Transcriptomic analysis of Chlorella sp. HS2 suggests the overflow of acetyl‐CoA and NADPH cofactor induces high lipid accumulation and halotolerance

Previously, we isolated Chlorella sp. HS2 (referred hereupon as HS2) from a local tidal rock pool and demonstrated its halotolerance and high biomass productivity under different salinity conditions. To further understand acclimation responses of this alga under high salinity stress, we performed tr...

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Bibliographic Details
Published in:Food and energy security 2021-02, Vol.10 (1), p.n/a
Main Authors: Yun, Jin‐Ho, Pierrelée, Michaël, Cho, Dae‐Hyun, Kim, Urim, Heo, Jina, Choi, Dong‐Yun, Lee, Yong Jae, Lee, Bongsoo, Kim, HyeRan, Habermann, Bianca, Chang, Yong Keun, Kim, Hee‐Sik
Format: Article
Language:English
Subjects:
ABC transporter
Acclimation
Acclimatization
acetyl‐CoA
Algae
Biomass
Carbohydrates
Cell culture
Cellular stress response
Chlorella
Chlorella sp. HS2
Crops
DNA
DNA repair
Freshwater
Gene expression
Glycolysis
halotolerance
Inland water environment
Life Sciences
lipid synthesis
Lipids
Metabolism
Overflow
Oxidative stress
Photosynthesis
Photosystem
Productivity
Reactive oxygen species
RNA‐seq
Salinity
Salinity effects
Salinity tolerance
Salt
Storage
Thylakoids
Triglycerides
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Summary:Previously, we isolated Chlorella sp. HS2 (referred hereupon as HS2) from a local tidal rock pool and demonstrated its halotolerance and high biomass productivity under different salinity conditions. To further understand acclimation responses of this alga under high salinity stress, we performed transcriptome analysis of triplicated culture samples grown in freshwater and marine conditions at both exponential and stationary growth phases. The results indicated that the transcripts involved in photosynthesis, TCA, and Calvin cycles were downregulated, whereas the upregulation of DNA repair mechanisms and an ABCB subfamily of eukaryotic type ABC transporter was observed at high salinity condition. In addition, while key enzymes associated with glycolysis pathway and triacylglycerol (TAG) synthesis were determined to be upregulated from early growth phase, salinity stress seemed to reduce the carbohydrate content of harvested biomass from 45.6 dw% to 14.7 dw% and nearly triple the total lipid content from 26.0 dw% to 62.0 dw%. These results suggest that the reallocation of storage carbon toward lipids played a significant role in conferring the viability of this alga under high salinity stress by remediating high level of cellular stress partially resulted from ROS generated in oxygen‐evolving thylakoids as observed in a direct measure of photosystem activities. Allocation of storage carbon toward the synthesis of lipids seemed to play a critical role in conferring the halotolerance of a Chlorella isolate by remediating excess oxidative stress experienced in photosystems.
ISSN:2048-3694
2048-3694
DOI:10.1002/fes3.267