Amino acids optically active, preparation

Another method for the preparation of 3-aryl-4//-l,2,4-oxadiazin-6(5.H )-oncs 4 is the reaction of aromatic nitrile oxides with ethyl esters of x-amino acids, which is thought to proceed via the esters of the A-(carboxymethyl)amide oximes discussed above. The nitrile oxides are generated from hydroxiinoyl chlorides7 and react in situ with the esters. If the esters are derived from optically active amino acids, optically active oxadiazinones are obtained.13... 

By all these methods the optically active forms of the amino acids have been prepared. 

In the cases where optically active substrates were used as starting materials, chiral, saturated 5(47/)-oxazolones were obtained with good enantiomeric excesses (ee). Oxazolones derived from Al-formyl-a-amino acids are better prepared using isopropenyl chloroformate, rather than methyl chloroformate, in the presence of N-methylmorphohne. ... 

In the Horner-Emmons reaction (Scheme 3), the sulfonylphosphonate carbanion 5 is formed in the presence of NaH and then reacts with an aldehyde to produce the intermediate 6 that undergoes in situ elimination to yield the vinyl sulfones and phosphonate anion. The sulfonyl group can stabilize the anion in the sulfonylphosphonate 5. The vinyl sulfones that are produced by this method using aldehydes as starting materials are exclusively the E (trans) isomers. The E-isomers of the vinyl sulfones are shown in the NMR spectra based on the coupling constants of the vinylic protons. Although strongly basic conditions are used in the Horner-Emmons reaction and a-amino aldehydes are easily racemized, the amino acid vinyl sulfones prepared by this method still show substantial optical activity. However, the enantiomeric purity of these compounds has not been determined. 5 ... 

Asymmetric synthesis of amino aeUs. Optically active amino acids can be prepared by addition of hydrogen cyanide to SchifT bases prepared from aliphatic aldehydes (representing the R group) and optically active benzylic amines (representing the... 

The Kabachnik Fields reaction, which involves the hydrophosphonylation of phos phites with imines generated in situ from carbonyl compounds and amines, is an attractive method for the preparation of a amino phosphonates. Optically active a amino phosphonic acids and their phosphonate esters are an attractive class of compounds due to their potent biological activities as nonproteinogenic analogues of a amino acids. Therefore, considerable attention has been given to their enantio selective synthesis by hydrophosphonylation of preformed imines, using either metal based catalysts or organocatalysis [107]. 

A closely related method for the preparation of optically pure amino adds involves the formation of hydantoins and the use of hydantoinases (Scheme 3.13). One advantage of this method is that when R is an aromatic group, in situ racemisation of the substrate can take place, leading to a high yield ( 50%) of optically pure amino acid (for further details, see Section 6.4.2). It is noteworthy that optically active amino acids can be prepared utilizing esterases, amidases (acylases) or hydantoinases six or seven amino adds are made commercially using one or another of these biotransformation processes. 

Racemic mixtures of amino acids can be prepared in the laboratory via a-haloacids, via the amidomalonate nthesis, or via the Strecker synthesis. Optically active amino acids are obtained either via resolution of a racemic mixture or via enantioselective synthesis. 

The DL-forms of nearly all of the amino acids have been prepared by racemization. The optically active amino acid is heated with a strong base, strong acid or an alkaline solution of acetic anhydride or ketene. Practical difficulties are that only a few of the optically active amino acids are readily obtainable, high temperatures and pressures may be required to effect rapid racemization and some amino acids are partly or wholly decomposed by treatment with hot acid or alkali. 

In summary a variety of novel optically active aryl amino acids have been prepared coupling of these to various 7-aminocephems has given a family of cephalosporins whose activity, based on primary evaluation is comparable to that of cephalexin, further investigation into these compounds is being pursued. 

Seehach D, Boes M, Naef R, Saweizer WB. Alkylation of amino acids without loss of the optical activity preparation of a-substituted proUne derivatives. A case of selfreproduction of chirahty. 7. Am. Chem. Soc. 1983 105 5390 5398. 

Synthetic utility of stereoselective alkylations in natural product chemistry is exemplified by the preparation of optically active 2-arylglycine esters (38). Chirally specific a-amino acids with methoxyaryl groups attached to the a-carbon were prepared by reaction of the dimethyl ether of a chiral bis-lactam derivative with methoxy arenes. Using SnCl as the Lewis acid, enantioselectivities ranging from 65 to 95% were obtained. 

Reductive alkylation with chiral substrates may afford new chiral centers. The reaction has been of interest for the preparation of optically active amino acids where the chirality of the amine function is induced in the prochiral carbonyl moiety 34,35). The degree of induced asymmetry is influenced by substrate, solvent, and temperature 26,27,28,29,48,51,65). Asymmetry also has been obtained by reduction of prochiral imines, using a chiral catalyst 44). Prediction of the major configurational isomer arising from a reductive alkylation can be made usually by the assumption that amine formation comes via an imine, not the hydroxyamino addition compound, and that the catalyst approaches the least hindered side (57). 

Figure A8.3 Preparation of optically active a-amino acids via bioconversion of the corresponding a-aminonitriles.

Figure A8.9 Procedure for the preparation of optically active a-disubstituted amino acids through stereoselective enzymatic cydisation of the N-carbamoyl derivatives.

