Biosynthesis of tylophorine and tylophorinine

Administration of 3,4-dihydroxyphenyl[2-¹⁴C] alanine to young Tylophora asthmatica plants revealed that ring B and carbon atoms C₉ and C₇ of tylophorine and tylophorinine are derived from dopa. Tracer experiments with 6,7-diphenylhexahydroindolizines (1–7) and (26) demonstrated that compound 1 is efficiently and specifically incorporated into tylophorine (13) and tylophorinine (16). Compounds (3), (4) and (26) were not metabolized by the plants to form (13) and (16) whereas (5) and (6) were utilized to yield (13) and (16). Compound (2) was very poorly converted into (13) and (16) and thus is not on the major biosynthetic pathway of (13) and (16).     

Deoxygenation reactions of c19-diterpenoid alkaloids

Efficient methods for deoxygenation of secondary and tertiary alcohols of some C₁₉-diterpenoid alkaloids are presented. Delphisine (12) was converted to 1-deoxydelphisine (19) via either 1,2-pyrodelphisine (17) or phenyl thionocarbonate 20. The following alkaloids were deoxygenated via their thiocarbonylimidazolyl derivatives: 14-acetyldelcosine (13) to 14-acetyl-l-deoxydelcosine (22); alkaline hydrolysis of 22 gave 1-deoxydelcosine (23); aconitine (24) to 3-deoxyaconitine (27); yunaconitine (25) to crassicauline A (28). Deoxygenation of 14-acetyldictyocarpine (30) via the chloro-derivative 31 gave 14-acetyl-10-deoxydictyocarpine (34). Reduction of 31 with LiAlH₄ gave the unusual elimination product 32. An improved partial synthesis of hypaconitine (35) from aconitine (24) is also presented.     

Resolution of 1-arylalkylamines with 3-O-hydrogen phthalate glucofuranose derivatives: role of steric bulk in a family of resolving agents

The development of three new acidic resolving agents which are hydrogen phthalates of 1,2:5,6-di-O-isopropylidene-α-d-glucofuranose 1, 1,2:5,6-di-O-cyclohexylidene-α-d-glucofuranose 2 and 1,2-O-cyclohexylidene-5,6-O-diphenylmethylidene-α-d-glucofuranose 3 is shown for the resolution of 1-arylalkylamines 7a–k. The salts between 1, 2 and (RS)-1-arylalkylamines 7a–k selectively crystallize 1·(S) 7a–j and 2·(S) 7a–h salts, allowing us to recover the corresponding bases (S) 7a–j and (S) 7a–h, respectively, in good yield and enantiomeric excess (73–95% ee). Whereas, the salts between 3 and (RS)-1-arylalkylamines 7a–c,g–i,k selectively crystallize 3·(S)-7a–c,g–i salts to recover the corresponding bases (S)-7a–c,g–i in poor enantiomeric excess (4–35% ee). The difference between the resolving ability of 1 and 2 for 1-arylalkylamines 7a–h is very slight, but there is considerable difference compared to ortho-substituted 1-arylalkylamines 7i and 7j. The role of substituents on a family of resolving agents 1, 2 and 3 is also discussed to interpret their resolving ability.     

Thio-acids—V : Some reactions of 3-oxo-1,2-dithioles

Diphenyldiazomethane with compound (1) gave dibenzoyl, while 2 and 3 gave the corresponding 3-oxo(2H)thiophenes 5. With copper-bronze 1 gave 2,2′-di-(thiobenzoate) (4), while 2 gave 2,7-diphenylthiepin (6a) and 2,5-diphenylthiophene (7a), but 3 gave only 2,5-di-(p-methoxyphenyl)thiophene (7b). With Grignard reagents 1 gave the corresponding methanol derivative 14, while 2 gave the thiobenzoylethylenes 13a and b, but 3 gave 2,7-di-(p - methoxyphenyl) - 4,4,5,5- tetraphenyl(4H)thiepin (15). The reaction mechanisms are discussed.     

Stereospecific synthesis of chiral precursors of thienamycin from L-Threonine

L-Threonine was transformed, stereospecifically, to a versatile β-lactam (5a) in 3 steps. This β-lactam was further converted to a key intermediate (25) for the synthesis of thienamycin and its biologically active analogues. Furthermore, the compound 5a was changed to iodides (18 and 23), cyanides (19 and 24), chloromethylketone (26) and aldehydes (30 and 31) which appear to have a latent potential as precursors for the syntheses of the carbapenems.     

