Reductive enzymes carbonyl reductases

Baker s yeast has been widely used for the reduction of ketones. The substrate specificity and enantioselectivity of the carbonyl reductase from baker s yeast, which is known to catalyze the reduction of P-keto ester to L-hydroxyester (L2-enzyme) [15], was investigated, and the enzyme was found to reduce chloro-, acetoxy ketones with high enantioselectivity (Figure 8.32) [24aj. 

The usefulness of the carbonyl reductase from Candida magnoliae as an enzyme catalyst in the synthesis of chiral alcohol intermediates has been demonstrated by carrying out the reduction of several ketones on a preparative scale [56]. The isolated yields and enantiomeric excess of the product alcohols are summarized in Table 7.1, from which it can be seen that these chiral alcohols were obtained in essentially optically pure forms in excellent yields. These chiral alcohols are important intermediates in the synthesis of pharmaceuticals and agrichemicals. For example, optically active 2-hydroxy-3-methylbutyrate is an important chiral synthon... 

Zhu, D., Yang, Y., Buynak, J.D. and Hua, L. (2006) Stereoselective ketone reduction by a carbonyl reductase from Sporobolomyces salmonicolor. Substrate specificity, enantioselectivity and enzyme—substrate docking studies. Organic and Biomolecular Chemistry, 4 (14), 2690-2695. 

The carbonyl reductases catalyze reduction of aldehydes and ketones by reduced pyridine nucleotides (NADH and/or NADPH). As mentioned earlier, alcohol dehydrogenase can perform this function in the presence of a high ratio of NADH to NAD+. Other enzymes capable of carbonyl reduction include the aldehyde and ketone reductases. The aldehyde and ketone reductases have a ubiquitous species distribution, with the enzymes present in organisms ranging from bacteria to vertebrates. The mammalian carbonyl reductases have been extensively reviewed (101). 

There are a number of findings suggesting that agents that facilitate elimination of protein carbonyls (by either proteolytic elimination or by enzymically mediated chemical reduction) may suppress neurodegenerative conditions in model systems (Botella et al., 2004). Consequently, as carnosine may also react with protein carbonyls, it is theoretically possible that it could suppress formation and /the reactivity of protein carbonyls in the brain. Whether carnosine participates in carbonyl reductase activity has not been investigated but it is also a reasonable speculation. 

In a photometric assay NADP(H)-dependent LBADH (see above) [9] and NAD(H) -dependent Candida parapsilosis carbonyl reductase (CPCR) [40] were identified as suitable catalysts accepting a broad range of ynones as substrates. Both enzymes catalyze the reduction of various aryl alkynones 21 with high enantioselectivity and efficiency (Scheme 2.2.7.13) [41]. 

Dehydrogenases often act primarily to reduce a carbonyl compound rather than to dehydrogenate an alcohol. These enzymes may still be called dehydrogenases. For example, in the lactic acid fermentation lactate is formed by reduction of pyruvate but we still call the enzyme lactate dehydrogenase. In our bodies this enzyme functions in both directions. However, some enzymes that act mainly in the direction of reduction are called reductases. An example is aldose reductase, a member of a family of aldo-keto reductases71 73 which have (a / P)8-barrel structures.74 76... 

The enzyme catalyzing the reduction of ketopantolactone to D-pantolactone was isolated in a crystalline form from the cells of Candida parapsilosis and characterized in some detail [106] (see Tables 4 and 5). It is a novel NADPH-dependent carbonyl reductase with a molecular mass of about 40,000. In addition to the reduction of ketopantolactone, the enzyme catalyzes those of a variety of cyclic diketones, including derivatives of ketopantolactone, isatin, camphorquinone and so on, to give the corresponding (R)-alcohols [106, 107], The enzyme was termed conjugated polyketone reductase , since the enzyme catalyzes only the reduction of conjugated polyketones as follows. 

Carbonyl reductases and alcohol and aldehyde dehydrogenases are cytosolic enzymes being involved in the oxidation of alcohols and aldehydes and in the reduction of aldehydes and ketones (Lang and Kalgutkar 2003). 

