Natural products enantioselective Michael addition

Scheme 2.15 Enantioselective Michael addition of aldehydes with functionalized nitroalkenes and an application to the total synthesis of densely functionalized homoprolines and natural product (-)-botryodipIodin.

A diastereo- and enantioselective Michael addition combined with a Darzens condensation reaction can be used to form two products of interest in the field of medicinal and natural products chemistry [60]. Additionally, depending on the workup conditions, an optically active epoxycyclohexanone, 92, can be prepared through an Sf 2 reaction, or the ElcB reaction pathway to 91 can be accessed (Scheme 7.17). In the early stages of the proposed mechanism, a planar iminium ion is suggested between the 2-[bis(3,5-bistrifluoromethylphenyl) trimethylsilany-loxymethyljpyrrolidine 61 and the aldehyde moiety of compound 88, which is subsequently attacked by the P-ketoester 89. For the synthesis of the epoxide, a... 

With the use of chiral reagents a differentiation of enantiotopic faces is possible, leading to an enantioselective reaction. The stereoselective version of the Michael addition reaction can be a useful tool in organic synthesis, for instance in the synthesis of natural products. 

In a recently published report by MacMillan s group [121] on the enantioselective synthesis of pyrroloindoline and furanoindoline natural products such as (-)-flustramine B 2-219 [122], enantiopure amines 2-215 were used as organocatalysts to promote a domino Michael addition/cyclization sequence (Scheme 2.51). As substrates, the substituted tryptamine 2-214 and a, 3-unsaturated aldehydes were used. Reaction of 2-214 and acrolein in the presence of 2-215 probably leads to the intermediate 2-216, which cyclizes to give the pyrroloindole moiety 2-217 with subsequent hydrolysis of the enamine moiety and reconstitution of the imidazolid-inone catalyst. After reduction of the aldehyde functionality in 2-217 with NaBH4 the flustramine precursor 2-218 was isolated in very good 90 % ee and 78 % yield. 

The potential application of this catalytic system was illustrated by Takemoto in the application to a tandem conjugate addition towards the asymmetric synthesis of (-)-epibatidine, a biologically active natural product [100, 101], The authors designed an enantioselective double Michael addition of an unsaturated functionalized P-ketoester to a p-aryl nitro-olefm. The asymmetric synthesis of the 4-nitro-cyclohexanones was achieved in both high diastereoselectivity and enantioselectivity, with the natural product precursor synthesized in 90% yield and 87.5 12.5 er (Scheme 49). The target (-)-epibatidine was subsequently achieved in six steps. 

It is interesting to note that the oxa-analogous Michael addition was reported for the first time in 1878 by Loydl et al. [19] in their work on the synthesis of artificial malic acid, which was five years ahead of the discovery of the actual Michael reaction described first by Komnenos [20], Claisen [21], and later Michael in 1887 [22] as one of the most important methods for C—C bond formation. In continuation of the early work on the oxa-Michael addition [23], the inter- and intramolecular additions of alkoxides to enantiopure Michael acceptors has been investigated, leading to the diastereo- and enantioselective synthesis of the corresponding Michael adducts [24]. The intramolecular reaction has often been used as a key step in natural product synthesis, for example as by Nicolaou et al. in the synthesis of Brevetoxin B in 1989 [25]. The addition of oxygen nucleophiles to nitro-alkenes was described by Barrett et al. [26], Kamimura et al. [27], and Brade and Vasella [28]. 

The Aspidosperma family of indole alkaloids has inspired many synthetic strategies for the construction of their pentacyclic framework of the parent compound aspidospermidine (366), since the initial clinical success of two derivatives, vinblastine (10) and vincristine, as anticancer agents. The alkaloids such as (-)-rhazinal (369) and (-)-rhazinilam (6) have been identified as novel leads for the development of new generation anticancer agents [10,11]. Bis-lactams (-)-leucunolam (370) and (-t-)-epi-leucunolam (371) have bio-genetic and structural relationships with these compounds [236]. Recently, enantioselective or racemic total syntheses of some of the these natural product were achieved. One successful synthesis was the preparation of the tricyclic ketone 365, an advanced intermediate in the synthesis of aspidospermidine (366), from pyrrole (1) (Scheme 76) [14]. The key step is the construction of the indolizidine 360, which represents the first example of the equivalent intramolecular Michael addition process [14,237,238]. The DIBAL-H mediated reduction product was subject to mesylation under the Crossland-... 

The indole and pyrrole rings are incorporated into many biologically active molecules. Therefore, the functionalization of indole and pyrrole cores via Michael-type additions has been discussed. This chapter especially focuses on studies of the last 10 years on catalyst systems, enantioselective synthesis and the design of natural products or biological active molecules as related to Michael additions of indole and pyrrole. 

The first enantioselective total synthesis of tetracyclic sesquiterpenoid (+)-cyclomyltaylan-5a-ol, isolated from a Taiwanese liverwort, was accomplished by H. Hagiwara and co-workers. They started out from Hajos-Parrish ketone analogue, (S)-(+)-4,7a-dimethyl-2,3,7,7a-tetrahydro-6/-/-indene-1,5-dione, that could be synthesized from 2-methylcyclopentane-1,3-dione and ethyl vinyl ketone in an acetic acid-catalyzed Michael addition followed by an intramolecular aldol reaction. The intramolecular aldol reaction was carried out in the presence of one equivalent (S)-(-)-phenylalanine and 0.5 equivalent D-camphorsulfonic acid. The resulting enone was recrystallized from hexane-diethyl ether to yield the product in 43% yield and 98% ee. Since the absolute stereochemistry of the natural product was unknown, the total synthesis also served to establish the absolute stereochemistry. 

On the basis of the above mechanistic assumption, the authors assumed that the p-ICD-amide-p-naphthol dual catalytic system should favor the (5)-aza-MBH product regardless of the nature of the Michael acceptors used and investigated the reaction between A -tosylimine 158 and alkyl vinyl ketone, which is known to provide the (i )-aza-MBH adduct. They developed a new p-ICD-amide (160) and found that an achiral protic additive was capable of inverting the p-ICD and p-ICD-amide (160) catalyzed enantioselective aza-MBH reaction between A -sulfonylimines and MVK/EVK, therefore providing another solution to the enantio-complementarity associated with this family of catalysts (Scheme 2.77). °... 

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