Synthesis of an octamethyl-18-crown-6 derivative and the X-ray crystal structure of its 2:1 complex with borane-ammonia

The synthesis of 2,2,3,3,11,11,12,12-octamethyl-1,4,7,10,13,16-hexaoxacyclooctadecane (2) from pinacol (3) by a sequence of reactions (3→4→5→6+5→2) involving alkylation (3→ 4), ozonolysis and reduction (4→5), tosylation (5→6), and cyclisation (5+6→2) is reported. With borane-ammonia, the octamethyl-18-crown-6 derivative 2 forms a crystalline 2:1 complex, (BH₃NH₃)₂ · 2. X-Ray crystallography reveals the two guest BH₃NH₃ molecules are hydrogen bonded in a centrosymmetric manner to the opposite faces of the host 2, which adopts an all-gauche (ag⁺a ag^-a)₃ conformation.     

Preparation and reaction of cyclopropyltriphenylphosphonium salt

Cyclopropyltriphenylphosphonium bromide (2a) was conveniently prepared from 3-bromopropyltriphenylphosphonium bromide (1a). The Wittig reaction of cyclopropyltriphenylphosphonium bromide (2a) with carbonyl compounds gave alkylidenecyclopropanes (4, 6 and 7). Successive treatment of 1a with two equivalents of base and carbonyl compounds gave alkylidenecyclopropanes (4 and 5) without isolation of intermediary 2a. 2-Methylcyclopropyltriphenylphosphonium bromide (2b) was prepared and allowed to react with carbonyl compounds.     

Synthesis of immunoreagents for measurement of galactosylhydroxylysine

(2S,5R)-(+)-Hydroxylysine (6) was transformed into (−)-succinimidyl ester (13) and conjugated to BSA or KLH to form immunogens (2 and 3) for generation of anti-galactosylhydroxylysine antibodies. Additionally, treatment of (−)-13 with 6-Fln-CH₂NH₂ (16) or acridinium derivative (17) and subsequent hydrolysis gave the fluorescent (4) and chemiluminescent (5) tracers, respectively. These immunoreagents (3,4 and 5,6) are essential for development of assays for diagnosis of osteoporosis.     

Synthesis of spiro-pyrazolines: reaction of 1,3-diphenylnitrilimine with fulvenes

A one-step synthesis of a new series of spiro-pyrazolines has been accomplished by the 1,3-dipolar cycloaddition of 1,3-diphenylnitrilimine with various fulvenes (2,3,4,5-tetraphenyl fulvene (1) and its analogues (2, 3), 9-benzalfluorene (7) and its analogues (8, 9) and 6,6-diphenylfluvene (13)). With the exception of 13 all other fulvenes undergo 1,3-dipolar cycloaddition across the exocyclic double bond to give the hitherto unreported spiro-pyrazoline derivatives (1-6, 10-12). In the case of 13, however, the addition of 1,3-dipole takes place at the site of endo-cyclic double bond, leading to the formation of a pyrazoline derivative (14).     

Synthesis of bis N-heterocyclic carbenes,derivatives and metal complexes

A method for the synthesis and isolation of 1,1′-methylene-bis-(3-aryl-imidazol-2-ylidene) ligands, aryl = 2,6-diisopropyl-phenyl (DiPP), L^DiPP, mesityl (mes), L^mes, is reported, which provides synthetically useful quantities of high purity. Derivatisation of L^DiPP with chalcogenides gave the adducts L^DiPPE₂, E = S, Se, Te. Reaction of L^DiPP with [Pd(tmeda)Me₂], [Pt(μ-SMe₂)Me₂]₂, [Ir(1,5-COD)(μ-Cl)]₂/KPF₆ and [NiBr₂(dme)] gave [Pd(L^DiPP)Me₂] (1), [Pt(L^DiPP)Me₂] (2), [Ir(L^DiPP)(1,5-COD)](PF₆) (3) and [Ni(L^DiPP)Br₂] (4), respectively. The latter was reduced in the presence of CO to [Ni(L^DiPP)(CO)₂] (5). The structures of L^mes, L^DiPPTe₂, and 1–5 are also reported.     

