Total synthesis of prolycopene, a novel 7,9,7′,9′-tetra-cis(Z) carotenoid and main pigment of the tangerine tomato Lycopersicon esculentum

A total synthesis of the 7,9,7′,9′-tetra-cis(Z) isomer of lycopene, also known as ‘prolycopene’, produced as the major carotenoid pigment in fruits of the tangerine tomato Lycopersicon esculentum (‘Tangella’) is described. The synthesis is based on: (i) a modified Sonogashira coupling reaction between the E-alkenyl bromide 6 and the Z-enynol 7, leading to the 2Z-trienynol 8, followed by (ii) a Wittig reaction between the phosphonium salt 4 and the C₁₀-triene dialdehyde 5 producing the symmetrical 9,9′-Z isomer of the bis-acetylene 3 and (iii) semi-hydrogenation of 3 in the presence of Lindlar's catalyst, and chromatography.     

Humulene derivatives from Saharian Asteriscus graveolens

Three new sesquiterpene-humulenes, (?)- asteriscunolides I (1), J (2) and (?)-(2Z,6E,9Z)-8-oxo-1α-acetoxy-2,6,9-humulatrien-12-oic acid (3) were isolated from the leaves-flowers of the Saharan medicinal plant Asteriscus graveolens along with six known compounds. The structures of the compounds were determined on the basis of spectroscopic mono and bidimensional NMR, mass spectrometry and by single-crystal X-ray diffraction. Compounds 1–3 were evaluated for cytotoxic assay, no significant activity was detected.     

Acid catalyzed monodehydro-2,5-diketopiperazine formation from N-α-ketoacyl amino acid amides

We have developed a new synthetic method for monodehydro-2,5-diketopiperazines (monodehydroDKPs), which is based on an acid catalyzed cyclization of N-α-ketoacyl amino acid amides. Using this cyclization reaction, monodehydroDKP was formed with no or slight racemization in case that N-α-ketoacyl amino acid amides with β-aliphatic-α-ketoacyl groups and sterically unhindered N-substituting groups at the C-terminal amide nitrogen were used in the presence of catalytic amount of p-TsOH (3-5 mol %) or 10% TFA. In the case of β-aryl-α-ketoacyl amino acid derivatives, in which an enol form predominantly exists by conjugation with the aromatic ring, racemization could be minimized by optimizing the reaction conditions (5 mol % p-TsOH, reflux for 6 h), although the chemical yield could not be dramatically improved. However, this reaction condition was successfully applied to the synthesis of a tubulin depolymerization agent, (−)-tert-butyl-oxa-phenylahistin, with no racemization.     

Application of chiral tetrahydropentalene ligands in rhodium-catalyzed 1,4-addition of (E)-2-phenylethenyl- and (Z)-propenylboronic acids to enones

Chiral tetrahydropentalenes (3aR,6aR)-1 have been prepared and used as ligands in the Rh-catalyzed 1,4-addition of 1-alkenylboronic acids to cyclic enones 5. It has been discovered that the stereochemistry of the reaction was controlled by the steric properties of the aryl groups in 1 rather than their electronic nature. In the vinylation with (E)-2-phenylethenylboronic acid 5, ligands (3aR,6aR)-1 provided enantioselectivity up to 87% ee and gave high yields of ethenylketones 6 in the presence of 1 (6.6 mol %). The configuration of all ketone products obtained with (3aR,6aR)-1 is (S). Rh-catalyzed reaction of cyclopentenone 4a and (Z)-propenylboronic acid 7 in the presence of ligands (3aR,6aR)-1 yielded at 50 °C an inseparable mixture of (Z)- and (E)-ketones 8 with (Z)-8 as the major product and both in only moderate enantiomeric excess.     

