Proline catalysis asymmetric

The Rediscoveiy of Proline Catalysis Asymmetric Aldol Reactions... 

Aminocatalysis is a biomimetic strategy used by enzymes such as class I aldolases. Application of aminocatalysis in an asymmetric aldol reaction was reported in the early 1970s. Proline (19) efficiently promoted an intramolecular direct aldol reaction to afford Wieland-Miescher ketone in 93% ee [17,18]. More than 25 years later, in 2000, List, Barbas, and co-workers reported that proline (19) is also effective for intermolecular direct aldol reactions of acetone (le) and various aldehydes 3. Notably, the reaction proceeded smoothly in anhydrous DMSO at an ambient temperature to afford aldol adducts in good yield and in modest to excellent enantioselectivity (up to >99% ee, Scheme 9) [19-22]. The chemical yields and selectivity of proline catalysis are comparable to the best metallic catalysts, although high catalyst loading (30 mol %) is required. Proline (19)... 

Important extensions of proline catalysis in direct aldol reactions were also reported. Pioneering work by List and co-workers demonstrated that hydroxy-acetone (24) effectively serves as a donor substrate to afford anfi-l,2-diol 25 with excellent enantioselectivity (Scheme 11) [24]. The method represents the first catalytic asymmetric synthesis of anf/-l,2-diols and complements the asymmetric dihydroxylation developed by Sharpless and other researchers (described in Chap. 20). Barbas utilized proline to catalyze asymmetric self-aldoli-zation of acetaldehyde [25]. Jorgensen reported the cross aldol reaction of aldehydes and activated ketones like diethyl ketomalonate, in which the aldehyde... 

Lam, Y.-h. Honk, K. N. Scheffler, U. Mahrwald, R. Stereoselectivities of histidine-catalyzed asymmetric aldol additions and contrasts with proline catalysis A quantum mechanical analysis, J. Am. Chem. Soc. 2012,134, 6286-6295. 

Hydroxyacetone 96 is a reagent in an even more remarkable reaction the asymmetric direct three-component Mannich reaction. It is combined with an aromatic amine 98 and the inevitable isobutyraldehyde 89 with proline catalysis to give a very high yield of a compound 99 that might have been made by an asymmetric amino-hydroxylation. The proline enamine of hydroxyacetone, must react with the imine salt formed from the amine and isobutyraldehyde. This is a formidable organisation in the asymmetric step. 

The initial spark for proline catalysis was provided independently and simultaneously by two groups in 1971. Hajos and Parrish on the one hand (Scheme 5.1), and Eder, Sauer and Wiechert (Scheme 5.2) on the other developed an asymmetric aldol cyclisation of triketones such as 1 to bicyclic allq l ketones 2. In the former report, (S)-proline was applied at 3 mol%, a low organocatalyst loading, even to date. The quantitative cyclisation reaction was completed in the reasonable time of 20 h, and provided the product in 93.4% ee. Dehydration to enone 3 completed the synthesis of a valuable building block in steroid chemistry. 

To facilitate the use of p-amino-aldehydes or -alcohols, obtained through asymmetric Mannich reactions, List et al. provided a procedure to use N-Boc-protected, preformed imines (21, 22) (Scheme 5.13a). While this method requires the formation of the imines, it provides products that can be deprotected under mild conditions, as compared to the widely used and robust PMB-protection in these reactions. Even acetaldehyde is applicable as aldehyde source (Scheme 5.13b). The p-amino-aldehydes (23, 24) obtained from this transformation are extremely valuable building blocks in organic synthesis, making this discovery one of the most useful applications of proline catalysis to date. 

The challenge of asymmetric and racemic a-functionalisation of carbonyls has led to the development of novel innovative solutions. As one option, organocatalysis and in particular, L-proline-catalysis has offered new technologies to access valuable a-functionalised products in a greener, more sustainable manner. 

Scheme 5.39 Asymmetric proline catalysis in the s5mthesis of (+)-palitantin.

In 2007, Ramachary et al. reported an asymmetric Knoevenagel/hydrogenation/Robinson annulation sequence to obtain Wieland-Miescher ketone 189 [88] (Scheme 2.62). The reaction of 5 equiv of aldehyde 9 with the 1,3-dicarbonyl compounds 186 (with CH acid) and Hantzsch ester 187 under proline catalysis furnished the expected cyclo-hexane-1,3-dione B in good yields. Once the solvent was removed by vacuum pump, the crude reaction mixture was diluted with DMF and treated with methyl vinyl ketone 188 in the presence of (S)-proline (1) furnishing the expected... 

