First enantiospecific synthesis of (+)-β-herbertenol

The first enantiospecific synthesis of (+)-β-herbertenol, from naturally occurring R-(+)-citronellal, employing Taber's diazo decomposition protocol as the key step, is described.     

First enantiospecific synthesis of the antitumor marine sponge metabolite (-)-15-oxopuupehenol from (-)-sclareol

[reaction: see text] A new route toward puupehenone-related bioactive metabolites from (-)-sclareol, based on the palladium(II)-mediated diastereoselective cyclization of a drimenylphenol, is described. Utilizing this, the first enantiospecific synthesis of the antitumor and antimalarial (-)-15-oxopuupehenol, together with improved syntheses of (+)-puupehenone, (+)-puupehedione, and (+)-15-cyanopuupehenone, were accomplished.     

An enantiospecific synthesis of (+)-isoparvifolinone and (−)-parvifoline

An enantiospecific synthesis of (+)-isoparvifolinone and (−)-parvifoline, from naturally occurring (R)-(+)-citronellal, employing intramolecular Friedel-Crafts acylation as the key step, is described.     

Synthesis of (+)-agelasine D from (+)-manool

(+)-Agelasine D, originally isolated from the marine sponge Agelas nakamurai, is synthesized for the first time. The terpenoid side chain was readily available from the diterpene alcohol (+)-manool.     

The first enantiospecific total synthesis of a C-quaternary voachalotine alkaloid, (+)-dehydrovoachalotine

The first enantiospecific total synthesis of the indole alkaloid (+)-dehydrovoachalotine (1) has been achieved from d-(+)-tryptophan methyl ester in 28% overall yield. The formation of the prochiral quaternary carbon center at C-16 in the key intermediate (12) was realized via a Tollens reaction from N_a-methylvellosimine (13) in 95% yield. This approach could also be applied to the synthesis of many other indole alkaloids that contain a quaternary carbon center at C(16).     

Synthesis of (+)- and (−)-isocarvone

The first synthesis of 5-isopropenyl-3-methyl-cyclohex-2-enone, (isocarvone) (2), in enantiomerically pure form is reported. Both enantiomers of 2 can be produced by manipulation of carboxylic acid 5, which is available from R-(−)-carvone (1). These materials provide new chiral building blocks that could be used in total synthesis of natural products and related optically active compounds.     

Highly efficient total synthesis of the marine natural products (+)-avarone, (+)-avarol, (-)-neoavarone, (-)-neoavarol and (+)-aureol

Biologically important and structurally unique marine natural products avarone (1), avarol (2), neoavarone (3), neoavarol (4) and aureol (5), were efficiently synthesized in a unified manner starting from (+)-5-methyl-Wieland-Miescher ketone 10. The synthesis involved the following crucial steps: i) Sequential BF(3)Et(2)O-induced rearrangement/cyclization reaction of 2 and 4 to produce 5 with complete stereoselectivity in high yield (2 --> 5 and 4 --> 5); ii) strategic salcomine oxidation of the phenolic compounds 6 and 8 to derive the corresponding quinones 1 and 3 (6 --> 1 and 8 --> 3); and iii) Birch reductive alkylation of 10 with bromide 11 to construct the requisite carbon framework 12 (10 + 11 --> 12). An in vitro cytotoxicity assay of compounds 1-5 against human histiocytic lymphoma cells U937 determined the order of cytotoxic potency (3 > 1 > 5 > 2 > 4) and some novel aspects of structure-activity relationships.     

First enantioselective synthesis of (−)-neplanocin F

(−)-Neplanocin F, the natural isomer of a component of the neplanocin family was enantioselectively synthesized starting from d-γ-ribonolactone. The synthetic approach was based on the preparation of a suitable carbocyclic precursor bearing three hydroxyl groups orthogonally protected. The key steps of the synthesis were the regioselective protection of a secondary allylic alcohol over a homoallylic one and the coupling of the nucleobase with a triflate intermediate.     

