Microbial growth on hydrocarbons: terminal branching inhibits biodegradation.

A variety of octane-utilizing bacteria and fungi were screened for growth on some terminally branched dimethyloctane derivatives to explore the effects of iso- and anteiso-termini on the biodegradability of such hydrocarbons. Of 27 microbial strains tested, only 9 were found to use any of the branched hydrocarbons tested as a sole carbon source, and then only those hydrocarbons containing at least one iso-terminus were susceptible to degradation. Anteiso-or isopropenyl termini prevented biodegradation. None of the hydrocarbonoclastic yeasts tested was able to utilize branched-hydrocarbon growth sustrates. In the case of pseudomonads containing the OCT plasmid, whole-cell oxidation of n-octane was poorly induced by terminally branched dimethyloctanes. In the presence of a gratuitous inducer of the octane-oxidizing enzymes, the iso-branched 2,7-dimethyloctane was slowly oxidized by whole cells, whereas the anteiso-branched 3,6-dimethyloctane was not oxidized at all. This microbial sampling dramatically illustrated the deleterious effect of alkyl branching, especially anteiso-terminal branching, on the biodegradation of hydrocarbons.

Biodegradation of acyclic isoprenoids by Pseudomonas species.

The ability of various pseudomonads to utilize acyclic isoprenoids as a sole carbon source was investigated. Tests for utilization of acyclic isoprenols such as citronellol and geraniol were complicated by toxic effects of these alcohols, and most species tested were killed by exposure to citronellol or geraniol (0.1%, vol/vol) in liquid culture. In the case of Pseudomonas citronellolis, sensitivity to isoprenols is reduced by prior induction of the isoprenoid degradative pathway via either growth on succinate in the presence of citronellol or growth on citronellic acid. For this species, citronellic acid proved to be the best isoprenoid growth substrate tested. Geraniol utilization as a taxonomic indicator for different subgroups of pseudomonads is discussed. Only a few of the species tested were able to utilize acyclic isoprenoids. Two species which utilize C10 acyclic isoprenoids, P. aeruginosa and P. mendocina, were shown to contain the inducible enzyme geranyl-coenzyme A carboxylase, one of the unique enzymes in the isoprenol degradative pathway known to occur in P. citronellolis. Of the species which utilized geranitol, none showed definite growth on the homologous C15 and C20 isoprenols.