Pathways of hydrocarbon dissimilation by aPseudomonas as revealed by chloramphenicol

Pseudomonas aeruginosa cells pre-grown on a particular hydrocarbon will oxidize other hydrocarbons as well. Degradation of these hydrocarbons proceeds to a point — depending on their structure — where new enzymes are needed for further degradation. Lack of these enzymes causes accumulation of products. However, secondary adaptation processes tend to decrease yields of intermediates, in particular when adaptation rates are high.By inhibiting these secondary adaptation processes with chloramphenicol (CAM), the amounts of various intermediates could be increased.Propionic acid was accumulated from heptane by hexane-grown cells in yields up to 60% (molar) calculated on heptane converted. The effect of CAM suggests that propionic acid is not subject to -oxidation (acrylate pathway) but is degraded via methylmalonate by adaptive enzymes.2-Methylhexane was converted for 30–40% (molar) intoiso-valeric acid by heptane-grown cells. A known pathway ofiso-valeric acid oxidation incorporates a carbon dioxide fixation step, and lack of this enzyme in heptane-grown cells probably causesiso-valeric acid accumulation.Heptene-1 incubation with heptane-grown cells resulted in a 30–40% conversion into 4-pentenoic plus 2, 4-pentadienoic acids. 6-Heptenoic acid was detected occasionally. A predominant attack at C₇ of the heptene-1 molecule is indicated at least for heptane-grown cells. Attack on the saturated end of the molecule seems well in line with the assumption that alkane oxidation by these bacteria is effected by oxygen transferring enzymes operating on a methyl group, as opposed to the action of a dehydrogenase and formation of an -olefin as the intermediate.