Strain improvement of Chlorella sp. for phenol biodegradation by adaptive laboratory evolution
- PMID: 26803904
- DOI: 10.1016/j.biortech.2016.01.022
Strain improvement of Chlorella sp. for phenol biodegradation by adaptive laboratory evolution
Abstract
Microalgae are highly efficient photosynthesis cell factories for CO2 capture, biofuel productions and wastewater treatment. Phenol is a typical environmental contaminant. Microalgae normally have a low tolerance for, and a low degradation rate to, high concentration of phenol. Adaptive laboratory evolution was performed for phenolic wastewater treatment by Chlorella sp. The resulting strain was obtained after 31 cycles (about 95d) under 500mg/L phenol as environmental stress. It could grow under 500mg/L and 700mg/L phenol without significant inhibition. The maximal biomass concentrations of the resulting strain at day 8 were 3.40g/L under 500mg/L phenol and 2.70g/L under 700mg/L phenol, respectively. They were more than two times of those of the original strain. In addition, 500mg/L phenol was fully removed by the resulting strain in 7d when the initial cell density was 0.6g/L.
Keywords: Adaptive laboratory evolution; Microalgae; Phenol biodegradation; Wastewater treatment.
Copyright © 2016 Elsevier Ltd. All rights reserved.
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