A new method for the detection of racemization during peptide synthesis: stereoselective hydrolysis of diastereomeric peptides by leucine aminopeptidase

A suitably protected dipeptide of configuration L -D , e.g. Z-L -Ala-D -Ala is coupled with an all L alanine peptide, e.g. L -Ala-L -Ala-ONb

1 Abbreviations according to the IUPAC-IUB rules, ‘Symbols for Amino-Acid Derivatives and Peptides, Recommendations (1971)’'. see e.g. J. biol. Chemistry 247, 977 (1972). In particular the following abbreviations have been used: Z = benzyloxycarbonyl-, -ONb = p-nitrobenzyloxy-, -ONSu = succinimido-oxy-. Additional abbreviations are LAP = leucine aminopeptidase, DCCI = N,N′-dicyclohexylcarbodiimide, DMF = dimethylformamide.

. The blocking groups are removed and the free peptide hydrolyzed by leucine amino peptidase (E.C. 3.4.1.1). This enzyme shows absolute L -specificity for the penultimate peptide bond from the amino end and therefore cleaves only the all L peptide formed through racemization. The amount of free alanine determined by amino acid analysis gives a multiple of the degree of racemization. The sensitivity of the test allows 0.1% of (L -Ala)₄ to be detected in the synthesis of L -Ala-D -Ala-L -Ala-L Ala. Coupling of Z-L -Ala-D -Ala and Z-L -Ala-D -Phe with di- and trialanine peptides has been studied using DCCI and DCCI + 1-hydroxybenzotriazole as coupling reagents. The degree of racemization was around 80% for the coupling by DCCI in DMF but was reduced to 0.2–0.4% in the presence of 2 equivalents of 1-hydroxybenzotriazole. Coupling using the succinimide esters Z-L -Ala-D -Ala-ONSu and Z-L -Ala-D -Phe-ONSu resulted in 0.8 to 10% racemization, depending on the solvent and base used.     

First enantiospecific Baker–Venkataraman-rearrangements aiming at the total synthesis of chiral anthrapyran antibiotics

The base-catalyzed acyl transfer (Baker–Venkataraman reaction) of chiral 2-acetyl-1-hydroxyanthraquionone esters 6 of 2-methylbutanoic acid or 11 of O-allyl lactic acid proceeds with virtually no racemization to ketides 7 and 12. The subsequent acid-catalyzed cyclization to the chiral anthra[1,2-b]pyran antibiotics such as (S)-1″-11-dideoxyespicufolin 8 or 13 also occurs with a very low racemization.     

Synthesis of E and Z 1-amino-2-aryl(alkyl)-cyclopropanecarboxylic acids via meldrum derivatives

The reaction of 5-arylidene(alkylidene)-2,2-dimethyl-1,3-dioxane-4,6-diones (1) (Meldrum's acid derivatives) with dimethylsulfoxonium methylide gave 1- aryl(alkyl) - 6,6 - dimethyl - 4,8 - dioxo - 5,7 -dioxaspiro [2.5] octanes (2) which, on treatment with sodium methoxide or ammonium hydroxide, gave exclusively E-1-methoxy-carboyl-2-aryl-cyclopropanecarboxylic acids (4) or Z-1-carbamoyl-2-aryl(alkyl)-cyclopropanecarboxylic acids (7), respectively. Compounds, 4, under conditions of Curtius-type reactions, yielded Z-methyl 1-isocyanate-2-aryl-cyclopropanecarboxylates (5), while derivatives 7 were treated with hypobromite, leading to E-1-methoxy-carbonylamino-2-aryl(alkyl)-cyclopropanecarboxylic acids (8).Reaction of compounds 5 and 8 with hydrochloric acid produced the corresponding Z and E 1-amino-2-aryl (alkyl)-cyclopropanecarboxylic acids hydrochlorides (6). The ¹H-NMR spectral data were analyzed to deduce the stereochemistry of the compounds obtained.     

