Olefins natural product synthesis

Sakaki S (2005) Theoretical Studies of C-H s-Bond Activation and Related by Transition-Metal Complexes. 12 31-78 Satoh T, see Miura M (2005) 14 1-20 Satoh T, see Miura M (2005) 14 55-84 Savoia D (2005) Progress in the Asymmetric Synthesis of 1,2-Diamines from Azomethine Compounds. 15 1-58 Schmalz HG, Gotov B, Bbttcher A (2004) Natural Product Synthesis. 7 157-180 Schmidt B, Hermanns J (2004) Olefin Metathesis Directed to Organic Synthesis Principles and Applications. 13 223-267... 

Chakraborty has described the highly diastereoselective. Barrero and his group developed an approach to functionalized six-membered rings with exocyclic olefins from a-oxygenated derivatives of geraniol. The diastereo-selectivity observed is reasonable and thus the method holds promise for natural product synthesis [105]. 

The Heck reaction, a palladium-catalyzed vinylic substitution, is conducted with olefins and organohalides or pseudohalides are frequently used as reactants [15, 16], One of the strengths of the method is that it enables the direct monofunctionalization of a vinylic carbon, which is difficult to achieve by other means. Numerous elegant transformations based on Heck chemistry have been developed in natural and non-natural product synthesis. Intermolecular reactions with cyclic and acyclic al-kenes, and intramolecular cyclization procedures, have led to the assembly of a variety of complex and sterically congested molecules. 

The [2+2]-photocycloaddition of carbonyl groups with olefins (Paterno-Buchi reaction) is one of the oldest known photochemical reactions and has become increasingly important for the synthesis of complex molecules. Existing reviews have summarized the mechanistic considerations and defined the scope and limitations of this photocycloaddition73. Although this reaction likely proceeds via initial excitation of the carbonyl compound and not the excited state of the diene, the many examples of this reaction in natural product synthesis justify inclusion in this chapter. 

Metathesis reactions are now widely used in natural product synthesis. Novel retrosynthetic analyses were developed because a carbon-carbon single bond can be formed after hydrogenation of a double bond constructed by metathesis. Although many types of metathesis are now known, the reaction is classified by olefin, enyne, and alkyne metatheses in this chapter. 

These reactions involve metallate rearrangements , migratory insertion and transition metal-catalysed vinylic substitution reactions. They also perform well in applications in natural product synthesis . Many useful synthetic possibilities arise from application of ring-closing olefin metathesis (RCM) to unsaturated homoaldol products and their derivatives by means of the Grubbs catalyst 3942 4-286 Equation 105 presents some examples. ... 

However, from the outset of this field, the limitations as well as the potentials of this cycloaddition were also apparent. For instance, the efficiency of this cycloaddition in an intermolecular manner was typically low unless strained olefins were used. Moreover, the use of unsymmetrical alkenes led to a mixture of the cyclopentenone regioisomers. Synthetic utility of this reaction is considerably expanded by the emergency of the intramolecular reaction. Schore introduced the first intramolecular version forming several rings simultaneously, which is now the most popular synthetic strategy in natural product synthesis because of its conceptual and operational simplicity. Additionally, the regiochemistry is no longer the problem in this variation. 

Keywords Asymmetric synthesis, Chiral catalysis, Mo-based catalysts, Natural product synthesis, Olefin metathesis, Recyclable catalysts, Ru-based catalysts, Supported chiral catalysts... 

Osmium-catalysed dihydroxylation of olefins is a powerful route towards enantioselective introduction of chiral centers into organic substrates [82]. Its importance is remarkable because of its common use in organic and natural product synthesis, due to its ability to introduce two vicinal functional groups into hydrocarbons with no functional groups [83]. Prof. Sharpless received the 2001 Nobel Prize in chemistry for his development of asymmetric catalytic oxidation reactions of alkenes, including his outstanding achievements in the osmium asymmetric dihydroxylation of olefins. 

Olefin metathesis has become a very important reaction in polymer chemistry and natural product synthesis [47-49]. Garber et al. have used the physical properties of dendrimers in order to improve the separation between the dendritic metathesis catalyst and products on silica gel column chromatography [50]. The Van Koten group has reported on the synthesis of different generations of carbosilane dendrimers functionalized with ruthenium metathesis catalysts [51]. 

In general, the stereoelectronic influence of substituents in [2 + 2]-photocycload-dition reactions is minor, and the preferred ground-state conformation often accounts for the formation of the major diastereoisomer. Inspection of molecular models and force field calculations provide a good picture of possible transition states leading via 1,4-biradicals to cyclobutane products. The total synthesis of (+)-guanacastepene represents another recent example for the use of stereoselective intramolecular cyclopentenone-olefin photocycloadditions in natural products synthesis [32]. 

Side differentiating effects like allylic 1,3-strain [45] are also observed leading to exo/endo isomers. This effect is particularly expressed in the reaction of compound 42. In this case, a methoxy group is involved in the corresponding steric interaction (compare transition state Q). A lower side differentiation is observed in the reaction of compounds 52 and 58. In the latter case, the allylic 1,3-strain effect is located on the olefinic side chain and the only one of the hydrogen atoms at the methylene carbon is involved in the corresponding interaction (transition state R). The 1,3-allylic strain effect was particularly important in the application of the reaction to natural product synthesis (see below) since it diminish the number of isomers. 

Schmalz HG, Gotov B, Bottcher A (2004) Natural Product Synthesis. 7 157-180 Schrock RR (1998) Olefin Metathesis by Well-Defined Complexes of Molybdenum and Tungsten. 1 1-36... 

Natural product synthesis and medicinal chemistry exist in a symbiotic relationship with the development of synthesis methodology. Noy-ori s asymmetric hydrogenations, Sharpless olefin oxidations, Grubbs olefin metathesis, Buchwald-Hartwig couplings and Jacobsen s hydrolytic kinetic resolution are illustrious examples with many practical applications. The key to the success of the above-mentioned reactions is that they have provided reliable shortcuts to more traditional synthetic... 

Because of the excellent performance of the new catalysts, many research groups use ringclosing metathesis as the key step in natural product synthesis [12]-[18]. Scheme 6 shows some examples. Via ring-closing metathesis of the olefin 37 to the hydroazulene 38, Blechert et al. [12] succeeded in synthesizing a cyclic system which is part of many sesquiterpenes. Cyclooctane derivatives, whose synthesis is the main problem in taxol synthesis, can be obtained in good yields (39 40), as demonstrated by Grubbs et al. [ 13]. 

The general area of zirconacyclopentane chemistry has been reviewed.76 Because these molecules are best viewed as zirconium or hafnium dialkyl complexes, and hence as tetravalent metal centers, this renders them beyond the scope of this review. It should be noted that these molecules display a rich reaction chemistry, serving as initiators for olefin polymerization,77-79 reagents for organic methodology,57,80-86 and key intermediates in natural product synthesis.87,88... 

Reductive Eliminations in the Synthesis of Natural Products Synthesis of (—)-Siccanin. The Julia-Lythgoe olefination provides an important tool in the total synthesis of a number of natural products.12 The reductive... 

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