Search for a simpler synthetic model system for intramolecular 1,3-dipolar cycloaddition to the 5,6-double bond of a pyrimidine nucleoside

In search for a simpler model system for the study of intramolecular thermal reactions between the base and 5'-functionalized sugar moiety in nucleosides, 1-(3-azidopropyl)uracil (2), 1-(4-azidobutyl) pyrimidines (12 and 13) and 1-(5-azidopentyl)-uracil (14) was synthesized through the corresponding ω-benzoyloxy-(6,7 and 8) and ω-hydroxyalkyl-pyrimidines (9,10 and 11). Heating 2 gave 1,N⁶-trimethylene-6-aminouracil (4), while heating 12 and 13 gave N¹-C₆ cleaved addition products. 15 and 16, respectively. 15 was regiospecifically transformed to 1,2,3-triazole derivatives, 17,18 and 19. Heating 1-(4-azidobutyl)-5-bromouracil (20) yielded 3,9-tetramethylene-8-azaxanthine (22). 9 with NBA gave 1,0⁶-tetramethylene-5-bromo-6-hydroxy-5,6-dihydrouracil (24) and the 5-brominated analog of 9 (25). The 4-functionalized butyl side chain proved to serve as a substitute for the 5'-functionalized sugar moiety in pyrimidine ribonucleosides.     

Synthesis of adamantane derivatives—38: Synthesis of 1,3-bishoadamantane via ring-expansion of homoadamantan-2-one and homoadamant-4-en-2-one

The ring expansion of homoadamant-4-en-2-one (7) via the corresponding aminomethyl alcohol (9) gave 1,3-bishomoadamant-7-en-4-one (10) as the major product which was converted to 1,3-bishomoadamant-4-ene (14) and 1,3-bishomoadamanta-4,7-diene (16) via the alcohols 13 and 15. Catalytic hydrogenation of 14 and 16 afforded 1,3-bishomoadamantane (2). The ring expansion of homoadamantan-2-one (17) via the aminomethyl alcohol (19) afforded a 9:1 mixture of 1,3-bishomoadamantan-4-one (12) and 5-one (20). The same mixture was also obtained directly from 17 on treatment with diazomethane. The Wolff-Kishner reduction of 12 and 20 gave also 2.     

Comparative effect of cyclodextrin nanocavities versus organic solvents on the fluorescence of carbamate and indole compounds

The effect of the addition of different amounts of organic solvents (S) on the fluorescence of aromatic compounds (C) and their inclusion complexes with β-cyclodextrin (βCD) and hydroxypropyl-β-cyclodextrin (HPCD) has been examined using steady-state measurements. Carbamate pesticides with different aromatic moiety, such as carbofuran (CF), promecarb (PC), carbaryl (CY) and bendiocarb (BC) were used, as well as indole derivatives with different polarity in their lateral chains, such as melatonin (M, neutral), 5-methoxytryptamine (MT, cation) and auxin (IA, anion). Their complexes in water show a fluorescence signal higher than that obtained for the free substrates in solvent:water mixtures (30%, v/v n-propanol or acetonitrile, and 50%, v/v methanol). The isofluorescent point (IF), the %IF and the F_85% are defined in order to evaluate the use of CD nanocavities as a non-polluting alternative for the analysis of the compounds analyzed.Apparent formation constants (K_AP, M⁻¹) for the complexes of C:HPCD at different solvent percentages were determined for CF and PC with methanol (MeOH), n-propanol (ProOH) and acetonitrile (ACN), and for indole compounds with ACN. A decrease in the K_AP values for the CF:HPCD (120–30) and PC:HPCD (2000–400) complexes occurs in accordance with the solvent affinities for CDs (MeOH < ACN < ProOH). Nevertheless, in the indolic series, the polar characteristics of MT, IA and M determine their behaviour in the presence of ACN. For the neutral substrate M, K_AP decreases with the increasing percentage of ACN (100–10). In contrast, for IA and MT (ionic substrates) K_AP increases (10–100).These results may be accounted for by two different mechanisms: the competition between C and S for the cavity of the receptor or the formation of ternary complexes C:S:CD with additional stabilization.     

