The Microbioloǵical Deǵradation of Aromatic Compounds

References

1. Ayengar P. K., Hayaishi O., Nakajima M., Tomida I. 1959; Enzymic aromatization of 3,5-cyclohexadiene-l,2-diol. Biochim. biophys. Acta 33:111
   [Google Scholar]
2. Behrman E. J., Tanaka T. 1959; The quinoline pathway of tryptophan oxidation by Pseudomonas: the initial steps in the oxidation of kynurenic acid. Biochem. biophys. Res. Comm 1:257
   [Google Scholar]
3. Chapman P. J., Dagley S. 1962; Oxidation of homogentisic acid by cell-free extracts of a Vibrio. J. gen. Microbiol 28:251
   [Google Scholar]
4. Clarke F. M., Fina L. R. 1952; The anaerobic decomposition of benzoic acid during methane fermentation. Arch. Biochem 36:26
   [Google Scholar]
5. Colla C., Fiecchi A., Treccani V. 1959; Ricerche sul metabolismo ossidativo microbico dell’antracene e del fenantrene. Nota II. Isolamento e caratterizzazione del 3,4-diidro-3,4-diossifenantrene. Ann. Microbiol, e Enzimol 9:87
   [Google Scholar]
6. Coulson C. B., Evans W. C. 1959; Microbiological degradation of trans-cinnamic acid by soil Pseudomonads. J. Soc. chem. Ind., Lond p 543
   [Google Scholar]
7. Dagley S., Evans W. C., Ribbons D. W. 1960; New pathways in the oxidative metabolism of aromatic compounds by micro-organisms. Nature, Lond 188:560
   [Google Scholar]
8. Dagley S., Stopher D. A. 1959; A new mode of fission of the benzene nucleus by bacteria. Biochem. J 73:16P
   [Google Scholar]
9. Davies J. I., Evans W. C. 1962; Ring fission of the naphthalene nucleus by certain soil Pseudomonads. Biochem. J 85:21P
   [Google Scholar]
10. Evans W. C., Gaunt J. K., Davies J. I. 1961; The metabolism of the chloropheno-xyacetic acid herbicides by soil micro-organisms. Proc. 5th int. Congr. Biochem,., Moscow Sec 14:306
    [Google Scholar]
11. Fernley H. N., Evans W. C. 1958; Oxidative metabolism of polycyclic hydrocarbons by soil Pseudomonads. Nature, Bond 182:373
    [Google Scholar]
12. Fina L. E., Fiskin A. M. 1960; The anaerobic decomposition of benzoic acid during methane fermentation. II. Fate of carbons 1 and 7. Arch. Biochem 91:163
    [Google Scholar]
13. Gholson R. K., Nishizuka Y., Ichiyama A., Kawai H., Nakamura S., Hayaishi O. 1962; New intermediate in the catabolism of tryptophan in mammalian liver. J. biol. Chem 237:2043
    [Google Scholar]
14. Hayaishi O., Katagiri M., Rothberg S. 1957; Studies on oxygenases; pyrocatechase. J. biol. Chem 229:905
    [Google Scholar]
15. Hosokawa K., Nakagawa H., Takeda Y. 1961; Cofactor requirements for anthranilate oxidase. J. Biochem., Tokyo 49:355
    [Google Scholar]
16. Ichihara A., Adachi K., Hosokawa K., Takeda Y. 1962; The enzymatic hydroxylation of aromatic carboxylic acids; substrate specificities of anthranilate and benzoate oxidases. J. biol. Chem 237:2296
    [Google Scholar]
17. Ingraham LL. L. 1962 Biochemical Mechanisms New York: Wiley and Sons Inc;
    [Google Scholar]
18. Katagiri M., Yamamoto S., Hayaishi O. 1962; Flavin adenine dinucleotide requirement for the enzymatic hydroxylation and decarboxylation of salicylic acid. J. biol. Chem 237:2413
    [Google Scholar]
19. Kojima Y., Itada N., Hayaishi O. 1961; Metapyrocatechase: a new catecholcleaving enzyme. J. biol. Chem 236:2223
    [Google Scholar]
20. Kuno S., Tashiro M., Taniuchi H., Horibata K., Hayaishi O. 1961; Enzymatic degradation of kynurenic acid. Fed. Proc 20:3
    [Google Scholar]
21. Mare E. K., Stone R. W. 1959; The bacterial oxidation of benzene. Dissertation Abstr 20460
    [Google Scholar]
22. Mason H. S. 1957; Mechanisms of oxygen metabolism. Advanc. Enzymol 14:79
    [Google Scholar]
23. Nishizuka Y., Ichiyama A., Nakamura S., Hayaishi O. 1962; A new metabolic pathway of catechol. J. biol. Chem 237:268
    [Google Scholar]
24. Proctor M. H., Scher S. 1960; Decomposition of benzoate by a photosynthetic bacterium. Biochem. J 76:33 P
    [Google Scholar]
25. Pullman A., Pullman B. 1955 Cancerisation par les substances chemiques et structure moleculaire Paris: Masson et Cie;
    [Google Scholar]
26. Ribbons D. W., Evans W. C. 1960; Oxidative metabolism of phthalic acid by soil Pseudomonads. Biochem. J 76:310
    [Google Scholar]
27. Ribbons D. W., Evans W. C. 1962; Oxidative metabolism of protocatechuic acid by certain soil Pseudomonads: A new ring-fission mechanism. Biochem. J 83:482
    [Google Scholar]
28. Roberts F. F. 1962 Metabolism of benzoate by methane bacteria M.Sc. Thesis Kansas State University, U.S. A;
    [Google Scholar]
29. Rogoff M. 1962; Chemistry of oxidation of polycyclic aromatic hydrocarbons by soil Pseudomonads. J. Bad 83:998
    [Google Scholar]
30. Taniuchi H., Kojima Y., Kanetsuna F., Ochiai H., Hayaishi O. 1962; Mechanism of the autoxidation of oxygenases. Biochem. biophys. Res. Comm 8:96
    [Google Scholar]
31. Walker N., Wiltshire G. H. 1953; The breakdown of naphthalene by a soil bacterium. J. gen. Microbiol 8:273
    [Google Scholar]
32. Webley D. M., Duff R. B., Farmer V. C. 1955; Beta-oxidation of fatty acids by Nocardia opaca. J. gen. Microbiol 13:361
    [Google Scholar]
33. Woodings E. T. 1961; The microbial dissimilation of aromatic methyl ethers. Dissertation Abstrs 212438
    [Google Scholar]
34. Yano K., Arima K. 1958; Metabolism of aromatic compounds by bacteria. II. m-hydroxybenzoic acid hydroxylase A and B; 5-dehydroshikimic acid, a precursor of protocatechuic acid; pathway from salicylic acid to gentisic acid. J. appl. Microbiol 4:241
    [Google Scholar]