Proline catalysis compounds

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. 

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... 

As previously noted (Scheme 1), prior to the explosion of interest in iminium ion catalysis as a platform for the activation of a,P-unsaturated carbonyl compounds in 2000, Yamaguchi [29-33] and Taguchi [34] showed that proline derived bi-func-tional catalysts could provide an effective platform for the ion-pair controlled conjugate addition of malonates and nitroalkanes to a, 3-unsaturated ketones with good levels of stereocontrol. 

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 arylation of ethyl acetoacetate, ethyl benzoylacetate, and diethyl malonate under the catalysis of CuI/L-proline in DMSO has been performed at 40-50 °C in the presence of CS2CO3 to provide the 2-aryl-1,3-dicarbonyl compounds in good yields.38 Both aryl iodides and aryl bromides are compatible with these reaction conditions. 

L-Proline is perhaps the most well-known organocatalyst. Although the natural L-form is normally used, proline is available in both enantiomeric forms [57], this being somewhat of an asset when compared to enzymatic catalysis [58], Proline is the only natural amino acid to exhibit genuine secondary amine functionality thus, the nitrogen atom has a higher p Ka than other amino acids and so features an enhanced nucleophilicity compared to the other amino acids. Hence, proline is able to act as a nucleophile, in particular with carbonyl compounds or Michael acceptors, to form either an iminium ion or enamine. In these reactions, the carboxylic function of the amino acid acts as a Bronsted acid, rendering the proline a bifunctional catalyst. 

Enamine catalysis using proline or related catalysts has now been applied to both intermolecular and intramolecular nucleophilic addition reactions with a variety of electrophiles. In addition to carbonyl compounds (C = O), these include imines (C = N) in Mannich reactions (List 2000 List et al. 2002 Hayashi et al. 2003a Cordova et al. 2002c ... 

Enantioselective catalysis promoted by enantiomerically pure amines (aminocatalysis) is the subject of considerable interest due to the ubiquitous presence and ready availability of these compounds in the chiral pool. In this context amino acids have always played a key role. One of the most successful and versatile chiral organic catalysts, proline, was... 

Simple L-alanine, L-valine, L-norvaline, L-isolecucine, L-serine and other linear amino acids [ 121 ] or chiral amino acids with a binaphthyl backbone [ 122] and peptides have also been used as asymmetric catalysts [123,124,125,126]. Solid-supported proline-terminated peptides have been used for heterogeneous catalysis of the asymmetric aldol reaction [ 127]. Apart from proline and derivatives, other cyclic compounds such as 5,5-dimethyl thiazolidinium-4-car-boxylate (DMTC) [128], 2-fert-butyl-4-benzyl imidazolidinones [129], (l/ ,25)-2-aminocy-clopentanecarboxylic acid [130], (5 -5-(pyrrolidin-2-yl)tetrazole, (5)-l,3-thiazolidine-4-car-boxylic acid, (5)-5,5-dimethyl-l,3-thiazolidine-4-carboxylic acid, and (5)-hydroxyproline are effective catalysts in asymmetric aldol reactions [126,131,132,133,134,135]. 

One of the most studied processes is the direct intermolecular asymmetric aldol condensation catalysed by proline and primary amines, which generally uses DMSO as solvent. The same reaction has been demonstrated to also occur using mechanochemical techniques, under solvent-free ball-milling conditions. This chemistry is generally referred to as enamine catalysis , since the electrophilic substitution reactions in the a-position of carbonyl compounds occur via enamine intermediates, as outlined in the catalytic cycle shown in Scheme 1.1. A ketone or an a-branched aldehyde, the donor carbonyl compound, is the enamine precursor and an aromatic aldehyde, the acceptor carbonyl compound, acts as the electrophile. Scheme 1.1 shows the TS for the ratedetermining enamine addition step, which is critical for the achievement of enantiocontrol, as calculated by Houk. ... 

Proline is a stable, nontoxic, cyclic, secondary pyrrolidine-based amino acid with an increased pK value. Thus, proline is a chiral bidentate compound that can form catalytically active metal complexes (Melchiorre et al. 2008). Bidentate means that proline has not only one tooth but also a second one to bite and react. The greatest difference to other amino acids is a Lewis-base type catalysis that facilitates iminium and enamine-based reactions. It is especially noteworthy that cross-aldol condensations of unprotected glycoladehyde and racemic glyceralde-hyde in the presence of catalytic amounts of the Zn-(proline)2 gave a mixture of pentoses and hexoses (Kofoed et al. 2004). Again, proline seems to play the decisive role. The conditions are prebiotic the reaction proceeded in water for seven days at room temperature. It is remarkable that the pentose products contained ribose (34%), lyxose (32%), arabinose (21%), and xylose (12%) and that all are stable under the conditions. Thus, the diastereomeric and enantiomeric selection observed support the idea that amino acids have been the source of chirality for prebiotic sugar synthesis. 

Acetone, the component that must enolise, is present in large excess but the achievement is considerable. The reaction involves formation of the proline enamine of acetone 91 which then attacks the aldehyde through a chair-like transition state 92 held together by the acidic proton of proline s carboxylic acid. This gives the imine salt 93 hydrolysed to the product with regeneration of proline. The intermediates are like those in the Robinson annelation enamines and imines. Organic catalysis with amines relies on equilibria between these intermediates and carbonyl compounds. 

L-Proline could be used as an effective catalyst via dual-enamine-iminium-catalysis modes. Pyrrolidine was ineffective, indicative of the crucial role of proline s carboigrlate moiety. The Meldrum s acid derivatives could be postfunctionalised via methanolysis and in situ decarboig lation to produce complex 1,5-dicarbonyl compounds. This strategy was applied towards the synthesis of polycyclic chromene derivatives (38, Scheme 5.43). ... 

Even though the use of (S)-proline (1) for the synthesis of the Wieland-Miescher ketone, a transformation now known as the Hajos-Parrish-Eder-Sauer-Wiechert reaetion, was reported in the early 1970s, aminocatalysis - namely the catalysis promoted by the use of chiral second-aiy amines - was rediscovered only thirty years later. The renaissance of aminocatalysis was prompted by two independent reports by List et al. on the asymmetric intermolecular aldol addition catalysed by (S)-proline (1) and by MacMillan et al. on the asymmetric Diels-Alder cycloaddition catalj ed by a phenylalanine-derived imidazolidinone 2. These two reactions represented the archetypical examples of asymmetric carbonyl compound activation, via enamine (Figure ll.lA) and iminium-ion (Figure 11.IB), respectively. 

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