Kurze Totalsynthesen von (±)-Sativen und (±)-cis-Sativendiol

Short Total Syntheses of (±)-Sativene and (±)-cis-Sativenediol Our approach to (±)-sativene (7) and (±)-cis-sdtivenediol (9) involves: (a) reaction of 3-methylbutanoyl chloride with Et₃N/cyclopentadiene to give the endo-isopropyl-ketone 1 (here improved to 71%), (b) NBS bromination of 1 to a 5:1 mixture (87%) of the bromo-ketones 2 and 3 , (c) NFD-reaction sequence initiated by the attack of 1,2-butadienyl titanate (complex of 15 , obtained from 2-butine) on 2/3 to afford 52% of the brexenone derivative 4 (along with 8% of its epimer 16 ), (d) addition of dibromomethane to 4 forming 63% of the diene-alcohol 5 (along with 13% of the diene-carbaldehyde 38 ), and (e) carbenoid ring-expansion with MeLi applied to 5 resulting in 41% the diene-ketone 6 (along with 15% of a 1:3 mixture of the diene-ketones 32 and 33 ). Wolff-Kishner reduction of 6 led to 81% of (±)-sativene (7), when enough O₂ was present, but to 97% of the diene 8 in the strict absence of O₂. (±)-cis-Sativenediol (9) was obrained (86%) by OsO₄ hydroxylation of 8 . The brexenone derivatives 4 and 16 (6:1, 50%) were also produced when the NFD-reaction sequence was applied to the isomeric bromo-ketone mixture 13/13 (1:3). The latter was obtained by NBS bromination of 10 , which in turn was available by base epimerization of 1 , followed by destructive removal of unreacted 1 by repeated gas-flow thermolysis. An analogous (less convenient) route to (±)-sativene (7) passed through a series of dihydro compounds (the ene series) it started with the methylidene-ketone 36 , which was the product (97%) of a partial hydrogenation of 4 . Addition of dibromomethane to 36 led t 62% of the methylidene-alcohol 39 (along with a little tetracyclic ether 40 ). Carbenoid ring expansion of 39 with MeLi afforded ca. 42% of the methylidene-ketone 41 (along with 7% of the methylidene-ketone 43 or, under slightly different condition, along with 9% of the methylidene-ketone 42 and 10% of the methylidene-carabaldehyde 44 ). The methylidene-alcohol 39 and the methylidene-ketone 43 were also obtained by partial hydrogenation of 5 and 33 , respectively. Wolff-Kisher reduction converted 41 into (±)-sativene ( 7 99%); the same conditons applied to 42 afforded only ca. 8% 7 (along with three other hydrocarbons, one of them (ca. 21%) probably being (±)-copacamphene (45)). In the diene series, the two succeeding reactions ( 4→5 and 5→6 ) competed with the same side reaction, a rearrangement leading to the brendene-aldehyde 38. In the ene series, the corresponding dihydro-by-product 44 was found in the reacton 39→41 , but not during 36→39. These side reactons could largely be suppressed by keeping the reaction temperature low. An explanation is proposed.     

Total Synthesis of (±)-Patriscabrol and (±)-Boschnialactone

A total synthesis of (±)-patriscabrol (1) and (±)-boschnialactone (2) is described. The cyclopentapyranone skeleton is assembled by means of Baeyer-Villiger oxidation of ketol 5.     

Total synthesis of (±)-fangchinoline

(±)-Fangchinoline was synthesized by condensation of (±)-1-(3-bromo-4-methoxy-benzyl)-2-methyl-6-methoxy-7-hydroxy-8-bromo-1,2,3,4-tetrahydroisoquinoline ( 2 ) and (±)-1-(4-hydroxy-benzyl)-2-methyl-6-methoxy-7-hydroxy-1,2,3,4-tetrahydroisoquinoline ( 3 ) in the presence of copper, pyridine and potassium carbonate.     

Studies on the syntheses of heterocyclic compounds. Part CDXCVII. Total syntheses of (±)-cryptaustoline and (±)-thaliporphine by the benzyne reaction

The indisputable benzyne reaction of 1-(5-bromo-3,4-dimethoxybenzyl)-1,2,3,4-tetrahydro-7-hydroxy-6-metlioxy-2-methylisoquinoline (II) with sodium amide in liquid ammonia afforded the following compounds, (±)-cryptaustoline iodide (VI), (±)-thaliporphine (VIII), 1 -(3,4-dimeth-oxybenzyl)- (III), and 1 -(2-amino-4,5-dimethoxybenzyl)-l,2,3,4-tetrahydro-7-hydroxy-6-meth-oxy-2-methylisoquinoline (IV).     

