The biosurfactant production can enhance the hydrocarbon biodegradation, as the hydrophobicity
of these compounds reduces the degradation rates. Much of the attention was given to microbial hydrocarbon
biodegradation, while limited work is present regarding the capacity of fungal biosurfactants for enhancing
the remediation process. This research work identified the potential of biosurfactant production and hydrocarbon degradation of selected fungal strains belonging to Aspergillus, Penicillium, and Candida genera in
contrast to a hydrocarbon-degrading and biosurfactant non-producing fungal strain. The highest biodegradation was noted for Aspergillus niger FA5 (90.7%), followed by Penicillium chrysogenum FP4 and Aspergillus
terreus FP6 (87.4 and 85.0%, respectively), and lastly, Candida sp. FG2 (80.1%). Biosurfactant-producing
hydrocarbon degrading fungal strains A. niger FA5, P. chrysogenum FP4, A. terreus FP6, and Candida sp. FG2
degraded hydrocarbons 1.32-, 1.27-, 1.24-, and 1.18-fold higher than non-producing A. flavus FP10 (68.6%).
When the data were analyzed for correlation, hydrocarbon degradation was found negatively corelated to surface tension (r = –0.747, p = 0.005), while positively correlated with emulsification index (r = 0.964, p <
0.001), and cell hydrophobicity (r = 0.835, p < 0.001). The results indicate that fungi capable of attaching
hydrocarbons at high concentration to the cell surface and effectively reducing surface tension were able to
exhibit significant improvements in the rate of hydrocarbon degradation. Hence, it is concluded that if a fungus can produce biosurfactant that can improve hydrocarbon emulsification and reduce surface tension, the
hydrocarbon breakdown can be accelerated from 12 to 22% compared to non-producers
