Carpanone is a naturally occurring lignan-type

natural product A natural product is a natural compound or substance produced by a living organism—that is, found in nature. In the broadest sense, natural products include any substance produced by life. Natural products can also be prepared by chemical syn ...

most widely known for the remarkably complex way nature prepares it, and the similarly remarkable success that an early chemistry group, that of Orville L. Chapman, had at mimicking nature's pathway.C.W. Lindsley, C.R. Hopkins & G.A. Sulikowski, 2011, Biomimetic synthesis of lignans, In "Biomimetic Organic Synthesis" (E. Poupon & B. Nay, Eds.), Weinheim: Wiley-VCH, , se

accessed 4 June 2014.O.L. Chapman, M.R. Engel, J.P. Springer & J.C. Clardy, 1971, Total synthesis of carpanone, ''J. Am. Chem. Soc.'' 93:6697–6698. Carpanone is an organic compound first isolated from the carpano trees (''Cinnamomum sp.'') of

Bougainville Island Bougainville Island (Tok Pisin: ''Bogenvil'') is the main island of the Autonomous Region of Bougainville, which is part of Papua New Guinea. It was previously the main landmass in the German Empire-associated North Solomons. Its land area is ...

by Brophy and coworkers, trees from which the

derives its name.F. Liron, F. Fontana, J.-O. Zirimwabagabo, G. Prestat, J. Rajabi, C. La Rosa & G. Poli, 2009, A New Cross-Coupling-Based Synthesis of Carpanone, Org. Lett., 11(19):4378–4381, DOI: 10.1021/ol9017326, see o

accessed 4 June 2014 The hexacyclic lignan is one of a class of related diastereomers isolated from carpano bark as mixtures of equal proportion of the "handedness" of its components (i.e.,

racemic mixture In chemistry, a racemic mixture, or racemate (), is one that has equal amounts of left- and right-handed enantiomers of a chiral molecule or salt. Racemic mixtures are rare in nature, but many compounds are produced industrially as racemates. ...

s), and is notable in its stereochemical complexity, because it contains five contiguous stereogenic centers. The route by which this complex structure is achieved through

biosynthesis Biosynthesis is a multi-step, enzyme-catalyzed process where substrates are converted into more complex products in living organisms. In biosynthesis, simple compounds are modified, converted into other compounds, or joined to form macromolecules. ...

involves a series of reactions that, almost instantly, take a molecule with little three-dimensionality to the complex final structure. Notably, Brophy and coworkers isolated the simpler carpacin, a

phenylpropanoid The phenylpropanoids are a diverse family of organic compounds that are synthesized by plants from the amino acids phenylalanine and tyrosine. Their name is derived from the six-carbon, aromatic phenyl group and the three-carbon propene tail of ...

with a 9-carbon framework, recognized its substructure as being dimerized within the complex carpanone structure, and proposed a hypothesis of how carpacin was converted to carpanone in plant cells: * carpacin underwent loss of a methyl (-CH₃) group from the ring methoxy (-OCH₃) group to provide the phenol,

desmethyl In chemical nomenclature, nor- is a prefix to name a structural analog that can be derived from a parent compound by the removal of one carbon atom along with the accompanying hydrogen atoms. The nor-compound can be derived by removal of a , , or ...

carpacin, * this phenol intermediate then underwent a phenolic coupling to generate a dimeric intermediate, which was * followed immediately by a Diels-Alder (4+2) cycloaddition reaction to create 2 new rings, to give the final carpanone product. Remarkably, within two years, Chapman and coworkers were able to chemically design a route to mimic this proposed biosynthetic route, and achieved the synthesis of carpanone from carpacin in a single "pot", in about 50% yield. Carpanone itself is limited in its pharmacologic and biologic activities, but related analogs arrived at by variations of the Brophy-Chapman approach have shown activities as tool compounds relevant to mammalian exocytosis and vesicular traffic,Brian C. Goess, Rami N. Hannoush, Lawrence K. Chan, Tomas Kirchhausen, and Matthew D. Shair, 2006, Synthesis of a 10,000-Membered Library of Molecules Resembling Carpanone and Discovery of Vesicular Traffic Inhibitors, ''J. Am. Chem. Soc.'' 128(16): 5391–5403, DOI: 10.1021/ja056338g, se

accessed 4 June 2014. and provided therapeutic hit to lead, "hits" in antiinfective, antihypertensive, and hepatoprotective areas. The original Chapman design and synthesis is considered a classic in total synthesis, and one that highlights the power of biomimetic synthesis.