Total Syntheses of (±)‐Fawcettimine, (±)‐Fawcettidine, (±)‐Lycoflexine,and (±)‐Lycoposerramine‐Q

The total syntheses of four fawcettimine‐related Lycopodium alkaloids, (±)‐fawcettimine, (±)‐fawcettidine, (±)‐lycoposerramine‐Q, and (±)‐lycoflexine, were completed in a highly stereoselective manner. The Pauson–Khand reaction of 4‐methylidene‐6‐siloxyoct‐1‐en‐7‐yne followed by regio‐ and stereoselective hydrogenation led to the short‐step preparation of the bicyclo[4.3.0]nonenone intermediate bearing a methyl group with the required stereochemistry. The subsequent chemical manipulation of the bicyclic compound afforded the 6‐5‐9‐membered tricyclic dioxo compound, which was then transformed into the four targeted alkaloids in an alternative and more efficient fashion.     

Short Syntheses of (±)-Grandisol and (±) Lineatin via,a common Intermediate

A 6-step synthesis of (±)-grandisol ( 1 ) is presented, which involves dichloroketene addition to 3-methyl-3-butenyl acetate ( 4 ), reductive dechlorination of the adduct 6 to the ketone 7 and saponification to 8 , aldolization of 7 or 8 with acetone and cyclization to the bicyclic ketone 9 , Wolff-kishner, reduction to 14 , and finally ring opening to 1. Since 9 is a known intermediate of the synthesis of (±)-lineatin ( 2 ), the latter can now be obtained in 6 steps.     

Total Synthesis of (±)-3-Deoxy-7,8-dihydromorphine, (±)-4-Methoxy-N-methylmorphinan-6-one and 2,4-Dioxygenated (±)-Congeners

A total synthesis of racemic 3-deoxy-7,8-dihydromorphine ((±)- 2 ) and 4-me-thoxy-ALmethylmorphinan-6-one ((±)- 3 ) is described. The key intermediate was 2,4-dihydroxy-N-formylmorphinan-6-one (11) , obtained from 3,5-dibenzyloxy-phenylacetic acid (4) in 41.8% overall yield. Bromination of 11 , and treatment with aqueous N_aOH-solution afforded, after N-deblocking and reductive N-methylation with concomitant removal of the aromatic bounded Br-atom, the morphinanone 14. Elimination of the HO–C(2) group in 14 was accomplished by hydrogenolysis of its N-phenyltetrazolyl ether 15 , to give 3-deoxy-6,0-didehydro-7,8-dihydromorphine (16). Reduction of 16 with L-Selectride at low temperature provided (±)- 2 in high yield. The ether 15 directly afforded, under more vigorous reduction conditions, 4-hydroxy-N-methylmorphinan-6-one (17). and after O-methylation of 17 , the methyl ether (±)- 3 was obtained. A (1:l)-mixture of 4-hydroxy-2-methoxy-N-methylmor-phinan-6-one (28) and its 2-hydroxy-4-methoxy isomer 30 svere obtained by Grewe-cyclization of a mono-methoxylated aromatic precursor similar to that which afforded 11. The 2,4-dioxygenated N-methylmorphinan-6-ones 29 , 31 and 38 were also prepared and characterized.     

Formal Syntheses of (±)-Verbenalol and (±)-Udoteatrial

A formal total synthesis of (±)-verbenalol 1 and (±)-udoteatrial 2 is described. Tie key intermediate is diiodolactone 7.     

Synthese von (±)-Muscopyridin über eine C-ZIP-Ringerweiterungsreaktion

Synthesis of (±)-Muscopyridine via C-ZIP Ring Enlargement Treatment of 4-(1-nitro-2-oxocyclododec-1-yl)butanal ( 1 ) and of its methyl derivative 5 with pentylamine in EtOH at room temperature gave the ring-enlarged aminomethylidene derivatives 6 and 7 , respectively (Scheme 1). After hydrolysis of the aminomethylidene group in 6 and 7 and deformylation followed by a reductive Nef-type reaction, the macrocyclic diketones 10 and 11 , respectively, were obtained. They were transformed by a modified Hantzsch procedure to the title compound (±)-muscopyridine ( 13 ) and normuscopyridine ( 12 ), respectively.     

Vicinal Dianion of Triethyl Ethanetricarboxylate: Syntheses of (±)‐Lichesterinic Acid, (±)‐Phaseolinic Acid, (±)‐Nephromopsinic Acid, (±)‐Rocellaric Acid,and (±)‐Dihydroprotolichesterinic Acid

The vicinal dianion 2 derived from triethyl ethanetricarboxylate reacted regioselectively with aldehydes and ketones at C(β) to provide paraconic acid derivatives 5a – f in moderate to high yields as mixtures of diastereoisomers. The paraconic acid derivatives 5e and 5f were utilized as the starting materials for the syntheses of (±)‐lichesterinic acid ( 12 ), (±)‐phaseolinic acid ( 13 ), (±)‐nephromopsinic acid ( 14 ), (±)‐rocellaric acid ( 15 ), and (±)‐dihydroprotolichesterinic acid ( 16 ).     