This bioreduction system is applicable to the production of many other useful chiral alcohols by replacing the carbonyl reductase gene with that of another appropriate enzyme for carbonyl reduction (Fig. 19.6). A good library of microbial carbonyl reductases with different substrate and stereospecifici-... 

Synthetic statins are important lipid regulating drugs for the treatment of atherosclerosis and other diseases related to hyperlipidaemia, especially coronary heart disease. As the pharmacophore, all synthetic statins contain a saturated or partially unsaturated syn-3,5-dihydroxy C7-carboxylate. An important building block for the synthesis of the side chain is represented by 4-chloro-3-hydroxybutanoate esters (CHBE). Both enantiomers can be obtained by enzyme-catalyzed reduction of the (1-keto ester. The group of Kataoka and Shimizu found that an aldehyde reductase of Sporobolomyces salmonicolor [161] and a carbonyl reductase of Candida... 

In addition to this, that an interesting novel emulsion membrane reactor concept overcomes the difficulties of the large solvent volume otherwise required for the reduction of poorly soluble ketones [30]. 2-Octanone was reduced by a carbonyl reductase from Candida parapsilosis to (S)-2-octanol with > 99.5 % ee and total turnover number of 124 - the 9-fold value of that obtained in a classical enzyme reactor. 

Oxidoreductases these enzymes catalyze redox reactions. Examples are oxidases that catalyze oxidation of a substrate by reducing molecular oxygen (02), and peroxidases that reduce H202. Laccases (EC 1.10.3.2) are oxidases that catalyze the oxidation of (poly)phenolic substrates. Reductases and dehydrogenases (EC 1.1.1) catalyze the reduction of carbonyls, using NADH/NADPH cofactors. Catalases (EC 1.11.1.6) catalyze the decomposition of H202 to 02 and H20. 

Besides these examples, many other important enzymes for biocatalytic reductions, such as the NADPH-dependent carbonyl reductase from Candida magnoliae U2 the ketoreductase from Zygosaccharomyces rowxii11431, and the aldehyde reductase from Sporobolomyces salmonicolor AKU442911441, etc. have also been expressed in E. coli etc. and shown to be active. 

The reductive biotransformation of drugs has been one of the least studied reactions, and many of the enzymes that are involved have not been well characterized. Some of the enzymes that catalyze reductive reactions of drugs are the cytochrome P450s, molybdenum reductases, alcohol dehydrogenases, carbonyl reductases, NADPH cytochrome P450 reductase, NAD(P)H— quinone oxidoreductases, and enzymes of the intestinal microflora (Matsunaga et al., 2006 Rosemond and Walsh, 2004). 

Both alcohol dehydrogenases and carbonyl reductases are cytosolie enzymes that catalyze the reduction of aldehydes to primary alcohols however, earbonyl reductases also eatalyze the reduction of ketones to alcohols. Whereas aleohol dehydrogenases utilize NADH as a cofactor, the carbonyl reductases utilize NADPH (Rosemond and Walsh, 2004) ... 

Dehydrogenases and reductases are enzymes that catalyze the reduction of carbonyl groups. The natural substrates of the enzymes are alcohols, such as ethanol, lactate, glycerol, and the corresponding carbonyl compounds however, unnatural ketones can also be reduced enantioselectively. To exhibit catalytic activities, the enzymes require a coenzyme such as NADH or NADPH from which a hydride is transferred to the substrate carbonyl carbon. 

The biocatalytic counterpart for this transformation is done by the alcohol dehydrogenases [ADHs, EC 1.1.1.x., also called ketoreductases (KREDs) or carbonyl reductases (CRs)], which are able to perform stereoselective carbonyl reductions or enantioselective alcohol oxidations [5-8]. These enzymes are probably the most employed oxidoreductases and make use of a nicotinamide cofactor such as NADH or NADPH to transfer electrons into and from the target substrate. Depending on their substrate scope, ADHs can be divided into primary alcohol dehydrogenases, preferentially reducing aldehydes, and secondary alcohol dehydrogenases that have... 

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