Total synthesis

The first total synthesis of carpanone was the biomimetic approach published by Chapman ''et al.'' in 1971. The required desmethylcarpacin (2-

allyl In organic chemistry, an allyl group is a substituent with the structural formula , where R is the rest of the molecule. It consists of a methylene bridge () attached to a vinyl group (). The name is derived from the scientific name for garlic, ...

sesamol Sesamol is a natural organic compound which is a component of sesame seeds and sesame oil, with anti- inflammatory, antioxidant, antidepressant and neuroprotective properties. It is a white crystalline solid that is a derivative of phenol. It i ...

), shown below as the starting molecule in the scheme, is acquired in two high-yield steps involving three transformations: * allylation of the phenolic anion generated after treatment of

with potassium carbonate and allyl bromide, * followed by a thermal Claisen rearrangement to move the O-allyl group onto the adjacent site on the aromatic ring, and then * thermal isomerization of the Claisen product, to move the terminal olefin ( alkene) into conjugation with the ring (with e.g., potassium ''tert''-butoxide as base). This procedure is one of several that gives the required

carpacin (carpacin with the methyl of its methoxy group removed). Though oxidative dimerizations of phenols normally used a 1-electron oxidant, Chapman then followed a precedent involving a 2-electron oxidant and treated desmethylcarpacin with PdCl₂ in the presence of sodium acetate (e.g., dissolved in a mixture of methanol and water); the reaction was perceived to proceed via a complexation of a pair of carpacins to the Pd(II) metal via their phenolic anions (as shown in scheme, below right), followed by a classic 8-8' (β-β') oxidative phenolic coupling of the two olefin tails—shown crossing in the image—to give a dimeric ''trans''-''ortho''- quinone methide-type of lignan intermediate. A particular conformation of this dimer then places a 4-electron enone of one ring over the 2-electron enol of the other (shown adjacent in image for clarity), setting the state for a variant of the Diels-Alder reaction termed an inverse demand Diels-Alder reaction (see curved arrows in image), which closes the 2 new rings and generates the 5 contiguous stereocenters. The carpanone is produced in yields of ≈50% by the original method, and in yields >90% in modern variants (see below). The synthesis of a single diastereomer was confirmed in the original Chapman work, using X-ray crystallography. For the elegance of its "one-pot construction of a tetracyclic scaffold with complete stereocontrol of five contiguous stereo centers", the original Chapman design and synthesis is " w considered a classic in total synthesis" that "highlights the power of biomimetic synthesis".

Extensions of the system

The Chapman approach has been applied in a variety of ways since its original report, varying substrates, oxidants, and other aspects (and so synthesis of carpanone has subsequently been achieved by "quite a few research groups"); the actual mechanism of Pd(II) action is likely more complex than the original conjecture, and there is evidence that the mechanism, broadly speaking, depends on actual conditions (specific substrate, oxidant, etc.). Various groups, including the laboratories of Steve Ley, Craig Lindley, and Matthew Shair, have succeeded in extending the Chapman method to ''solid-supported synthesis'', i.e., phenolic starting materials on polymeric supports, thus allowing the generation of libraries of carpanone analogs. A hetero-8-8' oxidative coupling system akin to the Chapman approach has been developed that uses IPh(OAC)₂, and that allows for preparation of more electron rich homodimers, and for hetero-tetracyclic analogs of carpanone.C.W. Lindsley, L.K. Chan, B.C. Goess, R. Joseph & M.D. Shair, 2001, Solid-phase biomimetic synthesis of carpanone-like molecules, J. Am. Chem. Soc. 122, 422–423.

References and notes

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Total synthesis

Extensions of the system

References and notes

Further reading