A Stereoselective Total Synthesis of (±)-Maritimol, (±)-2-Deoxystemodinone, (±)-Stemodinone,and (±)-Stemodin

A simple and stereoselective total synthesis of (±)-maritimol ( 2d ) and its conversion into the other title compounds (±)-( 2a ), ((±)- 2b ), and ((±)- 2c ) is described. The unique bicyclo[3.2.1]octane moiety, constituting their C/D-ring system, is stereospecifically obtained by solvolytic rearrangement of the methanesulfonate 23 .     

Eine neue Synthese von (±)-Dihydrorecifeiolid

A New Synthesis of (±)-Dihydrorecifeiolide Ethyl 1-(2′-formylethyl)-2-oxocyclooctane-1-carboxylate ( 2 ) prepared by Michael reaction of ethyl 2-oxocyclooctane-1-carboxylate ( 1 ) was regioselectively methylated at the aldehyde group with (CH₃)₂Ti[OCH(CH₃)₂]₂ to give 3 (Scheme 1). The alcohol 3 was treated with Bu₄NF to give the deethoxycarbonylated product 4 which by distillation gave the bicyclic enol ether 5 . Oxidation (m-chloroperbenzoic acid) of 5 and reduction of the resulting oxolacton 6 yielded the title compound (±)-dihydrorecifeiolide ( 7 ) in an overall yield of nearly 50 %. Methylation of the aldehyde 2 with MeLi gave the ring-enlarged lacton 9 in poor yield (13 %). The deethoxycarbonylation reaction 3 → 4 was studied in more detail (Scheme 3).     

A Flexible Stereoselective Synthesis of the Spirosesquiterpenes (±)-β-Acorenol, (±)-β-Acoradiene, (±)-Acorenone-B and (±)-Acorenone via an Intramolecular Ene-Reaction

The racemic spirosesquiterpenes β-acorenol ( 1 ), β-acoradiene ( 2 ), acorenone-B ( 3 ) and acorenone ( 4 ) (Scheme 2) have been synthesized in a simple, flexible and highly stereoselective manner from the ester 5 . The key step (Schemes 3 and 4), an intramolecular thermal ene reaction of the 1,6-diene 6 , proceeded with 100% endo-selectivity to give the separable and interconvertible epimers 7a and 7b . Transformation of the ‘trans’-ester 7a to (±)- 1 and (±)- 2 via the enone 9 (Scheme 5) involved either a thermal retro-ene reaction 10 → 12 or, alternatively, an acid-catalysed elimination 11 → 13 + 14 followed by conversion to the 2-propanols 16 and 17 and their reduction with sodium in ammonia into 1 which was then dehydrated to 2 . The conversion of the ‘cis’-ester 7b to either 3 (Scheme 6) or 4 (Scheme 7) was accomplished by transforming firstly the carbethoxy group to an isopropyl group via 7b → 18 → 19 → 20 , oxidation of 20 to 21 , then alkylative 1,2-enone transposition 21 → 22 → 23 → 3 . By regioselective hydroboration and oxidation, the same precursor 20 gave a single ketone 25 which was subjected to the regioselective sulfenylation-alkylation-desulfenylation sequence 25 → 26 → 27 → 4 .     

Synthesis of Aristotelia-type alkaloids. Part VII. Syntheses of (±)-sorelline, (±)-serratenone,and (±)-aristotelin-19-one

The imine obtained by condensing indole-protected 2-(indol-3-yl)acetaldehyde ( 5 ) with the terpinylamine derivative (±)- 4 was cyclized in 51% yield to the 19-substituted hobartine derivative (±)- 20 upon exposure to anhydrous HCOOH. This pivotal intermediate was further elaborated into the indole alkaloids (±)-serratenone ((±)- 22 ) and (±)-sorelline ((±)- 29 ). In the course of these investigations, a novel rearrangement was uncovered; a Lewis acid-catalyzed 1,3-migration of an arylsulfonyl group from the indole N-atom into the benzene ring. The discovery that synthetic (±)-aristotelin-19-one ((±)- 34 ) has decidedly different spectroscopic properties than aristolasicone, a metabolite for which the structure has been recently proposed, led to a revision of the structure of the latter.     

