Synthetic strategies directed to the antitumour alkaloids sesbanimide A and manzamine A

Synthons derived from nature's chiral pool have been utilized in developing strategies aimed at the syntheses of the alkaloids sesbanimide A and manzamine A. The route designed for sesbanimide A has provided the naturally occurring alkaloid and a facile access to several analogues for structure-activity relationship studies. The approach to the synthesis of manzamine A has led to a strategically functionalized chiral tricyclic intermediate possessing the absolute stereochemistry of the natural product. Recent results on the synthesis of sesbanimide analogues and the progress towards the total synthesis of manzamine A is described.     

Neuritogenic activity-guided isolation of a free base form manzamine A from a marine sponge, Acanthostrongylophora aff. ingens (Thiele, 1899)

Two manzamine-class alkaloids, manzamine A (1) and 8-hydroxymanzamine (2) were isolated from a Japanese marine sponge Acanthostrongylophora aff. ingens, together with three known alkaloids manzamine E (3), manzamine F (4), and manzamine X (5). The spectral features of 1 and 2 were different from the reported data. Detailed structure analysis using 2D NMR revealed the structure of 1 and 2 as a free base form of hydrochloric salt. These manzamine-class alkaloids showed neuritogenic activity against Neuro 2a cells.     

Enantioselective total synthesis of marine alkaloids,manzamine A and related compounds

A review of our studies toward the enantioselective total synthesis of ircinal A, manzamine A and related compounds is presented in detail.     

Highly diastereoselective approach toward (+/-)-tetraponerine T6 and analogues via the double cycloisomerization-reduction of bis-alkynylpyrimidines

A new, short, and efficient approach toward tricyclic alkaloids, involving the double cycloisomerization-reduction of bis-alkynylpyrimidines 3a-m, has been developed. The requisite bis-alkynylpyrimidines 3a-m were readily prepared via regioselective sequential Sonogashira coupling reactions of dibromopyrimidines 1. Bis-alkynylpyrimidines 3a-m were converted into the 5-6-5 tricyclic heteroaromatic cores 4a-m via the Cu(I)-assisted double cycloisomerization reaction. The reaction proceeded stepwise, which was confirmed by the isolation of the mono-pyrrolization intermediate 5. The structure of 5 was assigned by 2D NMR and by independent synthesis. Cycloisomerization of 5 under standard conditions afforded tricyclic 4g in 89% yield. The PtO2-catalyzed hydrogenation of bis-pyrrolopyrimidines 4d, 4g, and 4i in acidic media afforded stable amidinium derivatives, 11a, 11b, and 11c. Further reduction of the latter with LiAlH4 allowed for the highly diastereoselective total synthesis of (+/-)-tetraponerine T6 and its analogues.     

Applications of vinylogous Mannich reactions. Total syntheses of the Ergot alkaloids rugulovasines A and B and setoclavine.

Concise syntheses of the Ergot alkaloids rugulovasine A (3a), rugulovasine B (3b), and setoclavine (2) have been completed by strategies that feature inter- and intramolecular vinylogous Mannich reactions as the key steps. Thus, the first synthesis of 3a,b commenced with the conversion of the known indole 17 into 24 via the addition of the furan 22 to the iminium ion 21, which was generated in situ from the aldehyde 19. Cyclization of 24 by a novel S(RN)1 reaction followed by removal of the N-benzyl group furnished a mixture (1:2) of 3a and 3b. In an alternative approach to these alkaloids, the biaryl 35 was reduced with DIBAL-H to give an intermediate imine that underwent spontaneous cyclization via an intramolecular vinylogous Mannich addition to provide 36a,b. N-Methylation of the derived benzyl carbamates 37a,b followed by global deprotection gave a mixture (2:1) of rugulovasines A and B (3a,b). Setoclavine (2) was then prepared from the biaryl 41 using a closely related intramolecular vinylogous Mannich reaction to furnish the spirocyclic lactones 42a,b. These lactones were subsequently transformed by hydride reduction and reductive methylation into the ergoline derivatives 43a,b, which were in turn converted into 2 by deprotection and solvolytic 1,3-rearrangement of the allylic hydroxyl group.     

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.     

