Aspartic acid decarboxylase

Aspartic acid decarboxylase cataly2es the decarboxylation of asparatic acid to yield P-alanine (10), a precursor for the biosynthesis of pantothenic acid (67). FiaaHy, (R)-pantothenic acid is obtaiaed by coupling P-alaniae (10) with (R)-pantoate (22) ia the presence of pantothenate synthetase ... 

David, W. E., and H. C. Lichstein Aspartic acid decarboxylase in bacteria. 

Manometric determiaation of L-lysiae, L-argioine, L-leuciae, L-ornithine, L-tyrosiae, L-histidine, L-glutamic acid, and L-aspartic acid has been reviewed (136). This method depends on the measurement of the carbon dioxide released by the T.-amino acid decarboxylase which is specific to each amino acid. 

L-alanine can be prepared from aspartic acid (Figure A8.13). L-Aspartate-(5-decarboxylase produced by Xanthomonas oryzae No 531 has been used to prepared L-alanine in 95% yield from 15% L-aspartic add solution. Other strains, ie Pseudomonas dacunhae or Achromobacter pestifer, give comparable yields of L-alanine. The process has been commercialised by Tanabe. 

Amino Acid Systems Glutamine binding sites, 46, 414 labeling of the active site of r-aspartate /3-decarboxylase with yS-chloro-r-ala-nine, 46, 427 active site of r-asparaginase reaction with diazo-4-oxonorvaline, 46, 432 labeling of serum prealbumin with N-bro-moacetyl-L-thyroxine, 46, 435 a pyridoxamine phosphate derivative, 46, 441. 

D-aspartic acid DL-aspartic acid L-aspartate decarboxylase... 

Also Tanabe have extended the use of that aspartic acid producing process by using the L-aspartic acid as the substrate for L-alanine production using P. dacunae cells with L-aspartate decarboxylase activity. This process has been operating since 1982 using sequential colunms of iimnobihsed E. coli and P. dacunae cells (Chibata, Tosa and Takamatsu, 1987). Also, DL-aspartic acid can be used as the feed in this process. Then, D-aspartic acid is obtained as an additional product, for which there is a modest demand. 

Aspartate a-decarboxylase 753, 755 Aspartate p-decarboxylase 746 Aspartate racemase 741 Aspartic acid (Asp, D) 52, 53s biosynthesis 517 pXa value of 293, 487 Aspartic proteases 621-625 Aspartyl aminopeptidase 621 p-Aspartyl phosphate 539, 540s Assays of enzyme activity 456 Assembly core of virus shell 365 Assembly pathway... 

In addition to resolution approaches, there are three main methods to prepare amino acids by biological methods addition of ammonia to an unsaturated carboxylic acid the conversion of an a-keto acid to an amino acid by transamination from another amino acid, and the reductive animation of an a-keto acid. These approaches are discussed in Chapter 19 and will not be discussed here to avoid duplication. The use of a lyase to prepare L-aspartic acid is included in this chapter as is the use of decarboxylases to access D-glutamic acid. 

Amino acid decarboxylases can be used to catalyze the resolution of several amino acids, and for the most part their utility has been underestimated, especially with respect to the irreversible reaction equilibrium. The decarboxylases are ideally suited to large-scale industrial application as a result of their robust nature, d-Aspartate (13, n = 1) and D-glutamate (13, n = 2) can be made economically... 

A number of decarboxylase enzymes have been described as catalysts for the preparation of chiral synthons, which are difficult to access chemically (see Chapter 2).264 The amino acid decarboxylases catalyze the pyridoxal phosphate (PLP)-dependent removal of C02 from their respective substrates. This reaction has found great industrial utility with one specific enzyme in particular, L-aspartate-P-decarboxylase (E.C. 4.1.1.12) from Pseudomonas dacunhae. This biocatalyst, most often used in immobilized whole cells, has been utilized by Tanabe to synthesize L-alanine on an industrial scale (multi-tons) since the mid-1960s (Scheme 19.33).242-265 Another use for this biocatalyst has been the resolution of racemic aspartic acid to produce L-alanine and D-aspartic acid (Scheme 19.34). The cloning of the L-aspartate-P-decarboxylase from Alcaligenes faecalis into E. coli offers additional potential to produce both of these amino acids.266... 

Alanine and aspartic acid are produced commercially utilizing enzymes. In the case of alanine, the process of decarboxylation of aspartic acid by the aspartate decarboxylase from Pseudomonas dacunhae is commercialized. The annual world production of alanine is about 200 tons. Aspartic acid is produced commercially by condensing fumarate and ammonia using aspartase from Escherichia coli. This process has been made more convenient with an enzyme immobilization technique. Aspartic acid is used primarily as a raw material with phenylalanine to produce aspartame, a noncaloric sweetener. Production and sales of aspartame have increased rapidly since its introduction in 1981. Tyrosine, valine, leucine, isoleucine, serine, threonine, arginine, glutamine, proline, histidine, cit-rulline, L-dopa, homoserine, ornithine, cysteine, tryptophan, and phenylalanine also can be produced by enzymatic methods. 

A similar process is also used for the production of L-malic acid from fumarate, in this case using a hydratase enzyme derived from Brevibacterium ammoniagenes. Another variation of the Tanabe technology involves the synthesis of L-alanine from L-aspartic acid through the use of immobilized whole cells (P dacunae) containing aspartate-decarboxylase. 

Woo TU, Walsh JP, Benes FM. 2004. Density of glutamic acid decarboxylase 67 messenger RNA-containing neurons that express the N-methyl-D-aspartate receptor subunit NR2A in the anterior cingulate cortex in schizophrenia and bipolar disorder. Arch Gen Psychiatry 61 649-657. 

For two transaminases the remaining unknown stereochemical parameter was determined by demonstrating an internal transfer of tritium (dialkyl amino acid transaminase) [28] or deuterium (pyridoxamine-pyruvate transaminase) [27] from the a-position of the substrate L-alanine to C-4 of the cofactor. Internal hydrogen transfer from the a-position of the substrate amino acid to C-4 of PLP has also been demonstrated for two of the abortive transamination reactions, those catalyzed by tryptophan synthase fi2 protein [32] and by aspartate-/8-decarboxylase [31]. In addition, the same phenomenon must occur in alanine transaminase, as deduced from the observation that the enzyme catalyzes exchange of the /8-hydrogens of... 

As summarized in Scheme II, PLP enzymes can catalyze replacements at the y-carbon of amino acids and eliminations of HY between C-fi and C-y. In mechanistic similarity to the aspartate-/3-decarboxylase reaction, in these processes the quinoid intermediate 1 loses a proton from C-/3, followed by elimination of an anionic group (Y ) from C-y, to generate the central intermediate PLP-vinylglycine, 4 (Scheme II). This species, the vinylogue of 1, can undergo a number of reactions. Addition of a new anionic group (Y ) and reversal of the reaction sequence constitutes the y-replacement reaction, as in cystathionine-y-synthase. On the other hand, in analogy to the protonation of 1 at C-a, 4 can be protonated at C-y,... 

The assay described for amino acid decarboxylase can be used to quantitate the substrates and products associated with the decarboxylation of arginine, aspartate, 2,6-diaminopimelate, histidine, glutamate, lysine, and ornithine. 

Aspartate undergoes /3-decarboxylation to /S-alanine unlike most amino acid decarboxylases, aspartate decarboxylase is not pyridoxal phosphate-dependent, but has a catalytic pyruvate residue, derived by postsynthetic modification of a serine residue (Section 9.8.1). Pantothenic acid results from the formation of a peptide bond between /3-alanine and pantoic acid. 

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