First Total Synthesis of (±)-13-Hydroxyneocembrene

First total synthesis of (±)-13-hydroxyneocembrene ( 1 ), starting from 6-methyl-5-hepten-2-one ( 6 ) and geraniol ( 7 ), is described. The key steps are (i) the addition of sulfur-stabilized carbanion 12 to aldehyde 9 , (ii) the synthesis of 18 by using phase-transfer catalyzed coupling reaction, and (iii) low-valent titanium-induced intramolecular coupling of oxo aldehyde 3 to afford the target molecule after the final deprotection.     

New Synthetic Routes to Biologically Interesting Geranylated Flavanones and Geranylated Chalcones: First Total Synthesis of (±)‐Prostratol F,Xanthoangelol, and (±)‐Lespeol

A new and efficient synthetic approach to biologically interesting geranylated flavanones and geranylated chalcones is described. Thus, the first total syntheses of the geranylated flavanones (±)‐prostratol F ( 1 ), (±)‐8‐geranyl‐3′,4′,7‐trihydroxyflavanone ( 2 ), and (±)‐6‐geranyl‐5,7‐dihydroxy‐3′,4′‐dimethoxyflavanone ( 3 ) were carried out starting from 2,4‐dihydroxyacetophenone ( 10 ) and 2,4,6‐trihydroxyacethophenone ( 17 ) in five to six steps (Schemes 2 and 3). The geranylated chalcones xanthoangelol ( 4 ), 3‐geranyl‐2,3′,4,4′‐tetrahydroxychalcone ( 5 ), (±)‐lespeol ( 6 ), and lespeol derivatives (±)‐ 7 – 9 were synthesized starting from 2,4‐dihydroxyacetophenone ( 10 ) in three to four steps (Schemes 2 and 6).     

(±)-5′-Nor ribofuranoside carbocyclic guanosine

The synthesis of the guanine derivative (±)-2-amino-1,9-dihydro-9-[(1′α,2′β,3′β,4′α)-(2′,3′,4′-trihydroxy-1′-cyclopentyl]-6H-purin-6-one ( 2 ) is described. This compound is viewed as the carbocyclic ribofuranoside guanine nucleoside analogue lacking the 5′-methylene.     

Synthese der Spermidin-Alkaloide (±)-Inandenin-10-ol,Inandenin-10-on und (±)-Oncinotin

Syntheses of the Spermidine Alkaloids (±)-Inandenin-10-ol, Inandenin-10-one, and (±)-Oncinotine New syntheses of the title compounds using two-ring-enlargement reactions are described. Starting from the aldehyde 1 , the corresponding 4′-aza derivative 15 could be obtained by reductive amination with the appropriate and protected spermidine derivative 14 (Scheme 4). Enlargement of the carbocyclic ring in 15 by five members gave, after further transformations, the hydroxylactam 18 . Transamidation of 18 , the second ring-enlargement step, led to (±)-inandenin-10-ol (7;22.9% overall yield) and, after oxidation, to inandenin-10-one ( 8 ; 22.5%, overall yield). (±)-Oncinotine 6 was synthesized by two pathways (Scheme 6): protection of the terminal NH₂ group by treatment with the Nefkens reagent and replacement of the OH group by Cl gave 24 , which by thermal transamidation followed by direct ring closure led to the oncinotine derivative 26 . The same intermediate could be obtained in higher yield via 28 by oxidation and protection of 18 followed by transamidation and reductive ring closure. Treatment of 26 with hydrazine finally gave (±)-oncinotine 6 in 15.9% overall yield.     

An Efficient Stereoselective Synthesis of (±)-Sweroside and (±)-secologanin aglucone O-methyl ethers. Preliminary communication

A seven-step stereoselective synthesis of (±)-sweroside aglucone O-methyl ether ( 16a ) was achieved in 27% overall yield from 1, 4-cyclohexadiene ( 4 ) and methyl diformylacetate ( 5 ). Secologanin aglucone O-methyl ether ( 18a ) was then formed from 16a in 90% overall yield by a straightforward process. The key step in the synthesis was a [2+2]-enone-photoannelation of 4 and 5 to form the key intermediate 6 which possessed the desired cis-fused ring configuration, and all the caron atoms needed to complete the synthesis of 16a and 18a .     

A Total Synthesis of (±)- Aphidicolin: Regio- and stereoselective conversion of 3α,18-Di-O-benzyl-17-nor-14-aphidicolen-16-one into (±)-aphidicolin

A regio- and steroselective conversion of the totally synthetic 3α, 18-di-O-benzyl-17-nor-14-aphidicolen-16-one (5), into (±)-aphidicolin 1 , by hydroxylation of the 2-methylidenebicyclo[3.2.1] oct-3-ene derivative 6 is described. Compound 5 was a key intermediate in our previously described total synthesis of 2 , which represented a formal synthesis of 1 .