Divergent Total Synthesis of the Tricyclic Marine Alkaloids Lepadiformine,Fasicularin, and Isomers of Polycitorols by Reagent‐Controlled Diastereoselective Reductive Amination

We describe a flexible and divergent route to the pyrrolo‐/pyrido[1,2‐j]quinoline frameworks of tricyclic marine alkaloids via a common intermediate formed by the ester–enolate Claisen rearrangement of a cyclic amino acid allylic ester. We have synthesized the proposed structure of polycitorols and demonstrated that the structure of these alkaloids requires revision. In addition to asymmetric formal syntheses, stereoselective and concise total syntheses of (?)‐lepadiformine and (?)‐fasicularin were also accomplished from simple, commercially available starting materials in a completely substrate‐controlled manner. The key step in these total syntheses was the reagent‐dependent stereoselective reductive amination of the common intermediate to yield either indolizidines 55 a or 55 b . Aziridinium‐mediated carbon homologation of the hindered C‐10 group to the homoallylic group facilitated the synthesis.     

From a biogenetic scenario to a synthesis of the ABC ring of manzamine A

On the basis of a biogenetic proposal for explaining the biogenesis of manzamine A, the cycloaddition of dihydropyridinium salt 26 with diene derivative 5 leads to adducts 27. These adducts, as well as their related and previously described analogues 9, are now shown to be precursors of diene derivatives such as 10, 13, and 28. Treatment of diene 32 with sodium azide resulted in a one-step formation of the tricyclic imino derivative 34. This key intermediate was further transformed into tricyclic derivative 40, which possesses the essential features of the ABC ring of manzamine A.     

A divergent approach for the total syntheses of cernuane-type and quinolizidine-type Lycopodium alkaloids

The divergent total syntheses of cernuane-type and quinolizidine-type Lycopodium alkaloids are described. A common intermediate 5 for the two types of alkaloids was assembled practically from (+)-citronellal via organocatalytic α-amination, followed by the construction of oxazolidinone that was used for diastereoselective allylation. Key compound 5 was converted into cermizine C (3), and this in turn was converted into senepodine G (4) by the regioselective Polonovsky-Potier reaction. The total synthesis of representative cernuane-type alkaloids, (−)-cernuine (1) as well as (+)-cermizine D (2), was also accomplished from 5 by utilizing asymmetric transfer aminoallylation as a key step.     

Biomimetic entry to the sarpagan family of indole alkaloids: total synthesis of +-geissoschizine and +-N-methylvellosimine

A concise synthesis of (+)-geissoschizine (1), a biosynthetic precursor of a variety of monoterpenoid indole alkaloids, from d-tryptophan (19) was performed as a critical prelude to achieving the first biomimetic, enantioselective synthesis of the sarpagine alkaloid (+)-N(a)-methylvellosimine (5). The approach to (+)-geissoschizine was designed to address the dual problems of stereocontrolled formation of the E-ethylidene moiety and the correct relative configuration at C(3) and C(15). Key steps in the synthesis involve a vinylogous Mannich reaction to prepare the carboline 22, which has the absolute stereochemistry at C(3) corresponding to that in 1 and 5, and an intramolecular Michael addition that leads to the tetracyclic corynantheane derivative 24, which possesses the correct stereochemical relationship between C(3) and C(15). Compound 24 was then transformed into 27, the pivotal intermediate in the syntheses of 1 and 5, by a sequence that allowed the stereospecific introduction of the E-ethylidene moiety. Selective reduction of the lactam in 27 followed by removal of the C(5) carboxyl group by radical decarbonylation gave deformylgeissoschizine (2) that was converted into (+)-geissoschizine (1) by formylation. The common intermediate 27 was then converted via a straightforward sequence of reactions into the alpha-amino nitrile 39. The derived silyl enol ether 40 underwent ionization upon exposure to BF(3).OEt(2) to give the intermediate iminium ion 41 that then cyclized in a biomimetically inspired intramolecular Mannich reaction to deliver (+)-N(a)-methylvellosimine (5). This transformation provides experimental support for the involvement of such a cyclization as one of the key steps in the biosynthesis of the sarpagine and ajmaline alkaloids.     