A concise and stereoselective synthesis of (+)- and (−)-deoxoprosophylline

An efficient synthesis of (+)- and (−)-deoxoprosophylline was accomplished from the readily available cis-2-butene-1,4-diol in which the Sharpless asymmetric dihydroxylation was used as the key step.     

Total synthesis of (+)-epiepoformin and (−)-phyllostine

An efficient asymmetric total synthesis of naturally occurring cyclohexeneoxides, (+)-epiepoformin and (−)-phyllostine has been achieved using the chiral building block available from the base-catalyzed Diels-Alder reaction of 3-hydroxy-2-pyrone. Since (−)-theobroxide was derived from the same precursor of (+)-epiepoformin, the formal total synthesis of (−)-theobroxide has also been achieved.     

A diethyltartrate-based synthesis of both (−)- and (+)-arundic acid

A diethyltartrate-based synthesis of both enantiomers of the acute ischemic stroke therapeutic agent, arundic acid is presented. Separable diastereomers were obtained through the Johnson-Claisen rearrangement of the chiral vicinal diol based on the diethyltartrate skeleton and were converted separately into the two enantiomers of arundic acid.     

Total synthesis of (±) maculalactone A, maculalactone B and maculalactone C and the determination of the absolute configuration of natural (+) maculalactone A by asymmetric synthesis

Maculalactones A, B and C from the marine cyanobacterium Kyrtuthrix maculans are amongst the only compounds based on the tribenzylbutyrolactone skeleton known in nature and (+) maculalactone A from the natural source possesses significant biological activity against various marine herbivores and marine settlers. We now report a concise synthesis of racemic maculalactone A in five steps from inexpensive starting materials. Maculalactones B and C were synthesized by a minor modification to this procedure, and the synthetic design also permitted an asymmetric synthesis of maculalactone A to be achieved in around 85% ee. The (+) and (−) enantiomers of maculalactone A were assigned, respectively, to the S and R configurations on the basis of the chiral selectivity expected for catecholborane reduction of an unsymmetrical ketone in the presence of Corey's oxazoborolidine catalyst. Surprisingly, it appeared that natural (+) maculalactone A was biosynthesized in K. maculans in a partially racemic form, comprising ca. 90-95% of the (S) enantiomer and 5-10% of its (R) enantiomer. Coincidentally therefore, the percentage enantiomeric excess of the product obtained from asymmetric synthesis almost exactly matched that found in nature.     

First synthesis of picealactone C. A new route toward taxodione-related terpenoids from abietic acid

A new route to 12-hydroxyabietic acid (10) and related compounds from abietic acid (12), via acetoxyalcohol 15, is reported. Utilizing this, the first synthesis of picealactone C (5) was achieved. The synthesis of natural 12-hydroxydehydroabietic acid (8), 18-hydroxyferruginol (9) and methyl 12α-hydroxyabietate (11) is also reported.     

Novel synthetic strategy toward abietane and podocarpane-type diterpenes from (−)-sclareol: synthesis of the antitumor (+)-7-deoxynimbidiol

A new route to abietane and podocarpane-type terpenoids from labdane diterpenes is reported. The key step is the transformation of β-ketoester 9 into the corresponding O-acetylsalicylate ester 18, via a manganese(III)-based oxidative free-radical cyclization carried out in Ac₂O. Utilizing this, the synthesis of the antitumor (+)-7-deoxynimbidiol (5) from (−)-sclareol (11) has been achieved. (+)-Nimbidiol (6) and the natural terpenoid 20 have also been synthesized.     

Stereoselective synthesis of (−)-cytoxazone and (+)-epi-cytoxazone

Optically pure (−)-cytoxazone was synthesized, starting from methyl p-methoxycinnamate, in six steps and in 31% overall yield. The required anti-aminoalcohol configuration was established by combining Sharpless asymmetric aminohydroxylation with the configurational inversion of the intermediate amidoalcohol via an oxazoline. The synthesis of (+)-epi-cytoxazone is also described.     