Stereospecific preparation of (1E,3E,5E)-3.4-difluoro-1,6-diphenylhexatriene and (2E,4E,6E)-diethyl-4,5-difluoroocta-2,4,6-trienedioate

Palladium(0) catalyzed coupling of β-bromostyrene (E/Z = 89/11) with (E)-(1,2-difluoro-1,2-ethenediyl)bis[tributylstannane], 1, in DMF at room temperature stereospecifically gave only (1E,3E,5E)-3,4-difluoro-1,6-diphenylhexatriene. Similarly, palladium(0) catalyzed coupling of (E)-ethyl 3-bromoacrylate as the vinyl halide precursor stereospecifically gave (2E,4E,6E)-diethyl-4,5-difluoroocta-2,4,6-trienedioate. This work demonstrates that a non-fluorine-containing vinyl bromide will selectively undergo coupling with 1 and enable the stereospecific preparation of a mixed polyene system. The (E)-ethyl 3-bromoacrylate coupling with 1 illustrates that mixed functionalized hexatriene systems can be easily accessed via this methodology. The X-ray structure of (2E,4E,6E)-diethyl-4,5-difluoroocta-2,4,6-trienedioate confirmed its structure.     

A study of 1,5-hydrogen shift and cyclization reactions of an alkali isomerized methyl linolenoate

Heating a mixture formed by alkali isomerization of methyl linolenoate (1) produces a complex mixture with the bicyclic hexahydroindenoic esters 4β-(7-methoxycarbonylheptyl)-5α-methyl-2,3,3aα,4,5,7aαhexahydroindene (CL5) and 4β-ethyl-5α-(6-methoxycarbonylhexyl)-2,3,3aα,4,5,7aα-hexahydroindene (CL6) as main components. Similar isomerization reactions of three synthetic model compounds, methyl 9Z,13E,15Z-octadecatrienoate (2), 9Z,14E,16E-octadecatrienoate (4) and 9Z,11E,15Z-octadecatrienoate (5) corroborated the results obtained with alkali isomerized methyl linolenoate.     

Studies on Wittig rearrangement of furfuryl ethers in steroidal side chain synthesis

Wittig rearrangement of 17(20)-ethylidene-16-furfuryloxy steroids 5-8 was examined. Reaction of 17E(20)-ethylidene-16α-furfuryloxy steroid 5 with t-BuLi in THF afforded (20S,22S)- and (20S,22R)-22-hydroxy steroids 9, 10 and 17Z(20)-ethylidene-16α-(2-furyl)hydroxymethyl steroid 11 in 61, 28, and 9% yields, respectively. Base treatment of 17E(20)-ethylidene-16β-furfuryloxy steroid 7 gave (20R,22R)-22-hydroxy steroid 13 and 17Z(20)-ethylidene-16β-(2-furyl) hydroxymethyl steroid 14 in 60 and 17% yields. In contrast, 17Z(20)-ethylidene-16-furfuryloxy steroids 6, 8 led to the corresponding 2,3-rearranged products in low yields (25% for (20R,22S)-22-hydroxy steroid 12; 31% for (20S,22R)-22-hydroxy steroid 10). Both (20S,22S)- and (20S,22R)-22-hydroxy steroids 9, 10 were converted by catalytic hydrogenation into known compounds 16, 17, key intermediates for the synthesis of biologically active steroids.     

Efficient synthesis of 3-benzoyl Benzo[b]thiophenes and raloxifene via Mercury(II)-Catalyzed cyclization of 2-alkynylphenyl alkyl sulfoxides

The unique selective estrogen receptor modulator, Raloxifene (1), and antitubulin agent 2 were synthesized through the key intermediate, 4-methoxybenzyl 2-bromo-4-methoxyphenyl sulfoxide (6), respectively. It was found that compared with the o-sulfanyl aryl bromides, the sulfinyl group at ortho position accelerated the Sonogashira coupling reaction of aryl bromides. Thus, compound 6 was coupled with 3,4,5-trimethoxyphenyl acetylene, followed by mercury-catalyzed cyclization reaction afford compound 2 in 79% overall yield. Raloxifene (1) was prepared from compound 6 in four steps and 33% overall yield via coupling reaction with 1-trimethylsily-2-(4-tert-butyldimethylsiloxy)phenylethyne, mercury-catalyzed cyclization reaction, alkylation and demethylation.     

