Genetic and molecular organization of the alkylbenzene catabolism operon in the psychrotrophic strain Pseudomonas putida 01G3.

The 11-kb sequence encompassing the alkylbenzene upper pathway in Pseudomonas putida 01G3, a psychrotrophic strain able to degrade alkylbenzenes at low temperatures, was characterized. Together with a potential regulator (EbdR), six putative enzymes (EbdAaAbAcAdBC) were identified, and they exhibited highly significant similarities with enzymes implicated in the equivalent pathway in P. putida RE204. ebd genes appeared to be preferentially induced by ethylbenzene. Multiple-alignment data and growth rate measurements led us to classify 01G3 and closely related strains in two groups with distinct substrate specificities. Close to identified genes, remnants of IS5-like elements provided insight into the evolution of catabolic sequences through rearrangements from a less complex ancestral cluster.

Isolation of a soil psychrotrophic toluene-degrading Pseudomonas strain: influence of temperature on the growth characteristics on different substrates.

Two psychrotrophic toluene-degrading Pseudomonas putida strains were isolated at low temperature from a toluene-polluted soil, thereby demonstrating that toluene degradation at low temperature occurred in nature, a finding of possible interest for soil bioremediation procedures. In one of these strains, two aromatic compounds (toluene and benzoate) were degraded, most likely through different pathways. To study the effect of the growth temperature on the metabolism of these substrates, we studied the evolution of the maximal growth rates with respect to both temperature and substrate. It was shown that not only cardinal temperatures but also temperature characteristics deduced from the Arrhenius plot of maximal growth rates differed when the different substrates were used as sole carbon and energy source.