Oxidation enzyme-mediated

Chemiluminescence. Chemiluminescence (262—265) is the emission of light duting an exothermic chemical reaction, generaUy as fluorescence. It often occurs ia oxidation processes, and enzyme-mediated bioluminescence has important analytical appHcations (241,262). Chemiluminescence analysis is highly specific and can reach ppb detection limits with relatively simple iastmmentation. Nitric oxide has been so analyzed from reaction with ozone (266—268), and ozone can be detected by the emission at 585 nm from reaction with ethylene. 

The biomimetic approach to total synthesis draws inspiration from the enzyme-catalyzed conversion of squalene oxide (2) to lanosterol (3) (through polyolefinic cyclization and subsequent rearrangement), a biosynthetic precursor of cholesterol, and the related conversion of squalene oxide (2) to the plant triterpenoid dammaradienol (4) (see Scheme la).3 The dramatic productivity of these enzyme-mediated transformations is obvious in one impressive step, squalene oxide (2), a molecule harboring only a single asymmetric carbon atom, is converted into a stereochemically complex polycyclic framework in a manner that is stereospecific. In both cases, four carbocyclic rings are created at the expense of a single oxirane ring. 

Enzyme-mediated oxidation reactions offer highly diverse options for the modification of existing functional groups as well as for the introduction of novel function in chiral catalysis. Biooxidations often enable us to obtain complementary solutions to metal-assisted transformations and organocatalysis and are considered one of the important strategies of green chemistry . 

The enzyme-mediated Baeyer-Villiger oxidation to chiral lactone intermediates has received considerable attention in recent years as it offers several advantages in chemo-, regio-, and stereoselectivity compared to other catalytic strategies... 

The oxidation of heteroatoms and, in particular, the conversion of sulfides to asymmetric sulfoxides has continued to be a highly active field in biocatalysis. In particular, the diverse biotransformations at sulfur have received the majority of attention in the area of enzyme-mediated heteroatom oxidation. This is particularly due to the versatile applicability of sulfoxides as chiral auxiliaries in a variety of transformations coupled with facile protocols for the ultimate removal [187]. 

A successful case study for asymmetric nitrogen oxidation was reported for a series of (hetero)aromatic tertiary amines. High diastereoselectivity was observed for the enzyme-mediated oxidation of S-(—)-nicotine by isolated CHMOAdneto to give the corresponding ds-N-oxide [215]. The stereoselectivity of this biooxidation was complementary to the product obtained by flavin M O (FM O) from human li ver (trows-selective [216]) as well as unspecific oxidations by FMOs from porcine and guinea pig liver. 

Besides the numerous examples of anionic/anionic processes, anionic/pericydic domino reactions have become increasingly important and present the second largest group of anionically induced sequences. In contrast, there are only a few examples of anionic/radical, anionic/transition metal-mediated, as well as anionic/re-ductive or anionic/oxidative domino reactions. Anionic/photochemically induced and anionic/enzyme-mediated domino sequences have not been found in the literature during the past few decades. It should be noted that, as a consequence of our definition, anionic/cationic domino processes are not listed, as already stated for cationic/anionic domino processes. Thus, these reactions would require an oxidative and reductive step, respectively, which would be discussed under oxidative or reductive processes. 

Mihovilovic, M.D. (2006) Enzyme mediated Baeyer-Villiger oxidations. Current Organic Chemistry, 10 (11), 1265-1287. 

It is difficult to understand the oxidative pathways without an understanding of the enzymes that mediate them therefore, we will start with a discussion of the oxidative enzymes with examples of specific oxidations that each enzyme meditates. This will be followed by a discussion of metabolic pathways organized according to functional groups. 

Zhang and Dryhurst studied the electrochemical and enzyme-mediated oxidation of tetrahydropapaveroline 66 with the objective of investigating the oxidation chemistry and isolating the major oxidation products [91]. The... 

Denitrification occurs only in the presence of oxidized nitrogen and in an environment with limited (whieh prevails in the subsurfaee). Beeause denitrifieation is an enzyme-mediated reaetion, the substrate concentration funetions as a rate-determining factor. The dominant denitrifying bacteria are heterotrophie. The favored environmental conditions for the growth of denitrifying baeteria include a neutral pH (6-8), a favorable water-air (oxygen) ratio, and a subsurface temperature between 20 and 30°C. 

Bioprocesses incorporating more than one redox enzyme in an oxidative reaction system might involve, in the simplest case, two oxidizing enzymes coupled so that they act sequentially to effect two oxidation steps. A key issue in the development of such oxidative biocatalytic systems would be the determination of the values, for each enzyme involved, of the redox potentials. These can be determined by potentiometric titration using redox mediators (such as NADH) and techniques such as cyclic voltammetry or electrophoresis [44]. Knowledge of the redox potentials would facilitate the design and engineering of a process in which the two... 

The involvement of isobutylhydroxylamine, (CH3)2CHCH2NH—OH (4), and of HA (NH2OH) in the biosynthesis of the antibiotics valanimycin (5) and nebularine (6), respectively, has been demonstrated in Streptomyces species (see Section n.B). In the case of nebularine, HA is released in the final step of its production by enzymatically induced deamination of adenosine, while the isobutylhydroxylamine is a precursor for the biosynthesis of valanimycin. In cyanobacterium, the presence of free and bound HA was demonstrated to be a product of enzyme-mediated glutamine oxidation ... 

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