An efficient enantioselective synthesis of (R,R)-formoterol,a potent bronchodilator,using lipases

The potent β₂-adrenergic receptor agonist formoterol (R,R)-1 has been obtained in enantiomerically pure form by a convenient chemoenzymatic approach by coupling of epoxide (R)-6 with the unprotected primary amine (R)-9. Both chiral precursors have been prepared by enantiodifferentiation processes involving Pseudomonas cepacia (lipase PS) and Candida antarctica lipase (CALB), respectively. For the resolution of amine 9, we have found that utilization of triethylamine as non-reactive base enhances the reaction rate and the enantioselectivity of the process. The key coupling reaction of (R)-6 and (R)-9 has been conducted through derivatization of the amine with the labile trimethylsilyl group, which liberates the amino group of the resulting amino alcohol (R,R)-11 upon column chromatography purification. In this way, the overall approach is shorter than others previously described.     

A new synthesis of theaspirone,an odiferous principle of tea

A new synthesis of theaspirone (10) is recorded. The key step involves coupling between the organolithium reagent 6, derived from 4-bromo-2-butanol (4), and the monoketal of 4-ketoisophorone (3). Removal of protecting groups and ether cyclization then gave theaspirone 10 and its diastereoisomer 11.     

Trienylboronic acid, a versatile coupling tool for retinoid synthesis; stereospecific synthesis of 13-aryl substituted (11Z)-retinal

Trienylboronic acid 1a was prepared from iodotriene 3, which was coupled with (2Z,4Z)-3-aryl-5-iodo-2,4-pentadienol 9 by Suzuki coupling reaction to give geometrically pure 13-aryl substituted (11Z)-retinol 10. Oxidation of 10 gave 13-aryl substituted (11Z)-retinal 11.     

A novel method for (Z)-stereoselective preparation of CF3-substituted enediynes and their coupling reactions

Trifluoromethylated enynyl sulfones 3 were reacted with 2-4 equiv of phenyl, n-hexyl, trimethylsilyl, or triisopropylsilyl substituted ethynyllithium reagents in THF or ether at 0 °C to give trifluoromethylated enediynes 6 (Z)-stereoselectively in 41-96% yields. The reactions of β-fluoro-β-trifluoromethylvinyl sulfone 5 with same ethynyllithium reagents (4 equiv) afforded the corresponding enediynes 6 in 41-90% yields. The cross-coupling reactions of 6 bearing TMS group with aryl iodides in the presence of Pd(PPh₃)₂Cl₂, Ag₂CO₃, and n-Bu₄NBr provided the corresponding enediynes 6 in 20-71% yields. Dimerization of (Z)-6 bearing TMS group in the presence of CuBr₂ and K₂CO₃ yielded dimer (Z,Z)-7 in good yield.     

Chemoenzymatic enantiodivergent total syntheses of (+)- and (−)-codeine

Whole-cell fermentation of β-bromoethylbenzene with the recombinant strain Escherichia coli JM109 (pDTG601) that over-expresses toluene dioxygenase provided the corresponding cis-dihydrodiol 19, which served as a starting material for both enantiomers of codeine. The key intermediate for the synthesis of (+)-codeine was diol 25b, whose Mitsunobu coupling with bromoisovanillin was followed by an intramolecular Heck cyclization to aldehyde 35b. Elaboration of this material to vinyl bromide 27b allowed for the second Heck cyclization 36b. Adjustment of the C-6 stereogenic center and hydroamination completed the synthesis of ent-codeine in 14 steps from β-bromoethylbenzene. Diol 33b was converted via Mitsunobu reaction to epoxide 29, whose allylic opening with bromoisovanillin provided ether 54, the enantiomer of 35b. The synthesis of (−)-codeine was completed via two Heck cyclizations and a hydroamination protocol, in an analogous manner as that of ent-codeine. In addition, both enantiomers of epoxide 29, convenient precursors for the coupling with bromoisovanillin, were prepared from diol 33b by Mitsunobu reactions and cyclizations of the trans-diol moiety. Spectral and experimental data are provided for all compounds.     

