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We have conducted a series of degradation experiments to measure the efficacy of the newly engineered strains containing optimized synthetic phenanthrene and fluorene degradation pathway, demonstrating the bacteria's ability to harness the PAHs as a carbon source and ultimately degrading the compounds. These bacteria can be incorporated in oil spill remediation and bioreactor use as commercial product, achieving detoxification through combinatorial genetic bioremediation. | We have conducted a series of degradation experiments to measure the efficacy of the newly engineered strains containing optimized synthetic phenanthrene and fluorene degradation pathway, demonstrating the bacteria's ability to harness the PAHs as a carbon source and ultimately degrading the compounds. These bacteria can be incorporated in oil spill remediation and bioreactor use as commercial product, achieving detoxification through combinatorial genetic bioremediation. | ||
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Revision as of 01:03, 2 November 2017
applied design
Contamination cleaning up processes include skimming the oil into containment tanks - an approach that cannot be applied on high seas and bad weather conditions- and in situ burning - an approach that may create additional pollutants. Chemical dispersants are sometimes added to break down oil spills; however, the breakdown products may be absorbed by marine organisms and thus entered the food chain.
Clearly, bioremediation using microorganisms that naturally use crude oil as a source for growth and at the same degrade it is the preferred approach. Up to now, bioremediation approaches have mostly targeted microorganisms already present in the ecosystem where the oil spill occurs. However, this approach has limited results because the decontamination can take decades because of slow degradation rate. Fertilizers such as nitrogen and phosphorous may be added to enhance their activities with the risk of local pollution. The newest bioremediation products include a mixture of microorganisms that are able to deplete linear alkanes whereas the PAH class may not be degraded at all.
All these approaches have clear limitations. Therefore, there is the need for a commercially viable means of degrading PAHs in oil spills. Our approach offers a novel methodology for the degradation of multiple PAHs through the implementation of bacteria-derived pathways into E. coli. This methodology allows broad spectrum degradation of PAHs within an oil environment into safer residues.
To be able to degrade as many aromatic components as possible, our approach is to converge catabolic pathways and employ gene augmentation. This approach is possible because there are some intermediates that are common between pathways. To that end, we have cloned the genes upstream of the common intermediates of the phenanthrene and fluorene pathways and introduced them into a bacteria that would already have the ability to metabolize the downstream intermediates. In other words, the host strain already has a piece of the pathway, and by a process of engineering, we are augmenting its gene pool and thus its capacity of degradation. The advantage is that the product is universal meaning that it can degrade many chemical species of PAHs.
We have conducted a series of degradation experiments to measure the efficacy of the newly engineered strains containing optimized synthetic phenanthrene and fluorene degradation pathway, demonstrating the bacteria's ability to harness the PAHs as a carbon source and ultimately degrading the compounds. These bacteria can be incorporated in oil spill remediation and bioreactor use as commercial product, achieving detoxification through combinatorial genetic bioremediation.