Amino acids enantiomeric excesses

The four stereoisomers of this amino acid include the D- and L-forms of a-methylisoleucine and a-methylalloisoleucine. Cronin, J.R., and Pizzarello, S., 1997. Enantiomeric excesses in meteoritic amino acids.. Science 275 951—955. 

Since most often the selective formation of just one stereoisomer is desired, it is of great importance to develop highly selective methods. For example the second step, the aldol reaction, can be carried out in the presence of a chiral auxiliary—e.g. a chiral base—to yield a product with high enantiomeric excess. This has been demonstrated for example for the reaction of 2-methylcyclopenta-1,3-dione with methyl vinyl ketone in the presence of a chiral amine or a-amino acid. By using either enantiomer of the amino acid proline—i.e. (S)-(-)-proline or (/ )-(+)-proline—as chiral auxiliary, either enantiomer of the annulation product 7a-methyl-5,6,7,7a-tetrahydroindan-l,5-dione could be obtained with high enantiomeric excess. a-Substituted ketones, e.g. 2-methylcyclohexanone 9, usually add with the higher substituted a-carbon to the Michael acceptor ... 

A. Dossena, G. Galaverna, R. Coiradini and R. Marchelli, Two-dimensional liigh performance liquid chromatographic system foi the determination of enantiomeric excess in complex amino acid mixtures. Single amino acids analysis , ]. Chromatogr. 653 229-234 (1993). 

When /V-arenesulfonyl-a-amino acid derived boranes 13 and 14 are used in substoichiometric amounts in order to mediate enantioselective aldol additions of a,a-dimethyl substituted ketcnc acetal 15, /J-hydroxycarboxylic esters 16 are obtained in enantiomeric excess of 84 to > 99 %3fi. 

For successful DKR two reactions an in situ racemization (krac) and kinetic resolution [k(R) k(S)] must be carefully chosen. The detailed description of all parameters can be found in the literature [26], but in all cases, the racemization reaction must be much faster than the kinetic resolution. It is also important to note that both reactions must proceed under identical conditions. This methodology is highly attractive because the enantiomeric excess of the product is often higher than in the original kinetic resolution. Moreover, the work-up of the reaction is simpler since in an ideal case only the desired enantiomeric product is present in the reaction mixture. This concept is used for preparation of many important classes of organic compounds like natural and nonnatural a-amino acids, a-substituted nitriles and esters, cyanohydrins, 5-alkyl hydantoins, and thiazoUn-5-ones. 

A similar reaction occurs with 2-methylcyclopentane-l,3-dione,176 and can be done enantioselectively by using the amino acid L-proline to form an enamine intermediate. The (S)-enantiomer of the product is obtained in high enantiomeric excess.177... 

Subsequently, the enantioselective variant of this reaction202 was carried out in a biphasic medium (water + diethylene glycol) by using a mixture of amino acids and copper complexes (Eq. 3.54). When the reaction was carried out under an argon atmosphere, the recycling of the catalyst was also possible. The enantiomeric excess decreased slightly... 

An alternative to extraction crystallization is used to obtain a desired enantiomer after asymmetric hydrolysis by Evonik Industries. In such a way, L-amino acids for infusion solutions or as intermediates for pharmaceuticals are prepared [35,36]. For example, non-proteinogenic amino acids like L-norvaline or L-norleucine are possible products. The racemic A-acteyl-amino acid is converted by acylase 1 from Aspergillus oryzae to yield the enantiopure L-amino acid, acetic acid and the unconverted substrate (Figure 4.7). The product recovery is achieved by crystallization, benefiting from the low solubility of the product. The product mixture is filtrated by an ultrafiltration membrane and the unconverted acetyl-amino acid is reracemized in a subsequent step. The product yield is 80% and the enantiomeric excess 99.5%. 

The question was whether impurities were present in the samples analysed (Bada et al., 1983). In a more recent publication, Cronin and Pizzarello (1997) reported amino acid analyses using Murchison material in which an excess of L-enantiomers was present. Contamination with terrestrial biological material can be ruled out, as the amino acids in question are not proteinogenic a-methylamino acids, which occur either extremely seldom or not at all in terrestrial life forms, were detected. GLPC/mass spectrometry (MS) analysis gave the following enantiomeric excess (ee) values ... 

