Investigation of the Organic Solvent Resistance Mechanisms in Rhodococcus and Lysinibacillus Using Several Molecular Forensic Tools

Rhodococcus erythropolis IBB_Po5 (KM405337) and Lysinibacillus xylanilyticus IBB_Po7 (KM405338) showed good tolerance to 5% (v/v) organic solvents (alkanes, aromatics). However, 5% (v/v) alkanes (i.e., cyclohexane, n-hexane, n-decane) were less toxic for R. erythropolis IBB_Po5 and L. xylanilyticus IBB_Po7 cells, compared with 5% (v/v) aromatics (i.e., toluene, o-xylene, ethylbenzene). The high organic solvent tolerance of these two Gram-positive bacteria could be due to the presence in their genome of some catabolic (alkB1, todM, xylM) and trehalose-6-phosphate synthase (otsA1) genes. R. erythropolis IBB_Po5 possesses three catabolic genes (i.e., alkB1, todM, xylM), while L. xylanilyticus IBB_Po7 possesses only one catabolic gene (i.e., alkB1). Numerous adaptations involved in organic solvents tolerance were depicted in R. erythropolis IBB_Po5 and L. xylanilyticus IBB_Po7 cells exposed to 5% (v/v) alkanes and aromatics (i.e., changes in the cell growth rate, membrane permeability, cell morphology, biosurfactant emulsification index, carotenoids profile, DNA fingerprinting). Therefore, microbiological, biochemical, and DNA fingerprinting studies of the bacteria isolated from polluted environments could provide valuable information that may complement or supplement other forensic investigations.