Biomimetic synthesis
Biomimetic synthesis is an area of organic chemical synthesis that is specifically biologically inspired, so-named in 1917 by the English organic chemist and Nobel laureate Sir Robert Robinson.[1] The term encompasses both the testing of a "biogenetic hypothesis" (conjectured course of a biosynthesis in nature) through execution of a series of reactions designed to parallel the proposed biosynthesis, as well as programs of study where a synthetic reaction or reactions aimed at a desired synthetic goal are designed to mimic a one or more known enzymic transformations of an established biosynthetic pathway.[2][3] The earliest generally cited example of a biomimetic synthesis is Robinson's organic synthesis of the alkaloid tropinone.[1]
A more recent example is E.J. Corey's carbenium-mediated cyclization of an engineered linear polyene to provide a tetracyclic steroid ring system,[4] which built upon studies of cationic cyclizations of linear polyenes by the Albert Eschenmoser and Gilbert Stork,[5][6] and the extensive studies of the W.S. Johnson to define the requirements to initiate and terminate the cyclization, and to stabilize the cationic carbenium group during the cyclization (as nature accomplishes via enzymes during biosynthesis of steroids such as cholesterol).[7] In relation to the second definition, synthetic organic or inorganic catalysts applied to accomplish a chemical transformation accomplished in nature by a biocatalyst (e.g., a purely proteinaceous catalyst, a metal or other cofactor bound to an enzyme, or a ribozyme) can be said to be accomplishing a biomimetic synthesis, where design and characterization of such catalytic systems has been termed biomimetic chemistry.[8][9][10]
Contents
Synthesis of Protodaphniphylline
Proto-Daphniphylline is a precursor in the biosynthesis of a family of alkaloids found in Daphniphyllum macropodum. It is of interest due to its complex molecular structure making it a challenging target for conventional organic synthesis methods due to the fused ring structure and the spiro carbon centre. Based on a proposed biosynthesis pathway of proto-daphniphylline from squalene, Clayton Heathcock and co-workers developed a remarkably elegant and short total synthesis of proto-Daphniphylline from simple starting materials.[11] This is a classic example of how biomimetic synthesis dramatically simplifies traditional total synthesis towards complex natural products.
The key step in Heathcock’s synthetic route involves a cyclization of acyclic dialdehydes A or B to form proto-daphniphylline. Both dialdehydes (A or B) have carbon skeletons analogous to squalene and can be synthesized from simple starting materials. Treating A or B with a sequence of simple reagents containing potassium hydroxide, ammonia, and acetic acid led to the formation of proto-daphniphylline. Six σ-bonds and five rings were formed in this remarkable step. It was proposed in the original report that hydroxyldihydropyran intermediate C was first formed when the dialdehyde starting material (A) was treated with potassium hydroxide. A 2-aza-1, 3-diene intermediate (D) was generated from the reaction of intermediate C with ammonia. An acid-catalyzed Diels-Alder reaction formed intermediate E which was further converted to the final product under the reaction conditions.
Examples of biomimetic syntheses in Wikipedia
- carpanone, via the Chapman approach
- spirotryprostatin B, via the Ganesan approach
- endiandric acid, see Biomimetic Total synthesis, via Nicolaou approach
Further literature examples of biomimetic syntheses
- Merck synthesis of nakiterpiosin-type C-nor-D-homosteroids, e.g., Structural: Cleaved, contracted, and expanded rings (seco-, nor-, and homosteroids), via C-13 atom migration[12]
- Heathcock synthesis of squalene-derived daphniphylline-type alkaloids, e.g., Daphniphyllum, via tetra/pentacyclization cascades[13][14]
Further reading
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- Biomimetic Synthesis reporting and meet-up page at Facebook, see [6].
References
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- ↑ Ronald Breslow, 2008, Biomimetic Chemistry: Biology as an Inspiration, J. Biol. Chem. 284:1337-1342, DOI: 10.1074/jbc.X800011200, see [1], accessed 3 June 2014.
- ↑ Sonny C. Lee & Richard H. Holm, 2003, Speculative synthetic chemistry and the nitrogenase problem, Proc. Natl. Acad. Sci. U.S.A. 100(7):3595-3600, DOI:10.1073/pnas.0630028100, see [2], accessed 3 June 2014.
- ↑ Ronald Breslow, 1995, Biomimetic chemistry and artificial enzymes: Catalysis by design. Acc. Chem. Res. 28:146–153
- ↑ Piettre, S.; Heathcock, C. H. Science, 1990, 248, 1532
- ↑ Shuanhu Gao & Chio Chen, 2012, "Nakiterpiosin", in Total Synthesis of Natural Products: At the Frontiers of Organic Chemistry (Jie Jack Li & E.J. Corey, eds.), Berlin:Springer, pp. 25-38, esp. 25-28, e.g., [3], accessed 20 May 2014.
- ↑ Clayton H. Heathcock, Marvin M. Hansen, Roger B. Ruggeri & John C. Kath, 1992, "Daphniphyllum alkaloids. 11. Biomimetic total synthesis of methyl homosecodaphniphyllate. Development of the tetracyclization reaction", J. Org. Chem., 1992, 57 (9), pp 2544–2553, DOI: 10.1021/jo00035a008, e.g., [4], accessed 5 June 2014.
- ↑ Clayton H. Heathcock, Serge Piettre, Roger B. Ruggeri, John A. Ragan & John C. Kath, 1992, "Daphniphyllum alkaloids. 12. A proposed biosynthesis of the pentacylic skeleton. proto-Daphniphylline", J. Org. Chem., 1992, 57 (9), pp 2554–2566, DOI: 10.1021/jo00035a009, e.g., [5], accessed 5 June 2014.
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