Optically active five- or six-membered cyclic A -acyliminium ions of this type are generated from the a-inethoxy derivatives, easily obtainable through anodic methoxylation of intermediates that are prepared via ex-chiral-pool syntheses from certain natural amino acids. Reaction of 5-substituted five-membered cyclic A -acyliminium ions with various nucleophiles leads to the predominant formation of cw-products with moderate selectivity. The trans-selective reaction with alkyl copper reagents appears to be an exception. 

An excellent method for the diastereoselective synthesis of substituted amino acids is based on optically active bislactim ethers of cyclodipeptides as Michael donors (Schollkopf method, see Section 1.5.2.4.2.2.4.). Thus, the lithium enolates of bislactim ethers, from amino acids add in a 1,4-fashion to various a,/i-unsaturated esters with high diastereofacial selectivity (syn/anti ratios > 99.3 0.7-99.5 0.5). For example, the enolate of the lactim ether derivative 6, prepared from (S)-valine and glycine, adds in a highly stereoselective manner to methyl ( )-3-phenyl-propenoate a cis/trans ratio of 99.6 0.4 and a syn/anti ratio of 91 9, with respect to the two new stereogenic centers, in the product 7 are found105, los. 

Ail extremely useful method for the asymmetric synthesis of substituted amino acids, in particular glutamic acids, is based on optically active bislactim ethers of cyclodipeptides. The lithium etiolates of bislactim ethers (which are prepared easily from amino acids) undergo 1,4-addition to various a,/ -unsaturated esters to give -substituted 2,5-dihydropyrazine-propanoates203-205 with high diastereofacial selectivity, ratio (R/S) > 140-200 1. 

Several methods for asymmetric C —C bond formation have been developed based on the 1,4-addition of chiral nonracemic azaenolates derived from optically active imines or enamines. These methods are closely related to the Enders and Schollkopf procedures. A notable advantage of all these methods is the ready removal of the auxiliary group. Two types of auxiliaries were generally used to prepare the Michael donor chiral ketones, such as camphor or 2-hydroxy-3-pinanone chiral amines, in particular 1-phenylethanamine, and amino alcohol and amino acid derivatives. 

Hydroxy-L-prolin is converted into a 2-methoxypyrrolidine. This can be used as a valuable chiral building block to prepare optically active 2-substituted pyrrolidines (2-allyl, 2-cyano, 2-phosphono) with different nucleophiles and employing TiQ as Lewis acid (Eq. 21) [286]. Using these latent A -acylimmonium cations (Eq. 22) [287] (Table 9, No. 31), 2-(pyrimidin-l-yl)-2-amino acids [288], and 5-fluorouracil derivatives [289] have been prepared. For the synthesis of p-lactams a 4-acetoxyazetidinone, prepared by non-Kolbe electrolysis of the corresponding 4-carboxy derivative (Eq. 23) [290], proved to be a valuable intermediate. 0-Benzoylated a-hydroxyacetic acids are decarboxylated in methanol to mixed acylals [291]. By reaction of the intermediate cation, with the carboxylic acid used as precursor, esters are obtained in acetonitrile (Eq. 24) [292] and surprisingly also in methanol as solvent (Table 9, No. 32). Hydroxy compounds are formed by decarboxylation in water or in dimethyl sulfoxide (Table 9, Nos. 34, 35). 

In 1995, and regrettably missed in last year s review, Klotgen and Wiirthwein described the formation of the 4,5-dihydroazepine derivatives 2 by lithium induced cyclisation of the triene 1, followed by acylation <95TL7065>. This work has now been extended to the preparation of a number of l-acyl-2,3-dihydroazepines 4 from 3 <96T14801>. The formation of the intermediate anion and its subsequent cyclisation was followed by NMR spectroscopy and the stereochemistry of the final product elucidated by x-ray spectroscopy. The synthesis of optically active 2//-azepines 6 from amino acids has been described <96T10883>. The key step is the cyclisation of the amino acid derived alkene 5 with TFA. These azepines isomerise to the thermodynamically more stable 3//-azepines 7 in solution. 

This route has been widely exploited because of the availability of a-amino azomethine compoimds from natural (S)-a-amino acids, through the corresponding a-amino aldehydes, which are configurationally stable provided that the amino function is suitably protected. Moreover, some a-amino acids are available with the R configuration and a number of enzymatic and chemical transformations have been described for the preparation of optically active unnatural a-amino acids. Overall, the route suffers from the additional steps required for protection/deprotection of the amino function and, in the case of hydrazones and nitrones, cleavage of the N - N or N - O bond. 

Wong and co-workers have prepared various quaternary cx-nitro-cx-methyl carboxylic acid esters by the palladium-catalyzed allylic alkylation of a-nitropropionate ester (Eq. 5.59). The products can be kinetically resolved by using cx-chymotrypsin and are converted into optical active a-methyl cx-amino acids. Such amino acids are important due to the unique biological activity of these nonproteinogenic a-amino acids.82... 

Kibayashi and coworkers have used enantiometrically pure allylic silyl ethers obtained from amino acids in cycloaddition with nitrones (Eq. 8.49).71 Cyclic nitrone reacts with a chiral allyl ether to give selectively the exo and erythro isomer (de 90%). Optically active alkaloids containing a piperidine ring such as (+)-monomorine,71c (+)-coniine,71a and (-)-oncinotine71b have been prepared from the addition product. 

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