Pseudomonas putida

D-cysteine (derivatives) 3-chloro-DL-alanine + iNaHS 3-chloro-D-Ala dehydrochlorinase or Pseudomonas putidaE. coli etc ... 

Ozonolysis of 5,8,9-trihydroxy-2,3-dihydro-l//-pyrimido[l, 2-n]quinoline-3-carboxylic acid (420), obtained from isopyoverdin isolated from Pseudomonas putida BTPl by acidic hydrolysis, gave l-2,4-diaminobutyric acid, which confirmed the hypothesis that heterocyclic chromophores 1 and 4 of pyoverdin and isopyoverdin, respectively, could have the same precursor, and the configuration at C(3) should be 5 (97ZN(C)549). 

A very efficient and universal method has been developed for the production of optically pue L- and D-amino adds. The prindple is based on the enantioselective hydrolysis of D,L-amino add amides. The stable D,L-amino add amides are effidently prepared under mild reaction conditions starting from simple raw materials (Figure A8.2). Thus reaction of an aldehyde with hydrogen cyanide in ammonia (Strecker reaction) gives rise to the formation of the amino nitrile. The aminonitrile is converted in a high yield to the D,L-amino add amide under alkaline conditions in the presence of a catalytic amount of acetone. The resolution step is accomplished with permeabilised whole cells of Pseudomonas putida ATCC 12633. A nearly 100% stereoselectivity in hydrolysing only the L-amino add amide is combined with a very broad substrate spedfidty. 

L-Amino adds could be produced from D,L-aminonitriles with 50% conversion using Pseudomonas putida and Brembacterium sp respectively, the remainder being the corresponding D-amino add amide. However, this does not prove the presence of a stereoselective nitrilase. It is more likely that the nitrile hydratase converts the D,L-nitrile into the D,L-amino add amide, where upon a L-spedfic amidase converts the amide further into 50% L-amino add and 50% D-amino add amide. In this respect the method has no real advantage over the process of using a stereospecific L-aminopeptidase (vide supra). 

IJrocaninsaure aus Histidin (mit Achromobacter liquidum IAM 1667)3 l.-Asparaginsdure aus Ammoniumfumarat (mit Escherichia Coli ATCC 11 303)4 5 2 6 i.-Citridlin aus Arginin (mit Pseudomonas Putida ATCC 4359)7. 

Pseudomonas putida, Bacillus subtilis [l4C]Formate incorporates at C-2 of pyramine.78... 

Naphthalene carboxylate dioxygenase Pseudomonas putida U103 1976 [237] [224]... 

In our laboratory we have been investigating the mechanism of action of mandelic acid racemase from Pseudomonas putida (101), which catalyzes the racemization of either D or L-mandelic acid, 47. Evidence from kinetic and isotopic exchange studies indicates that the racemization proceeds via an... 

They are widely distributed across species. Bacteria possess cytochrome P450s, and P450cani (involved in the metabolism of camphor) of Pseudomonas putida is the only P450 isoform whose crystal stmcture has been established. 

Hegeman GD (1966) Synthesis of the enzymes of the mandelate pathway by Pseudomonas putida I synthesis of enzymes of the wild type. J Bacteriol 91 1140-1154. 

Tsou AY, SC Ransom, JA Gerlt, DD Buechter, PC Babbitt, GL Kenyon (1990) Mandelate pathway of Pseudomonas putida sequence relationships involving mandelate racemase, (5)-mandelate dehydrogenase, and benzoylformate decarboxylase and expression of benzoylformate decarboxylase in Escherichia coli. Biochemistry 29 9856-9862. 

Vercellone-Smith P, DS Herson (1997) Toluene elicits a carbon starvation response in Pseudomonas putida mt-2 containing the TOL plasmid pWWO. Appl Environ Microbiol 63 1925-1932. 

The oxidation by strains of Pseudomonas putida of the methyl group in arenes containing a hydroxyl group in the para position is, however, carried out by a different mechanism. The initial step is dehydrogenation to a quinone methide followed by hydration (hydroxylation) to the benzyl alcohol (Hopper 1976) (Figure 3.7). The reaction with 4-ethylphenol is partially stereospecific (Mclntire et al. 1984), and the enzymes that catalyze the first two steps are flavocytochromes (Mclntire et al. 1985). The role of formal hydroxylation in the degradation of azaarenes is discussed in the section on oxidoreductases (hydroxylases). 

The 4-methoxybenzoate monooxygenase from Pseudomonas putida shows low substrate specificity. Although it introduces only a single atom of oxygen into 3-hydroxy- and 4-hydroxybenzoate, it accomplishes the conversion of 4-vinylbenzoate into the corresponding side-chain diol (Wende et al. 1989). 

The initial hydroxylation in the degradation of some terpenes the ring methylene group of camphor by Pseudomonas putida (Katagiri et al. 1968 Tyson et al. 1972 Koga et al. 1986), and the isopropylidene methyl group of linalool by a strain of P. putida (Ullah et al. 1990). 

The reductive dehalogenation of polyhalogenated methanes (Castro et al. 1985) and polyhalogenated ethanes (Li and Wackett 1993) by Pseudomonas putida strain PpG786. 

The oxidation of f-butyl methyl ether to f-butanol (Steffan et al. 1997), which is also mediated by the cytochrome P450 from camphor-grown Pseudomonas putida CAM, but not by that from Rhodococcus rhodochrous strain 116. 

It is clear from the preceding comments that there is no absolute distinction between the oxygenase activities mediated by dioxygenases. This is even less clear for heteroarenes than it is for carbocyclic compounds. An illustrative example is provided by Pseudomonas putida strain 86 in which 8-hydroxy-quinol-2-one is produced from quinol-2-one (Rosche et al. 1997). 

Nonheme/ nonflavin Bacterium Pseudomonas putida Br Itoh et al. (1994)... 

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