Scientific Background on the Nobel Prize in Chemistry 2021
The year 2000: Enamine and iminium ion catalysis
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The year 2000: Enamine and iminium ion catalysis
In 2000, two publications defined the starting point for the impressive development of the area of organocatalysis. In the first publication, List and co-workers outlined an L -proline catalysed intermolecular aldol reaction (enamine catalysis/Lewis base catalysis). 24 Later the same year, MacMillan and co-workers discussed a Diels-Alder reaction between α,β-unsaturated aldehydes and cyclopentadiene catalysed by a chiral imidazolidinone (iminium ion catalysis/Lewis acid catalysis). 25 In the following discussion, enamine and iminium ion catalysis will be discussed separately. 26
Enamine catalysis: In 2000, List, Lerner and Barbas III showed that the naturally occurring amino acid L -proline catalyses an intermolecular aldol reaction, which is a carbon-carbon bond- forming reaction, between acetone and a series of aromatic aldehydes (including isobutyraldehyde, eq. 2). 24 They proposed that the reaction proceeds via an enamine intermediate, resulting in a Highest Occupied Molecular Orbital (HOMO) raising and increased nucleophilicity compared to the corresponding enol ether, and that the carboxylic acid functionality in the catalyst helps to stabilise the metal-free Zimmerman-Traxler transition state through hydrogen bonding. The catalyst is thus covalently attached to the substrate and controls the stereochemical pathway of the intermolecular aldol reaction. Subsequent computational studies of the reaction have refined this picture and highlight the role of the carboxylic acid proton as an intramolecular acid catalyst that provides charge stabilisation to the forming alkoxide anion. 27 The researchers also suggested that the L -proline catalyst functions as a ‘micro-aldolase’, i.e. as an enzyme mimic, and that other organic reactions might be susceptible to a similar proline-mediated enamine catalysis.
Some important findings preceded this work. In the early 1970s, the groups of Hajos and Parrish (1971, 1974) 28-29
and Eder, Sauer and Wiechert 30 (1971) independently reported pioneering contributions to the field of asymmetric catalysis. They showed that L -proline catalyses the cyclisation of the achiral triketone 5 to furnish the Wieland-Miescher ketone (6, the Hajos-Parrish-Eder-Sauer-Weichert, or HPESW, reaction), which is an important intermediate in the synthesis of several natural products (Scheme 1). For example, the HPESW reaction has been used for the synthesis of steroids. The reaction proceeds in high yields and produces compound 6 in high er.
5 (19)
The paper by Wiechert and colleagues is rather laconic and provides no information about the scope and mechanism of the reaction. In contrast, Hajos and Parrish put forward a mechanism involving a carbinolamine that is now obsolete, since it is appreciated that the reaction proceeds through enamine catalysis, but, perhaps more importantly, the authors recognized that the proline catalyst plays the same role as an enzyme. However, these studies were not followed up by the authors, nor did they result in a general concept of using chiral amines in asymmetric enamine catalysis. Indeed, later studies by Agami and colleagues using L -proline to catalyse intramolecular aldol reactions afforded the products in moderate to low er. 31
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