Aims: Astaxanthin-producing protist Aurantiochytrium limacinum can accumulate higher amounts of astaxanthin under light conditions; however, little is known about the impact of light exposure on its metabolism. Here, we investigated the transcriptional profile of A. limacinum under light conditions. Methods and Results: Transcriptomic analyses revealed that 962 genes of A. limacinum showed a significant change in expression under light conditions, most of which (94.5%) were downregulated. Furthermore, gene ontology enrichment analysis indicated that A. limacinum mainly downregulated genes associated with cell motility, proliferation and gene expression processes, whose activities depend on ATP as an energy source. Additionally, the quantification of carotenoid and its transcripts suggested that βcarotene and astaxanthin biosynthesis pathways were rate-limiting and tightly regulated steps, respectively. In comparison, these processes were enhanced under light conditions.
Conclusions:Considering that astaxanthin accumulation was highly correlated with reactive oxygen species (ROS) levels in microalgae, our results suggest that A. limacinum reduces ATP consumption to decrease the occurrence of ROS in mitochondria while accumulating astaxanthin to prevent ROS damage.
Significance and Impact of Study:This study provides novel insights into the impact of light exposure on A. limacinum metabolism, thereby facilitating a complete understanding of this protist for efficient astaxanthin production.
Aurantiochytrium limacinum can accumulate high amounts of omega-3 polyunsaturated fatty acids, especially docosahexaenoic acid (DHA). Although salinity affects the DHA content, its impact on the metabolic pathway responsible for DHA production in A. limacinum is not completely understood. To address this issue, we investigated the transcriptional profile of A. limacinum under hypoosmotic stress. We first cultured A. limacinum under typical and low salinity for RNA sequencing, respectively. Transcriptome analyses revealed that 933 genes exhibited significant changes in expression under hypoosmotic conditions, of which 81.4% were downregulated. Strikingly, A. limacinum downregulated genes related to polyketide synthesis and fatty acid synthase pathways, while upregulating β-oxidation-related genes. In accordance with this, DHA production significantly decreased under hypoosmotic conditions, while antioxidant-related genes were significantly upregulated. Considering that β-oxidation of fatty acids generates energy and reactive oxygen species (ROS), our results suggest that A. limacinum utilizes fatty acids for energy to survive under hypoosmotic conditions and detoxifies ROS using antioxidant systems.
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