Synthesis of l amino acids

This methodology provides a general synthesis of L-amino acids in 92-96% ee and in chemical yields of about 40-60%. Thus reaction of 3 (X = Br) with NaN3 under phase-transfer conditions provides 6, which is homologated to the 1-chloro-2-azidoboronate 7. This product is oxidized by sodium chlorite directly to an azido carboxylic acid (8). Hydrogenation of 8 provides L-amino acids (9). 

Ibble 4.4 Diastereoselective Ugi synthesis of L-amino acid amides with D-arabinosylamine 10... 

Almost all amino acids elicit taste. Most hydrophobic L-amino acids have a bitter taste. However, hydrophobic D-amino acids, which are formed simultaneously by the synthesis of L-amino acids, bring out a strong sweet taste. D-Trp, Phe, His, Tyr and Leu are 35, 7, 7, 6 and A times as sweet as sucrose, respectively (2). Gly and L-Ala elicit a strong sweet taste. It is thought that the strong sweet taste elicited by these amino acids is due to the ability of these molecules to bind to the sweet substance receptors. 

A classic example of a typical enzymatic resolution on an industrial scale is the acylase-mediated production of L-methionine. This method has also been applied for the production of L-phenylalanine and L-valine. In addition to acylases, amidases, hydantoinases, and /i-lactam hydrolases represent versatile biocatalysts for the production of optically active L-amino acids. A schematic overview of the different type of enzymatic resolutions for the synthesis of L-amino acids is given in Fig. 2. 

Using an L-amino acid dehydrogenase in the presence of a formate dehydrogenase for cofactor regeneration, a prochiral keto acid is converted with high yield and en-antioselectivity. Furthermore, biocatalytic transaminations as well as Michael-addi-tions are important reactions for the large-scale synthesis of L-amino acids. 

By analogy with the rearrangement of styrene oxide compounds, more complicated substances, e. g. phenylpyruvic acid methyl ester derivatives, can be synthesized from readily available glycidic acid esters, as shown in Figure 3. These esters can be used as intermediates for herbicides (e. g. the triazinones) and for the synthesis of L-amino acids. 

L-a-Amino acids. Bycroft and Lee have reported an efficient asymmetric synthesis of l-amino acids from o-keto acids and ammonia with L-proline as the... 

H. Kunz, W. Pfrengle, K. Ruck, and W. Sager, Stereoselective synthesis of L-amino acids via Strecker and Ugi reactions on carbohydrate templates. Synthesis (1991) 1039-1042. 

Juaristi E (ed) (1996) Enantioselective synthesis of [l-amino acids. Wiley-VCH, New York... 

Brundish, E., D. F. Elliott, and R. Wade Synthesis of L-Amino Acids and their Derivatives Labelled with Tritium. J. Labelled Compd. 7, 473-493 (1971). 

J.L Matthews, C. Braun, C. Guibour-denche, M. Overhand, D. Seebach, Preparation of enantiopure y -amino acids from a-amino acids using the Arndt-Eis-tert homologation, in E. Juaristi (Ed.), Enantioselective Synthesis of f-Amino Acids, Wiley-VCH, New York, 1997. 

In many cases, the racemization of a substrate required for DKR is difficult As an example, the production of optically pure cc-amino acids, which are used as intermediates for pharmaceuticals, cosmetics, and as chiral synfhons in organic chemistry [31], may be discussed. One of the important methods of the synthesis of amino acids is the hydrolysis of the appropriate hydantoins. Racemic 5-substituted hydantoins 15 are easily available from aldehydes using a commonly known synthetic procedure (Scheme 5.10) [32]. In the next step, they are enantioselectively hydrolyzed by d- or L-specific hydantoinase and the resulting N-carbamoyl amino acids 16 are hydrolyzed to optically pure a-amino acid 17 by other enzymes, namely, L- or D-specific carbamoylase. This process was introduced in the 1970s for the production of L-amino acids 17 [33]. For many substrates, the racemization process is too slow and in order to increase its rate enzymes called racemases are used. In processes the three enzymes, racemase, hydantoinase, and carbamoylase, can be used simultaneously this enables the production of a-amino acids without isolation of intermediates and increases the yield and productivity. Unfortunately, the commercial application of this process is limited because it is based on L-selective hydantoin-hydrolyzing enzymes [34, 35]. For production of D-amino acid the enzymes of opposite stereoselectivity are required. A recent study indicates that the inversion of enantioselectivity of hydantoinase, the key enzyme in the... 

Palchetti I, Mascini M (2005) Electrochemical Adsorption Technique for Immobilization of Single-Stranded Oligonucleotides onto Carbon Screen-Printed Electrodes. 261 27-43 Pascal R, Boiteau L, Commeyras A (2005) From the Prebiotic Synthesis of a-Amino Acids Towards a Primitive Translation Apparatus for the Synthesis of Peptides. 259 69-122 Paulo A, see Santos I (2005) 252 45-84 Perez EM, see Leigh DA (2006) 265 185-208 Perret F, see Coleman AW (2007) 277 31-88 Perron H, see Coleman AW (2007) 277 31-88 Pianowski Z, see Winssinger N (2007) 278 311-342 Piestert F, see Gansauer A (2007) 279 25-52... 

