. When kC₈/kC₁₆ >> 1, there is a large difference in the activation parameters between C 16 and its shorter counterparts. No simple correlation can be found between log (kC₈/kC₁₆) and various solvent polarity parameters, but log (kC₈/kC₁₆) correlates with Rekker's hydrophobic fragmental constants (f) of the organic components of these solvent systems (r = 0.976), indicating that the major factor which controls the hydrolysis of long-chain esters here is the hydrophobic-lipophilic interactions. Apparently, this is the first example of an application of Rekker's f constants to a correlation between solvent property and chemical reactivity in terms of rate constants.     

Oligonucleotide Analogues with Integrated Bases and Backbone. Part 32

The G[s ]G dinucleoside 6 and the G[s ]G* dinucleoside 8 were prepared by alkylation of the guanosine thiols derived from 2 and 5 , respectively, by the C(8)‐chloromethylated guanosine 4 that was obtained from alcohol 3 . Dinucleosides 6 and 8 were deacylated to 7 and 9 , and fully deprotected to 10 and 11 , respectively. The G[n ]G dinucleoside 16 was obtained by reductive amination of aldehyde 13 with an iminophosphorane derived from azide 14 and deprotection of the resulting dimer 15 . In the solid state of 6 , and in a solution of 6 and 8 in CDCl₃, H? N(1/I) and H? N(1/II) are engaged in intramolecular H‐bonds to the C?O of the isobutyryl protecting groups, and HN of the isobutyryl group of unit I forms an interresidue, intramolecular H‐bond to N(7/II), leading to a syn orientation of the nucleobase at unit I, to a tg orientation of the sulfanyl moiety, and to an orthogonal orientation of the nucleobases, preventing any base pairing. The silylated and isopropylidenated dinucleosides 7 and 9 are present in DMSO solution as solvated monoplexes. Broad ¹H‐NMR signals of the nucleosides 7 and 16 in CHCl₃ solution evidence equilibrating G‐quadruplexes. The quadruplex formation of 7 and 16 was established by ¹H‐NMR spectroscopy (only of 16 ), vapour pressure osmometry, mass spectrometry, and CD spectroscopy. The C(6(I))‐hydroxymethylated analogue 9 in CDCl₃ and the fully deprotected dinucleosides 10 and 11 in H₂O form only weakly π? π stacked associates, but no G‐quadruplexes, as evidenced by CD spectroscopy.     

Leiopathic Acid,a Novel Optically Active Hydroxydocosapentaenoic Acid,and related compounds,from the black coral Leiopathes sp. of Saint Paul Island (S. Indian Ocean)

The antipatharian Leiopathes sp., collected around Saint Paul Island, is shown here to contain, in relatively high amounts, the novel fatty acid leiopathic acid ( = (+)-(10R,7Z,11E,13Z,16Z,19Z)-10-hydroxy-7,11,13,16,19-docosapentaenoic acid; (+)- 1 ), besides (+)-(8R,5Z,9E,11Z,14Z,17Z)-8-hydroxy-5,9,11,14,17-icosapentaenoic acid ((+)- 11 ) and (+)-(8R,5Z,9E,11Z,14Z,)-8-hydroxy-05,9,11,14-icosatetraenoic acid ((+)- 16 ) and their ethyl ester (+)- 2 , (+)- 12 , and (+)- 17 .     

Chiral 1,4-benzodiazepines. XII. Conformation in a solution of 7-chloro-5-phenyl-3(S)methyl-1,3-dihydro-2H-1,4-benzodiazepine

Deuterium labeled congeners of 7-chloro-5-phenyl-3(S)-methyl-1,3-dihydro-2H-1,4-benzodiazepine ( 8 ), i.e., compounds 9 and 16-18 were prepared and their lis-nmr spectra run. For computational studies compounds 9 and 16 were chosen. The results of lis measurements revealed that 16 is present in more than 97% in the boat-like conformation I (Scheme 3).     

