Improving high carbon dioxide tolerance and carbon dioxide fixation capability of Chlorella sp. by adaptive laboratory evolution

Improving high carbon dioxide tolerance and carbon dioxide fixation capability of Chlorella sp. by adaptive laboratory evolution

CO2 capture by microalgae is a promising method to reduce greenhouse gas emissions. It is critical to construct a highly efficient way to obtain a microalgal strain tolerant to high CO2 concentrations with high CO2 fixation capability. In this study, two evolved Chlorella sp. strains, AE10 and AE20...

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Veröffentlicht in:Bioresource technology 2015-06, Vol.185, p.269-275
Hauptverfasser: Li, Dengjin, Wang, Liang, Zhao, Quanyu, Wei, Wei, Sun, Yuhan
Format: Artikel
Sprache:eng
Schlagworte:
Biomass
Bioreactors
Biotechnology - methods
Carbohydrates - chemistry
Carbon Dioxide - chemistry
Carotenoids - chemistry
Chlorella - metabolism
Chlorophyll - chemistry
Hydrogen-Ion Concentration
Lipids - chemistry
Microalgae
Phenotype
Pigmentation
Temperature
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Zusammenfassung:CO2 capture by microalgae is a promising method to reduce greenhouse gas emissions. It is critical to construct a highly efficient way to obtain a microalgal strain tolerant to high CO2 concentrations with high CO2 fixation capability. In this study, two evolved Chlorella sp. strains, AE10 and AE20 were obtained after 31 cycles of adaptive laboratory evolution (ALE) under 10% and 20% CO2, respectively. Both of them grew rapidly in 30% CO2 and the maximal biomass concentration of AE10 was 3.68±0.08g/L, which was 1.22 and 2.94 times to those of AE20 and original strain, respectively. The chlorophyll contents of AE10 and AE20 were significantly higher than those of the original one under 1-30% CO2. The influences of ALE process on biochemical compositions of Chlorella cells were also investigated. This study proved that ALE was an effective approach to improve high CO2 tolerance of Chlorella sp.
ISSN:0960-8524
1873-2976
DOI:10.1016/j.biortech.2015.03.011