Total synthesis of (+)-Z-deoxypukalide, a furanobutenolide-based cembranoid isolated from the pacific octocoral Leptogorgia spp.

A total synthesis of (+)-Z-deoxypukalide 3 using a combination of Stille and Nozaki-Hiyama-Kishi(NHK) coupling reactions as key steps, is described. During this study a new practical synthesis of the substituted butenolide intermediate 10, based on a combination of RCM and CM reactions from the cyclobutene ester 21 in the presence of 2-methylpropenol was also developed. Attempts to apply the intramolecular NHK reaction to the substrates 8a and 8b containing an ester group adjacent to the reacting aldehyde functionality gave disappointing low yields (<6%) of the corresponding coupled products 9. The synthetic (+)-Z-deoxypukalide 3 was correlated with naturally derived material, and also with pukalide 1, the first member of the furanobutenolide-based cembranoids to be isolated from corals.     

A new route to thiopyran S,S-dioxide derivatives via an overall ring-enlargement protocol from 3-nitrothiophene

(1E,3Z)-1-Aryl-4-methanesulfonyl-2-nitro-1,3-butadienes (8), derived from the initial ring-opening of 3-nitrothiophene (5), have been found to undergo a facile base-induced cyclization leading to thiopyran S,S-dioxides (9), thus furnishing a further example of effective ring-enlargement from 5- to 6-membered sulfur heterocycles. Compounds 9 are obtained as single racemic mixtures in satisfactory yields; they still contain a nitrovinylic moiety, which can be exploited for further modifications targeted to new derivatives endowed with either synthetic or pharmacological potentialities e.g., in the field of L-type Ca²⁺-channel blockers.     

Thermal and photochemical isomerization of exocyclic 1,3-dienes: 1,1-diphenyl-3,4-bis(trimethylsilylmethylene)-1-silacyclopentane s-cis(E,E)

This paper describes the photochemical and the thermal isomerization of s-cis(E,E) 1,1-diphenly-3,4-bis(trimethylsilylmethylene)-1-silacyclopentane (1a). Under thermal conditions a 1,3-sigmatropic of the methylene hydrogen occurs, yielding the s-trans isomer (1b). The photochemical irradiation of (1a) at 300 nm for 1 h in deoxygenated benzene gives the corresponding s-cis(E,Z) isomer (1c) and then the s-cis(Z,Z) isomer (1d) after prolonged irradiation (3 h). There was no evidence for the formation of the corresponding cyclobutene resulting from the ring closure of the exocylic diene.     

Preparation and characterization of molybdenum and tungsten compounds with diazabutadiene ligands constructed from amino esters and glyoxal: Crystal structures of meso and C2-symmetric isomers of Mo(CO)4(dab-asp(OMe)-OMe)

The title compounds were prepared by heating solutions of ester protected amino acids (H-l-Ala-OEt, H-β-Ala-OEt, H-l-Val-OMe, GABA-OMe, H-l-Asp(OMe)-OMe) and glyoxal in the presence of M(CO)₄(pip)₂ (M=Mo, W). The resulting novel complexes, M(CO)₄(dab-xxx-OR) (dab=diazabutadiene), contain an N,N′-diimine ligand and were characterized by ¹H- and ¹³C-NMR, IR, and UV-vis measurements. The low energy band in the visible portion of the electronic spectrum is assigned to a MLCT transition and exhibits solvatochromism. The valine, alanine and aspartic ester derivatives have C₂ symmetry resulting from the C₂ symmetry of the ligand. The reaction of the alanine and aspartic amino esters in the presence of NEt₃ produces diastereomeric mixtures caused by racemization at the amino acid α-carbon. Racemization is not observed during the formation of the valine derivatives. The crystal structures of (R,S)-Mo(CO)₄(dab-asp(OMe)-OMe) (5-RS), and (S,S)-Mo(CO)₄(dab-asp(OMe)-OMe) (5-SS), were determined. The structure of 5-RS confirms that racemization at the α-carbon occurred. 5-SS has C₂ symmetry.