A New Type of Deaggregators, the Bolaamphiphilic DeAgrs. Observations of the Dependence of Deaggregating Ability on Aggregator Concentration and Solvent Aggregating Power

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Synthesis of the Oviposition-Deterring Pheromone (ODP) in Rhagoletis cerasi L. Preliminary communication

For the assignment of the configuration at C(8) and C(15) of the natural oviposition-deterring pheromone 1 in Rhagoletis cerasi L., the four possible stereoisomers of 1 are synthesized. By condensing the C₆ building blocks (5R)- 4 and (5S)- 4 with the boron enolates of the C₁₀ building blocks (4S)- 13 and (4R)- 13 , followed by decarboxylative dehydration, all stereoisomers of 16 are available (Scheme 5). Glucosylation of 16 followed by formation of the taurin amide gives, after deprotection, the four stereoisomers (8R,15S)- 1 , (8R,15R)- 1 , (8R,15S) -1 , and (8S,15S)- 1 (Scheme 6).     

Pteridines. Part XCVII. Synthesis and properties of 6-thioxanthopterin and 7-thioisoxanthopterin

6-Thioxanthopterin ( 13 ) was synthesized in four steps starting from 2-amino-4-(penthyloxy)pteridine ( 3 ) via the 8-oxide 4 , its subsequent interconversion to the 6-chloro ( 7 ) and 6-thio derivative ( 12 ) and final hydrolysis of the pentyloxy group. 7-Thioisoxanthopterin ( 15 ) was derived analogously from 2-amino-4-(pentyloxy)pteridine-7(8H)-thione ( 14 ) by alkaline hydrolysis. The various 6- and 7-thiopteridines were methylated to give the corresponding 6- ( 10, 11 ) and 7-(methylthio) derivatives ( 16, 17 ). The newly synthesized compounds have been characterized by elemental analyses, their UV spectra, and the determination of the acidic and basic pK_a values. The spectral relationships are discussed in detail.     

Approaches to the synthesis of cytochalasans. Part 6. Synthesis of the C(14)–C(23) subunit of cytochalasins A,B. F and desoxaphomin

The synthesis of methyl (4R, 8R,)-10-bromo-8-methyl-4-(1,3,6-trioxaheptane)-2-deceneoate ( 5 ), a synthon for the construction of the macrocyclic moieties of the cytochalasins A ( 1), B. (2) F (3) and desoxaphomin ( 4 ) is described. (S)-Glutamic acid ( 6 ) was transformed to the C₅-epoxide 10 and 3-methylglutaric acid ( 11 ) to the C₅-bromide 15 . Coupling of both 10 and 15 by a CuI-catalyzed Grignard reaction gave the decanol 16 in very high yield. The latter was transformed by several steps to synthon 5 .     

Purines. XIV. Synthesis and properties of 8-nitroxanthine and its N-methyl derivatives

Xanthine ( 1 ) and its N-methyl derivatives 2–16 have been nitrated to the corresponding 8-nitro derivatives 17–32 under different reaction conditions. Nitration in glacial acetic acid with nitric acid works well with the N-7 unsubstituted and some of the 9-methylxanthines, respectively, whereas the 7-methylxanthine derivatives react best with nitronium tetrafluoroborate in sulfolane or glacial acetic acid. The 8-nitro group can be displaced nucleophilically to form 8-chloro-, 33, 34 , 8-ethoxy-, 35,36 , and uric acid derivatives 37–40 , respectively. The newly synthesized 8-nitroxanthines have been characterized by elemental analyses, pK-determinations and uv and ¹H-nmr spectra.     

Polymerization of surface-active monomers. II. Polymerization of quarternary alkyl salts of dimethylaminoethyl methacrylate with a different alkyl chain length

The cationic monomers (C_NBr), obtained by quarternization of dimethylaminoethyl methacrylate with n-alkyl bromide containing varying carbon number (N = 4, 8, 12, 14, and 16) were polymerized with radical initiators in water and various organic solvents. The degree of polymerization of the resulting polymers was determined by GPC measurements on poly(methyl methacrylate) samples derived from them. The rate of polymerization of the micelle-forming monomers (N = 8, 12, 14, and 16) in water increases with increasing a chain length of alkyl group, whereas it is little dependent on N in isotropic solution in dimethylformamide. The data on the degree of polymerization for the polymers of C₄Br, C₈Br, and C₁₂Br show that the polymerization of C₁₂Br with azo initiators in water and benzene gives polymers with a very high degree of polymerization. The results obtained here suggest that highly developed or relatively rigid, aggregated structures of monomers in solution are responsible for the formation of the polymers with a very high degree of polymerization, in addition to an enhanced rate of polymerization. Also considered are the relation of the molecular weight of poly(C₁₂Br) to the viscosity data in chloroform and methanol.