Quinoline hydroxylation

In the dehydrogenation of cis- and trans-1 -methyldecahydro-quinolines, hydroxylation takes place by the following mechanism 177... 

In opocinchenine the hydroxyl group must, therefore, be in the ortho-position relative to the point of attachment of the benzene ring to the quinoline nucleus. The relative positions of the two ethyl groups are determined by the fact that apocincheninic acid ethyl ether on oxidation with lead peroxide and sulphuric acid gives the lactone of hydroxyopo-cincheninic acid ethyl ether (I), which, on oxidation by sodium hypo-bromite, yields quinolylphenetoledicarboxylic acid (II). 

The lithium- -propylamine reducing system has been found capable of reducing julolidine (113) to /d -tetrahydrojulolidine (114, 66% yield) and 1-methyl-1,2,3,4-tctrahydroquinoline to a mixture of enamines (87% yield), l-methyl-J -octahydroquinoline (115) and 1-methyl-al -octahydro-quinoline (116) 102). This route to enamines of bicyclic and tricyclic systems avoids hydroxylation, which occurs during mercuric acetate oxidation of certain bicyclic and tricyclic tertiary amines 62,85 see Section III.A). 

Reaction of 2,4,7-trichloroquinoline with sodium methoxide (65°, 30 min) yielded an equal mixture of 2,7-dichloro-4-methoxy- (40%) and 4,7-dichloro-2-methoxy-derivatives (31%). The activating effect of the chloro groups is evident from the inertness of 4-chloro-quinoUne to methoxide ion at 65°. Alteration of the relative reactivity by cationization of the azine ring is again noted here in the acid-catalyzed hydrolysis (dilute HCl, 100°, 1.5 hr) of the trichloro compound to give 72% of the 2-hydroxylation product.Similarly, acid-hydrolysis of the alkoxy group proceeds much more readily in 2-ethoxy-4-chloro- than in 4-ethoxy-2-chloro-quinoline. ... 

The yield of hydroxylated products is always very low, and there are usually a number of by-products. For instance, side chains of aromatic nuclei are easily attacked, as shown by the formation of 5-hydroxymethyluracil from thymine. Breslow and Lukens measured both the amount of 3-hydroxyquinoline formed and the quinoline consumed during hydroxylation with Fenton s reagent and EDTA in the presence of several adducts (Table XII). 

Udenfriend et al. observed that aromatic compounds are hydroxyl-ated by a system consisting of ferrous ion, EDTA, ascorbic acid, and oxygend Aromatic and heteroaroinatic compounds are hydroxylated at the positions which are normally most reactive in electrophilic substitutions. For example, acetanilide gives rise exclusively to the o-and p-hydroxy isomers whereas quinoline gives the 3-hydroxy prod-uct. - The products of the reaction of this system w ith heterocyclic compounds are shown in Table XIII. 

Among the tasks remaining is the replacement of the C-16 hydroxyl group in 16 with a saturated butyl side chain. A partial hydrogenation of the alkyne in 16 with 5% Pd-BaS04 in the presence of quinoline, in methanol, followed sequentially by selective tosylation of the primary hydroxyl group and protection of the secondary hydroxyl group as an ethoxyethyl ether, affords intermediate 17 in 79% overall yield from 16. Key intermediate 6 is formed in 67 % yield upon treatment of 17 with lithium di-n-butylcuprate. 

In a related procedure, even benzene and substituted benzenes (e.g., PhMe, PhCl, xylenes) can be converted to phenols in good yields with sodium perborate F3CS020H. " Aromatic amines, N-acyl amines, and phenols were hydroxylated with H2O2 in SbFs—HF. Pyridine and quinoline were converted to their 2-acetoxy derivatives in high yields with acetyl hypofluorite AcOF at -75°C. ... 

The enzymes from Comamonas testosteroni for hydroxylation of quinoline to quinol-2-one (quinoline 2-oxidoreductase) and the dioxygenase responsible for the introduction of oxygen into the benzenoid ring (2-oxo-l,2-dihydroquinoline 5,6-dioxygenase) have been described (Schach et al. 1995). 

De Beyer A, F Lingens (1993) Microbial metabolism of quinoline and related compounds XVI. Quinaldine oxidoreductase from Arthrobacter spec. Rii 61a a molybdenum-containing enzyme catalysing the hydroxylation at C-4 of the heterocycle. Biol Chem Hoppe-Seyler 374 101-120. 

Although pyridines and quinolines were first produced during the carbonization of coal, they are now available by synthesis in quantities that far exceed those by the former. Phosphorylated ribosides of hydroxylated and aminated pyrimidines and purines make up the basic structure of ribonucleic and deoxyribonucleic acids. The polycyclic oxaarenes are plant metabolites, while thiaarenes are primarily important components of high-sulfur petroleum that must be removed. 

Peczyfiska-Czoch W et al. (1996) Microbial transformation of azacarbazoles X re-gioselective hydroxylation of 5,ll-dimethyl-5ff-indolo[2,3-l)]quinoline, a novel DNA topoisomerase 11 inhibitor, hy Rhizopus arrhizus. Biotechnol Lett 18(2) 123-128... 

Thus we would expect the phosphorescence efficiency to be greater for the first case than the second. In agreement with this conclusion, Similar effects are observed for heterocycles for example, the phosphorescence quantum yield for pyrazine (lowest n, it triplet) is 0.30(119) while that for quinoline in a hydroxylic solvent (lowest 77,77 triplet) is 0.19/305... 

Kaiser et al. reviewed the microbial metabolism of different nitrogen compounds [320], There is agreement among the authors in suggesting an initial step in the transformation of quinoline (by whole cells) that consists of a hydroxylation at position 2 of the heterocyclic aromatic ring, leading to 2-hydroxyquinoline (see Fig. 21 [321]). 

Further transformation included additional hydroxylation steps leading to 2,6-dihydroxyquinoline and a trihydroxyquinoline (probably 2,5,6-trihydroxyquinoline). Shukla [322], working with Pseudomonas sp. identified an alternate pathway, involving additional metabolites, besides the 2-hydroxyquinoline and 8-hydroxycoumarin. These were 2,8-dihydroxyquinoline and 2,3-dihydroxyphenylpropionic acid. Quinoline-adapted cells were also able to transform 2-hydroxyquinoline and 8-hydroxycoumarin without a lag phase, providing additional support for their intermediate role as intermediates in the metabolism of quinoline. 

As can be seen, in both the 5,6- and the 7,8-dihydroxy-2(lH)quinolinone pathways, after initial hydroxylation adjacent to the N-heteroatom, the benzene moiety of the quinoline ring is transformed to a dihydroxy derivative 5,6- or 7,8-, respectively, which subsequently undergoes ring cleavage. However, neither of them involves C—N bond cleavage and consequently do not lead to denitrogenated products. 

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