Later, Ramachary and Sakthidevi reported for the first time the organo-catal)Aic cascade approach to the asymmetric synthesis of functionalised chromans via Barbas-List aldol-acetalisation reaction, as depicted in Scheme 2.28. The reaction of acetone with 2-hydro ybenzaldehyde under trans-4-OH-L-proline-catalysis in NMP as solvent furnished the corresponding aldol/lactol intermediate which upon treatment with p-TSA in methanol in one-pot furnished the selectively frans-2-metho y-2-methyl-chroman-4-ol in 55% yield and 77% ee, as shown in Scheme 2.28. 

The chiral auxiliaries anchored to the substrate, which is subjected to diastereoselective catalysis, is another factor that can control these reactions. These chiral auxiliaries should be easily removed after reduction without damaging the hydrogenated substrate. A representative example in this sense is given by Gallezot and coworkers [268], They used (-)mentoxyacetic acid and various (S)-proline derivates as chiral auxiliaries for the reduction of o-cresol and o-toluic acid on Rh/C. A successful use of proline derivates in asymmetric catalysis has also been reported by Harada and coworkers [269,270], The nature of the solvent only has a slight influence on the d.e. [271],... 

In this chapter, we discuss recent (reported mainly during 2000-2005) asymmetric reactions catalyzed by chiral bases. Because practicality is an important factor in the present asymmetric catalysis, we restricted our discussion mainly to the reactions giving over 90% ee unless the conversion is novel. We notice, however, that there are many potentially useful and scientifically interesting reactions, in which enantioselectivity does not exceed the practical range at this moment. Chiral organic base (proline and cinchona alkaloids)-catalyzed reactions were discussed in Chapter 11 by Lelais and MacMillan. 

On the basis of encouraging work in the development of L-proline-DMSO and L-proline-ionic liquid systems for practical asymmetric aldol reactions, an aldolase antibody 38C2 was evaluated in the ionic liquid [BMIM]PF6 as a reusable aldolase-ionic liquid catalytic system for the aldol synthesis of oc-chloro- 3-hydroxy compounds (288). The biocatalytic process was followed by chemical catalysis using Et3N in the ionic liquid [BMIM]TfO at room temperature, which transformed the oc-chloro-(3-hydroxy compounds to the optically active (70% ee) oc, (3-epoxy carbonyl compounds. The aldolase antibody 38C2-ionic liquid system was also shown to be reusable for Michael additions and the reaction of fluoromethylated imines. 

The Tsogoeva group, in 2006, reported the introduction of newly designed bifunctional secondary amine-functionalized proline-based thioureas (95 and 96) and the primary amine-functionalized thioureas (97-99) for catalysis of the asymmetric addition of ketones to trans-P-nitrostyrenes (Figure 6.30) [260, 261]. Using... 

H., Hayes., T. and Gathergood., N. (2009) (ed A.B. Hughes) Amino Acids, Peptides and Proteins in Organic Chemistry. Volume 2 — Catalysis of Reactions by Amino Acids Wiley-VCH Verlag GmbH, Weinheim, pp. 283-337 (d) Gathergood, N. (2002) Asymmetric organocatalysis proline an essential amino-acid Aust. J. Chem.,... 

For a highlight on asymmetric organo-catalysis by proline and other low-molecular weight organic molecules, see H. Groger, J. Wilken, Angew. 

Notwithstanding the progress in other reaction types, the main thrust in organo-catalysis research centers is on enantioselective catalysis applications [109,110], of which amine-based asymmetric catalysts form the majority [111]. Most of the reactions proceed via the enamine catalytic cycle (Figure 3.38a) or via imonium intermediates. The most common (and most successful) catalysts for such reactions are proline derivatives. Thanks to its secondary amine functionality and relatively high pKa value, proline (pyrrolidine-2-carboxylic acid) is a good... 

Agami C, Puchot C (1986) Kinetic analysis of dual catalysis by proline in an asymmetric intramolecular aldol reaction. J Mol Catal 38 341-343 Agami C, Puchot C, Sevestre H (1986) Is the mechanism of the proline-cata-lyzed enantioselective aldol reaction related to biochemical processes Tetrahedron Lett 27 1501-1504... 

S.C. PanandB. List s paper spans the whole field of current organocat-alysts discussing Lewis and Brpnsted basic and acidic catalysts. Starting from the development of proline-mediated enamine catalysis— the Hajos-Parrish-Eder-Sauer-Wiechert reaction is an intramolecular transformation involving enamine catalysis—into an intermolecular process with various electrophilic reaction partners as a means to access cY-functionalized aldehydes, they discuss a straightforward classification of organocatalysts and expands on Brpnsted acid-mediated transformations, and describe the development of asymmetric counteranion-directed catalysis (ACDC). 

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