Reversible accumulation of p-hydroxybenzoate and catechol determines the sequential decomposition of phenolic compounds in mixed substrate cultivations in pseudomonads

Abstract

Accumulation of key catabolic intermediates during degradation of phenol, p-cresol and benzoate was studied in two-substrate batch cultivations by the strains Pseudomonas mendocina PC1, Pseudomonas fluorescens PC18 and P. fluorescens PC24. According to sequence analysis of 16S rRNA genes the strains belonged to different monophyletic clusters of Pseudomonas. The catechol 2,3-dioxygenase (C23O) gene, xylE, of strain PC1 and the phenol monooxygenase gene, pheA, of PC24 were localised on the chromosome, while the C23O gene, xylE, of strain PC18 and the p-cresol methylhydroxylase gene, pchF, of strains PC18 and PC24 were on plasmids. It was shown that, if the substrates were degraded from mixtures using either catechol meta, catechol ortho or catechol ortho and protocatechuate ortho pathways, then both substrates were catabolised simultaneously (nondiauxic growth) without the accumulation of intermediates. Exceptionally, degradation of phenol and benzoate via the catechol ortho pathway caused irreversible accumulation of cis,cis-muconate without detectable effect on simultaneous consumption of substrates. When the substrates were degraded from mixtures through meta and ortho catabolic pathways, the sequential consumption of substrates (diauxic growth) was observed due to the reversible accumulation of the catabolic intermediates p-hydroxybenzoate or catechol. Regulation of parallel catabolic pathways by the accumulation of catabolic intermediates depended on the concentration of growth substrates. At low concentrations simultaneous degradation occurred and the antagonistic effect of p-hydroxybenzoate on the degradation of phenol was diminished. In strain PC18 only the accumulation of p-hydroxybenzoate during growth on a phenol–p-cresol mixture seems to be directly metabolically regulated because phenol also induces the catabolic pathway for p-cresol degradation. Partial sequencing of the pchF genes of strains PC18 and PC24 showed considerable differences.