A Marine Spring Clean: Bacteria Crave Oil Disasters!

The threat of oil pollution through both natural seepage and anthropogenic activities is a permanent danger to all marine biodiversity. Numerous genera of marine bacteria, fungi and algae are responsible for the degradation of the oil hydrocarbons, mainly due to the limited supply of nutrients ordinarily available to them in seawater. This ‘self cleaning’ function has generated a lot of scientific interest over time because of its practical applications in large oil spills. In the past, Biostimulation (addition of nutrients) and bioaugmentation (addition of hydrocarbon-degrading bacteria) have been tested in oil cleanup operations with varying degrees of success.

Following previous research, this study chose the bacteria Alcanivorax borkumensis for bioaugmentation trials, with the addition of other microorganisms to assist with the degradation of heavy, aromatic compounds. 25 microcosms were set up in duplicate, consisting of seawater from the island of Helgoland (some of which was sterilised) and heavy fuel oil. A number of these microcosms were augmented with the bacteria A. borkumensis (either purified or with other microbes), others with an absorptive sorbent made from textile or leather fibres (known as ‘X-Oil’), and fertiliser was added roughly half of them. These were incubated aerobically in the dark at 17^oC (the sample site temperature). 50ml of each microcosm was taken on a weekly basis for analysis, and the deficit replaced with 50ml of seawater. Analysis included DNA extraction and PCR, sequencing of DNA fragments and phylogenetic analysis.

The results of this study were numerous, but taken as a whole, a few key points act as an effective summary. In all cases, A. borkumensis was found to break down the oil pollutant in the samples. The speed of this decomposition was enhanced significantly with the addition of fertiliser, which resulted in the emulsification of the oil and therefore a larger surface area for increased bioavailability. Biofilm formation was also detected in the nutrient-enhanced samples due to these effects. The rate of oil degradation was again increased in samples containing the X-Oil sorbents, which provided a good habitat to decomposers and increased the emulsification speed in samples also containing fertiliser. Decomposition in pure samples of A. borkumensis and sterilised seawater was found be faster and more intense, but less thorough than samples containing other organisms. DNA analysis showed a decrease in microorganism diversity over time in all samples – a process that was sped up with the addition of fertiliser, and even more so with both fertiliser and X-Oil.

This study found that overall, A. borkumensis is an extremely effective bacterium to use in the mitigation of oil spills for two reasons:

-          It is proficient in the degradation of aliphatic hydrocarbons

-          It naturally promotes the growth of other microorganisms that can break down ‘heavier’ molecules, while inhibiting the rest

The authors of this paper conclude by stating that the use of A.borkumensis combined with the new X-Oil sorbents could become a useful tool for bioremediation in future marine oil disasters. X-Oil does require further investigation despite its success here however, as the use of leather and textiles in oil spill mitigation is new and used for the first time in this experiment.

A review of Gertler C., Gerdts G., Timmis K.N., Yakimov M.M. and Golyshin P.N. (2009) Populations of heavy fuel oil-degrading marine microbial community in presence of oil sorbent materials, Journal of Applied Microbioligy, 107, 590-605