Total syntheses of the Securinega alkaloids (+)-14,15-dihydronorsecurinine, (-)-norsecurinine, and phyllanthine

A new strategy for enantiospecific construction of the Securinega alkaloids has been developed and applied in total syntheses of (+)-14,15-dihydronorsecurinine (8), (-)-norsecurinine (6), and phyllanthine (2). The B-ring and C7 absolute stereochemistry of these biologically active alkaloids originated from trans-4-hydroxy-L-proline (10), which was converted to ketonitrile 13 via a high-yielding eight-step sequence. Treatment of this ketonitrile with SmI2 afforded the 6-azabicyclo[3.2.1]octane B/C-ring system 14, which is a key advanced intermediate for all three synthetic targets. Annulation of the A-ring of (-)-norsecurinine (6) with the required C2 configuration via an N-acyliminium ion alkylation was accomplished using radical-based amide oxidation methodology developed in these laboratories as a key step, providing tricycle 33. Annulation of the D-ring onto alpha-hydroxyketone 33 with the Bestmann ylide 45 at 12 kbar gave (+)-14,15-dihydronorsecurinine (8). In the securinine series, the D-ring was incorporated using an intramolecular Wadsworth-Horner-Emmons olefination of phenylselenylated alpha-hydroxyketone 47. The C14,15 unsaturation was installed late in the synthesis by an oxidative elimination of the selenoxide derived from tetracyclic butenolide 50 to give (-)-norsecurinine (6). The A-ring of phyllanthine (2) was formed from hydroxyketone 14 using a stereoselective Yb(OTf)3-promoted hetero Diels-Alder reaction of the derived imine 34 with Danishefsky's diene, affording adduct 35. Conjugate reduction and stereoselective equatorial ketone reduction of vinylogous amide 35 provided tricyclic intermediate 36, which could then be elaborated in a few steps to stable hydroxyenone 53 via alpha-selenophenylenone intermediate 52. The D-ring was then constructed, again using an intramolecular Wadsworth-Horner-Emmons olefination reaction to give phyllanthine (2).     

Stereoselective total syntheses of three Lycopodium alkaloids, (-)-magellanine, (+)-magellaninone, and (+)-paniculatine, based on two Pauson-Khand reactions

The total syntheses of (-)-magellanine, (+)-magellaninone, and (+)-paniculatine were completed from diethyl l-tartrate via the common intermediate in a stereoselective manner. The crucial steps in these syntheses involved two intramolecular Pauson-Khand reactions of enynes: the first Pauson-Khand reaction constructed the bicyclo[4.3.0] carbon framework, the corresponding A and B rings of these alkaloids in a highly stereoselective manner, whereas the second Pauson-Khand reaction stereoselectively produced the bicyclo[3.3.0]skeleton, which could be converted into the C and D rings of the target natural products.     

Total Syntheses of (+)‐Grandilodine C and (+)‐Lapidilectine B and Determination of their Absolute Stereochemistry

Enantioselective total syntheses of the Kopsia alkaloids (+)‐grandilodine C and (+)‐lapidilectine B were accomplished. A key intermediate, spirodiketone, was synthesized in 3 steps and converted into the chiral enone by enantioselective deprotonation followed by oxidation with up to 76 % ee. Lactone formation was achieved through stereoselective vinylation followed by allylation and ozonolysis. The total synthesis of (+)‐grandilodine C was achieved by palladium‐catalyzed intramolecular allylic amination and ring‐closing metathesis to give 8‐ and 5‐membered heterocycles, respectively. Selective reduction of a lactam carbonyl gave (+)‐lapidilectine B. The absolute stereochemistry of both natural products was thereby confirmed. These syntheses enable the scalable preparation of the above alkaloids for biological studies.     

Divergent Total Syntheses of Lyconadins A and C

Divergent and concise total syntheses of two lycopodium alkaloids, lyconadins A and C have been developed. The synthesis of lyconadin A, having potent neurotrophic activity, features an efficient one‐pot ketal removal and formal aza‐[4+2] cyclization to form the cagelike core structure. A tandem ketal removal/Mannich reaction was developed to build the tricyclic structure of lyconadin C. Both lyconadins A and C were synthesized from a pivotal intermediate.     