Total synthesis of racemic,natural (+) and unnatural (−) scorzocreticin

The first total synthesis of racemic scorzocreticin and its pure enantiomers is described from readily available 3,5-dihydroxybenzoic acid. The key steps include Wittig olefination, asymmetric Me-CBS (Corey–Bakshi–Shibata) oxazaborolidine reduction, and improved Pd-catalyzed intramolecular lactonization reactions. Both the (S)-natural and (R)-unnatural enantiomers of scorzocreticin have been synthesized in excellent enantioselectivities (>99% and 99% ee, respectively). In addition, 1,10-phenanthroline, a bidentate N-ligand was employed in palladium-catalyzed intramolecular carbonylation/lactonization reaction for the construction of 3,4-dihydroisocoumarin ring.     

Synthesis of the marine furanoditerpene (−)-marginatone

A synthesis of the marine labdane furanoditerpene (−)-marginatone 1 has been accomplished by a short sequence of reactions starting from (+)-coronarin E 5. The key step is the stereocontrolled-intramolecular electrophilic cyclisation of the (+)-dihydrocoronarin E 6, to the tetracyclic marginatane skeleton 7, which is subsequently functionalized by allylic oxidation to give 1. As (+)-coronarin E 5 was previously synthesized from (−)-sclareol 10, the herein reported preparation constitutes the first formal total synthesis of (−)-marginatone 1, by which its absolute configuration has been confirmed.     

Concise enantioselective synthesis of (−)-lasubine II

An enantioselective synthesis of the quinolizidine alkaloid (−)-lasubine II 1 is reported. Two different pathways to the key intermediate 2 are described. The first case involving a sequence of ring rearrangement metathesis (RRM), simple functional group interconversion operations, followed by a stereoselective cross metathesis (CM) and in the second case a domino ring opening-/ring closing-/cross metathesis step is involved. In both cases, following the metathesis reactions, exclusively the E-isomer was obtained. The final cyclisation towards the quinolizidine skeleton is achieved by an intramolecular Michael reaction. This concept represents the first example of a highly stereoselective RRM-CM combination in the synthesis of a natural product.     

Total synthesis of (−)-amathaspiramide F

The stereoselective total synthesis of the marine alkaloid, (−)-amathaspiramide F (1), was achieved from the α-hydroxy-α-ethynylsilane 2. The key steps involved in the synthesis were (1) the enolate Claisen rearrangement of the α-acyloxy-α-alkenylsilane for the stereoselective construction of the consecutive C5 and C9 chiral centers of 1 (erythro configuration), (2) the construction of aza-spirohemiaminal 28, and (3) dibromination during the final stage of the total synthesis. The reaction of the (Z)-α-acyloxy-α-alkenylsilane 22 possessing the Boc-homoallylglycine ester as the acyloxy group underwent stereoselective enolate Claisen rearrangement to give the desired erythro product 23. On the other hand, the reaction of the α-acyloxy-α-alkenylsilane (Z)-5 having Boc-proline gave the unexpected threo product 6. Oxidative cleavage of the vinylsilane group of 23 followed by treatment with heptamethyldisilazane as the methylamine equivalent gave aza-spirohemiaminal 28. The problematic regioselective dibromination to 28 was achieved using n-Bu₄NBrCl₂.     

Total synthesis of (+)-xyloketal D, a secondary metabolite from the mangrove fungus Xylaria sp.

(+)-Xyloketal D was prepared in a one-pot multistep domino reaction by heating optically active 5-hydroxy-4-methyl-3-methylenepentan-2-one (R) in toluene with 2,4-dihydroxyacetophenone. The absolute configuration of the natural product was confirmed by preparation of the starting enone from a lactone of established absolute configuration.