Dynamic metabolomic crosstalk between Chlorella saccharophila and its new symbiotic bacteria enhances lutein production in microalga without compromising its biomass

• Published in: Enzyme and microbial technology Vol. 170; p. 110291
• Main Authors: Makaranga, Abdalah, Jutur, Pannaga Pavan
• Format: Journal Article
• Language: English
• Published: United States Elsevier Inc 01.10.2023
• Subjects: Biorefineries; Carotenogenesis; Chlorella saccharophila; Exiguobacterium sp; Lutein; Biorefineries; Carotenogenesis; Lutein; Chlorella saccharophila; Exiguobacterium sp
• ISSN: 0141-0229; 1879-0909
• DOI: 10.1016/j.enzmictec.2023.110291

The microalgae Chlorella saccharophila UTEX247 was co-cultured with its symbiotic indigenous isolated bacterial strain, Exiguobacterium sp., to determine the possible effects of bacteria on microalgae growth and lutein productivity. Under optimal conditions, the lutein productivity of co-culture was 298.97 µg L−1 d−1, which was nearly 1.45-fold higher compared to monocultures i.e., 103.3 µg L−1 d−1. The highest lutein productivities were obtained in co-cultures, accompanied by a significant increase in cell biomass up to 0.84-fold. These conditions were analyzed using an untargeted metabolomics approach to identify metabolites enhancing valuable renewables, i.e., lutein, without compromising growth. Our qualitative metabolomic analysis identified nearly 30 (microalgae alone), 41 (bacteria alone), and 75 (co-cultures) metabolites, respectively. Among these, 46 metabolites were unique in the co-culture alone. The co-culture interactions significantly altered the role of metabolites such as thiamine precursors, reactive sugar anomers like furanose and branched-chain amino acids (BCAA). Nevertheless, the central metabolism cycle upregulation depicted increased availability of carbon skeletons, leading to increased cell biomass and pigments. In conclusion, the co-cultures induce the production of relevant metabolites which regulate growth and lutein simultaneously in C. saccharophila UTEX247, which paves the way for a new perspective in microalgal biorefineries. •A new bacteria strain, Exiguobacterium sp., was characterised.•Co-culture conditions were optimized to improve lutein production without compromising growth.•Co-cultures simulated a metabolites-rich phycosphere environment.•Alternations in central carbon metabolism pathways in microalgae were observed due to dynamic metabolic crosstalk.