The total synthesis of alkaloids (-)-histrionicotoxin 259A, 285C and 285E

The first total syntheses of three "unsymmetrical" (i.e. different terminal groups in the side chains) members of the histrionicotoxin family of alkaloids have been accomplished via stepwise introduction of the two side chain moieties onto a common tricyclic core.     

Synthesis of the tricyclic indole alkaloids,dilemmaones A and B

Dilemmaones A-C are naturally occurring tricyclic indole alkaloids possessing a unique hydroxymethylene or methoxymethylene substituent at the C2 position of the indole core and a C6–C7 fused cyclopentanone. Dilemmaone B has been prepared in 5 steps from 5-methylindan-1-one, and dilemmaone A has been prepared in 3 steps from a common precursor, 6-bromo-5-methyl-7-nitroindan-1-one. In both syntheses, key steps include a Kosugi-Migita-Stille cross coupling and a reductive cyclization using hydrogen gas and a transition metal catalyst.     

Total Syntheses of Daphenylline,Daphnipaxianine A,and Himalenine D

We report the total syntheses of daphenylline ( 1 ), daphnipaxianine A ( 5 ), and himalenine D ( 6 ), three Daphniphyllum alkaloids from the calyciphylline A subfamily. A pentacyclic triketone was prepared by using atom‐transfer radical cyclization and the Lu [3+2] cycloaddition as key steps. Inspired by the proposed biosynthetic relationship between 1 and another calyciphylline A type alkaloid, we developed a ring‐expansion/aromatization/aldol cascade to construct the tetrasubstituted benzene moiety of 1 . The versatile triketone intermediate was also elaborated into 5 and 6 through a C=C bond migration/aldol cyclization approach.     

Collective Total Synthesis of 4-Azafluorenone Alkaloids

4-Azafluorenones are typically obtained by acid-mediated cyclization of 2-arylnicotinates. However, this approach fails to give 5-oxygenated 4-azafluorenones due to lactonization of 2-(2-alkoxy)phenylnicotinate intermediates. Herein, we report two modifications of established approaches to 4-azafluorenone synthesis that, either in combination or by themselves, enable the flexible preparation of 4-azafluorenones with diverse oxygenation patterns in the benzenoid ring. Undesired lactonization was circumvented via tert-butyl hydroperoxide (TBHP)-mediated radical cyclization of 2-aryl-3-(hydroxymethyl)pyridines. In the absence of suitable protecting groups for phenolic intermediates, bromide substituents were regioselectively introduced as latent hydroxy groups and later converted under palladium catalysis. We present the first total syntheses of five 4-azafluorenone alkaloids muniranine, darienine, 5,8-dimethoxy-7-hydroxyonychine, 5,6,7,8-tetramethoxyonychine, and 6,8-dihydroxy-7-methoxyonychine in addition to new total syntheses of six 4-azafluorenone alkaloids and one related pyridocoumarin alkaloid.     

Asymmetric synthesis of (-)-indolizidines 167B and 209D based on stereocontrolled allylation of a chiral tricyclic N-acyl-N,O-acetal

[reaction: see text] The tricyclic N-acyl-N,O-acetal incorporating (S)-2-(1-aminoethyl)phenol as a chiral auxiliary underwent TiCl4-mediated allylation to give the chiral (5S)-allylpyrrolidinone with retention of configuration in high yield and diastereoselectivity. On the bases of this methodology, the asymmetric syntheses of the dendrobatid alkaloids (-)-indolizidines 167B and 209D were achieved.     

A Cascade Strategy Enables a Total Synthesis of (±)‐Morphine

Morphine has been a target for synthetic chemists since Robinson proposed its correct structure in 1925, resulting in a large number of total syntheses of morphine alkaloids. Here we report a total synthesis of (±)‐morphine that employs two key strategic cyclizations: 1) a diastereoselective light‐mediated cyclization of an O‐arylated butyrolactone to form a tricyclic cis‐fused benzofuran and 2) a cascade ene–yne–ene ring closing metathesis to forge the tetracyclic morphine core. This approach enables a short and stereoselective synthesis of morphine in an overall yield of 6.6 %.