Chemo-, stereo- and regioselective hydrogenolysis of carbohydrate benzylidene acetals. Synthesis of benzyl ethers of benzyl α-d-, methyl β-D-mannopyranosides and benzyl α-D-rhamnopyranoside by ring cleavage of benzylidene derivatives with the LiAlH4-AlCl3 reagent

Treatment of benzyl α-(1) and methyl β-d-mannopyranoside (2) with α,α-dimethoxytoluene gave the exo and endo isomers (3,5 and 4,6) of the dibenzylidene derivatives of 1 and 2. Hydrogenolysis of the exo isomers (3 and 5) with a molar equivalent of AlH₂Cl gave the 3-0-benzyl-4,6-0-benzylidene derivatives (7 and 21), whereas the endo isomers (4 and 6) gave the 2-0-benzyl-4,6-0-benzylidene compounds (8 and 22). The 2-0-allyl ether 9 of 7, the 3-0-allyl derivative (10) of 8 and compounds 21 and 22 were treated with an additional molar equivalent of AlH₂Cl at reflux and the products were the 4-0-benzyl-6-hydroxyl derivatives (11, 12, 23 and 24), whereas in the case of 22 the 6-0-benzyl-4-hydroxyl isomer (25) was also isolated. By deallylation of 11 and 12, 3,4-(13) and 2,4-di-0-benzyl (14) ethers of 1 were prepared. Tosylation of 11 and 12, and subsequent reduction of the products (15 and 16) made possible the preparation of the partially protected benzyl α-d-rhamnopyranoside derivatives (17–20). The structures of the compounds synthesized were characterized by ¹H and ¹³C NMR spectroscopic investigation and by chemical methods.     

Novel generation and cycloaddition reactivity of N-phenylsulfonylbenzonitrilimine via thermal decomposition of N-(phenylsulfonyl)benzohydrazonoyl chloride

Thermal decomposition of N(phenylsulfonyl)-benzohydrazonoyl chloride (1) in refluxing toluene generated N-phenylsulfonylbenzonitrilimine (2) which gave 1,3-dipolar cycloadducts with ethyl (4a) and methyl acrylate (4b), acrylonitrile (4c), styrene (4d), norbornene (4e), and norbornadiene (4f). The reactions with 4a–d, 2 afforded regiospecifically 5-R substituted pyrazolines 5a–d in lower yields. The raction of 2 with 4e gave only exo adduct 5e, while the reaction with 4f gave both exo- (5f_x) and endo adducts (5f_n) as well as their retro-Diels-Alder product 6.     

Synthesis and structures of the dinuclear tin(II) complexes [R = Ph, X(Z) = CPh; R = SiMe3, X(Z) = PPh2] and of related compounds

Tin(II) compounds containing the ligands [CH(C₆H₃Me₂-2,5)C(Bu^t)NSiMe₃]⁻ (≡ L¹), [CH(Ph)C(Ph)NSiMe₃]⁻ (≡L²), [CH(SiMe₃)P(Ph)₂NSiMe₃]⁻ (≡ L³),

Full-size image (3K)

(≡ L⁴), [C(Ph)C(Ph)NSiMe₃]²⁻ (≡ L⁵), and [C(SiMe₃)P(Ph)₂NSiMe₃]²⁻ (≡ L⁶) are reported: the transient SnBr(L¹) (1) and SnBr(L²) (2), Sn(L¹)₂ (3) [P.B. Hitchcock, J. Hu, M.F. Lappert, M. Layh, J.R. Severn, J. Chem. Soc., Chem. Commun. (1997) 1189], the labile Sn(L²)₂ (4), [Sn(L⁵)]₂ (5), SnCl(L³) (6), Sn(L³)₂ (7), [Sn(L⁶)]₂ (8), Sn(L⁴)₂ (9) and Pb(L⁴)₂ (10). They were prepared from (i) SnBr₂ and K(L¹) (1, 3) or K(L²) (2, 4, 5); (ii) SnCl₂ and Li(L³) (6–9); or (iii) PbCl₂ and Li(L⁴) (10). Each of 1, 3 and 5–10 has been characterised by multinuclear NMR spectra; 3, 5, 6, 8, 9 and 10 by EI-mass spectra, but only 3, 5, 8, 9 and 10 were isolated pure and furnished X-ray quality crystals. Of greatest novelty are the title binuclear fused tricyclic ladder-like compounds 5 and 8. Quantum chemical calculations, on alternative pathways to 5 from 2 and to 8 from 7, are reported.     