Such enantiomeric excesses have not been observed in analyses of the corresponding a-H-a-aminoalkanoic acids. According to the authors, the excess of the L-forms could be due to a partial photocleavage of the racemic amino acid mixture as a result of the influence of circularly polarized UV light in a presolar cloud (Cronin and Pizzarello, 2000). 

Another example of the ability of proteinogenic amino acids, small peptides, and amines to catalyse the formation of new C-C bonds has been demonstrated by Weber and Pizzarello they were able to carry out model reactions for the stereospecific synthesis of sugars (tetroses) using homochiral L-dipeptides. The authors achieved a D-enantiomeric excess (ee) of more than 80% using L-Val-L-Val as the peptide catalyst in sugar synthesis (in particular D-erythrose) via self-condensation of glycol aldehyde. 

The question also arises as to where the chiral molecules came from. Were the L-amino acids or the D-sugars selected on the primeval Earth, or are exuaterresuial sources responsible for the homochirality This second possibility is dealt with by hypotheses on the effect of circularly polarised light, of extraterrestrial origin, on chiral molecules in the molecular clouds from which the solar system was formed. One such hypothesis was proposed by Rubenstein et al. (1983) and developed further by others, particularly A. W. Bonner (Bonner and Rubenstein, 1987) both scientists worked at Stanford University. The authors believe that the actual radiation source was synchrotron radiation from supernovae. The excess of one enantiomeric form generated by this irradiation process would have needed to be transported to Earth by comets and meteorites, probably during the bombardment phase around 4.2-3.8 billion years ago. 

It is still unclear what kind of radiation sources can lead to asymmetric reactions. Jeremy Bailey from the Anglo-Australian Observatory in Epping, Australia, investigated which astronomical objects could be considered radiation sources (Bailey et al., 1998 Bailey, 2001). It was possible in laboratory experiments to generate a small enantiomeric excess of some amino acids by using circularly polarized UV light (Norden, 1977). This asymmetric photolysis involves photochemical decomposition of both d- and L- enantiomers, but at different rates, so the more stable form tends to survive. This process must be subject to autocatalytic multiplication. 

The processes occurring at hydrothermal systems in prebiotic periods were without doubt highly complex, as was the chemistry of such systems this is due to the different gradients, for example, of pH or temperature, present near hydrothermal vents. Studies of the behaviour of amino acids under simulated hydrothermal conditions showed that d- and L-alanine molecules were racemised at different rates the process was clearly concentration-dependent. L-Alanine showed a low enantiomeric excess (ee) over D-alanine at increasing alanine concentrations. The same effect was observed with metal ions such as Zn2+ in the amino acid solution. Thus, homochi-ral enrichment of biomolecules in the primeval ocean could have resulted under the conditions present in hydrothermal systems (Nemoto et al., 2005). 

Many compounds are less soluble as racemates than as their pure enantiomers. It thus appears probable that evaporation of an amino acid solution with a low ee should cause selective precipitation of the racemate crystals, which in turn should lead to an increase of the ee. Extremely simple manipulations, carried out in the chemistry department of Columbia University, led to a drastic increase in enantiomeric excess of phenylalanine 500 mg phenylalanine (with a 1 % ee of the L-component) was dissolved in water, and the resulting solution slowly evaporated until about 400 mg had crystallised out. The remaining solution contained a few mg of phenylalanine with 40% ee of the L-component (i.e., a 70 30 ratio of l to d). If 500 mg of such a solution (40% ee in water) is allowed to evaporate and is separated from the racemate, the result is about 100 mg, with 90% ee of the L-enantiomer (Breslow and Levine, 2006). 

NMR can be a powerful tool for determination of enantiomeric excess or absolute configuration of the optically active compounds, however, these processes require the use of some auxiliaries, for example, chiral lanthanide shift reagents or chiral derivatising agent. In many cases, the starting point for determination of enantiopurity of amines, amino acids or diols is the formation of chiral imines. 

This reaction is very important for the synthesis of natural products and for the design of diversely substituted ligands. The use of Sml2 in radical additions of nitrones to 0.,j3-unsaturated amides and esters, constitutes a convenient synthesis of various functionalized y-amino acids with high enantiomeric excess (Schemes 2.114 and 2.115) (531-533). 

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