A newer therapeutic approach is the administration of betaine (6-12 g daily), which lowers homocysteine levels by favoring remethylation [33], A theoretical hazard of betaine treatment is increasing the blood methionine, sometimes to an extravagant degree ( 1 mmol/1). Experience to date indicates that betaine administration is safe, with no major side effects except for a fishy odor to the urine. Other therapeutic approaches have included the administration of salicylate to ameliorate the thromboembolic diathesis. Patients also have been treated with dietary supplements of L-cystine, since the block of the transsulfura-tion pathway in theory could diminish the synthesis of this amino acid. 

One of the interesting application of 12 (R= allyl, X=Br) will be the synthesis of cyclic amino acid, (S)-pipecolic acid, as its tert-butyl ester 271251 Monoalkylation of the O Donnell imine 23 with l-chloro-4-iodobutane afforded the alkylated product 26 with 99 % ee. The conversion of 26 to the tert-butyl ester of pipecolic acid 27 was achieved in high yield by the sequence imine reduction, cyclization, and hydrogenolytic removal, as shown in Scheme 8. 

In the search of new methodologies for the asymmetric synthesis of nonproteinogenic amino acids, 8-methyl-4,8a-diphenyltetrahydro-17/-pyrrolo[2.1 -r l, 4 oxazinc-l, 6(7//)-dionc 62, obtained as described in Scheme 24 (Section 11.11.7.3), was selectively reduced at the lactam carbonyl with BH3 and further opened by hydrogenolysis to give syn-disubstituted proline derivative 64 in 95% yield <1997SL935> (Scheme 6). It is noteworthy that hydrogenolysis did not affect the benzylic position of bicyclic compound 63. 

Asymmetric Synthesis of a-Amino Acids by the Alkylation of Pseudoephedrine Glycinamide. Preparation of L-Allylglycine and N-Boc L-Allylglycine. 

Diastereoselective 1,4- and 1,6-addition reactions of lithium amides to chiral naph-thyloxazolines were used by Shimano and Meyers108-110 for the synthesis of novel amino acids. For example, treatment of (S )-2-(l-naphthyl)-4-t-butyloxazoline with lithi-ated l,4-dioxa-8-azaspiro[4.5]decane and iodomethane provided the diastereomerically pure 1,4-addition product with excellent yield cleavage of the heterocyclic rings then gave the desired /3-amino acid (>99% ee/ds equation 32)108,109. In contrast to this, most acyclic lithium amides reacted with these oxazolines under 1,6-addition the products were transformed smoothly to 5-amino acid derivatives (equation 33)110. 

Gu, R.-L., Lee, I.S. and Sih, C.J., Chemo-enzymatic asymmetric synthesis of amino acids. Enantioselective hydrolyses of 2-phenyl-oxazolin-5-ones. Tetrahedron Lett., 1992, 33, 1953-1956 Crich, J., Brieva, R., Marquart, P., Gu, R.-L., Flemming, S. and Sih, C.J., Enzymic asymmetric synthesis of a-amino acids. Enantioselective cleavage of 4-substituted oxazolin-5-ones and thiazolin-5-ones. J. Org. Chem., 1993, 58, 3252-3258. 

Yasuda, M., Ueda, M., Muramatsu, H., Mihara, H. and Esaki, N., Enzymatic synthesis of cyclic amino acids by A-methyl-L-amino acid dehydrogenase from Pseudomonas putida. Tetrahedron Asymmetry. 2006, 17, 1775. 

The diastereofacial selective imine-ene reactions with a-imino esters prepared from (—)-8-phenylmenthyl glyoxylate have provided an efficient entry to the asymmetric synthesis of a-amino acids, and a Lewis acid-mediated intramolecular imine-ene reaction has been used for the key spirocyclization step in a recent synthesis of (—)-perhydrohistrionicotoxin. Asymmetric azo-ene reactions have been effected using the chiral azo-enophile, di-(—)-(lR,2S)-2-phenyl-l-cyclohexyldiazenedicarboxylate. ... 

Pascal R, Boiteau L, Commeyras A (2005) From the Prebiotic Synthesis of a-Amino Acids Towards a Primitive Translation Apparatus for the Synthesis of Peptides. 259 69-122 Paulo A, see Santos I (2005) 252 45-84... 

The same group has exploited this interesting dehydrogenase for the synthesis of cyclic amino acids from linear precursors by developing a one-pot, two-enzyme system (Scheme 2.16). t-Lysine oxidase or L- or d-AAO were initially used to... 

Scheme 2.16 Synthesis of cyclic amino acid (R)-40 by combined use of L-lysine oxidase and NMAADH.

L = ( R) - monophos Scheme 6.25 Chemoenzymatic synthesis of an amino acid. 

---