Steady-state and nanosecond spectroscopic studies of triplet sensitized reaction of K-region arene oxides

Photorearrangement reactions of K-region arene oxides, 9,10-epoxy-9,10-dihydrophenanthrene (1a), 3-acetyl-9,10-epoxy-9,10-dihydrophenanthrene (1b), and 3,4-epoxy-3,4-dihydropyrene (1c) in dichloroethane (DCE) solution were investigated by steady irradiation and nanosecond transient spectroscopy. Photorearrangements producing substituted oxepins, 2 occur via the singlet excited state of these compounds, while the phenolic products, 9-hydroxyphenanthrene (3a), 3-acetyl-9-hydroxyphenanthrene (3b), and 4-hydroxypyrene (3c) are formed via the triplet state. Phenol 3 formation from the triplet 1 sensitized by the triplet 3 (i.e. product sensitization) is proposed for the photorearrangement reactions of 1a and 1c, and this process is the only way phenol (3a) is formed because of the negligible intersystem crossing probability of 1a. No product sensitization occurs in the photorearrangement reaction of 1b.     

Photochemistry—xiii: The photokomerization of pyridazine 1 ,2-dioxides: formation of 3a,6a-dihydroisoxazolo[5,4-d]isoxazole

Products, generated from a photolysis of 1,2-dioxides (1) of unsubstituted (a), 3-Me-(b), 4-Me-(c), 3,6-diMe (d), 3-Ph-(e), 3-Me-6-Ph-(f) and 3,6-diPh-(g) pyridazines, have been investigated.Dioxides (1a–g) afforded 3a,6a-dihydroisoxazolo[5,4-d]isoxazoles (2a-g). Dioxides (1e and 1g) afforded 3-phenylisoxazole(7) besides 2. The structure of 2a was examined by X-ray crystallography.The compound 2d was also obtained by oxidation of the hexa-3-ene-2,5-dione dioxime. A mechanism generating those products has been speculated.     

Structural elucidation,antioxidant and hepatoprotective activities of chemical composition from Jinsi Huangju (Chrysanthemum morifolium) flowers

Six new compounds (huangjusus A-F), including three caffeic acid glycosides (1–3), one quinic acid derivative (4), one dihydroflavone glycoside (11) and one monoterpene (31), together with thirty-eight known compounds (5–10, 12–30, 32–44), were obtained from “Jinsi Huangju” (Chrysanthemum morifolium Ramat.) flowers. Their structures were elucidated on the basis of the data obtained from different spectroscopic techniques. Among these compounds, five new (1–4 and 11) and ten known (5–9, 12, 13, 17, 40, and 42) compounds demonstrated significant 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid) (ABTS) radical scavenging effects with IC₅₀ values of 4.22–19.90 μM. Furthermore, three new compounds (1, 11, and 31) and seven known compounds (13, 19, 21, 29, 30, 39, and 41) exhibited potent hepatoprotective activities against N-acetyl-p-aminophenol (APAP)-induced toxicity in HepG2 cells with the cell survival rates of 61.53 %, 63.55 %, 60.01 %, 63.05 %, 59.75 %, 59.15 %, 61.07 %, 62.72 %, 58.86 %, and 58.76 % (positive control bicyclol, 58.41 %), respectively, at a concentration of 10 μM. These results indicate the potency of the flowers against radicals and in hepatoprotections.     

Phosphorylation of nucleoside derivatives with aryl phosphoramidochloridates

The preparation of three aryl phosphorocyclohexylamidochloridates (7a, 7b and 7c) and an aryl phosphoromorpholidochloridate (8) is described. These aryl phosphoramidochloridates react with 2′,3′-O-methoxymethylene-uridine, -4-N-anisoylcytidine and -6-N-anisoyladenosine (9a, 9b and 9c, respectively), in the presence of the 1-ethylimidazole derivative (11a) to give high yields of the corresponding fully-protected 5′-phosphoramidates (10). Treatment of the latter compounds with aqueous alkali gives the nucleoside 5′-phosphoramidate derivatives (14) which, on mild acidic hydrolysis, give the corresponding unprotected 5′-nucleotides (15) in virtually quantitative yields. Phosphorylation of 2′-O-methoxytetrahydropyranyluridine (12) with 7a and 8, under the same conditions, occurs regiospecifically to give the corresponding 5′-phosphoramidate derivatives (13). The partially-protected dinucleoside phosphate (16b) has been prepared and phosphorylated with 7a to give, after removal of the protecting groups, the dinucleotide (18, pUpU) in high yield.