Department of Bioinformatics and Biotechnology, Government College University Faisalabad, Faisalabad 38000, Pakistan.
Dr. Panjwani Center for Molecular Medicine and Drug Research, International Center for Chemical and Biological Sciences, University of Karachi, Karachi 75270, Pakistan.
J Proteomics. 2022 Feb 10;252:104447. doi: 10.1016/j.jprot.2021.104447. Epub 2021 Dec 7.
Alkaliphilic cyanobacteria are suitable candidates to study the effect of alkaline wastewater cultivation on molecular metabolic responses. In the present study, the impact of wastewater, alkalinity, and alkaline wastewater cultivation was studied on the biomass production, biochemical composition, and the alkalinity responsive molecular mechanism through metabolomics. The results suggested a 1.29 to 1.44-fold higher biomass production along with improved lipid, carbohydrate, and pigment production under alkaline wastewater cultivation. The metabolomics analysis showed 1.2-fold and 5.54-fold increase in the indole-acetic acid and phytoene biosynthesis which contributed to overall enhanced cell differentiation and photo-protectiveness. Furthermore, lower levels of Ribulose-1,5-bisphosphate (RuBP), and higher levels of 2-phosphoglycerate and 3-phosphoglycerate suggested the efficient fixation of CO into biomass, and storage compounds including polysaccharides, lipids, and sterols. Interestingly, except L-histidine and L-phenylalanine, all the metabolites related to protein biosynthesis were downregulated in response to wastewater and alkaline wastewater cultivation. The cells protected themselves from alkalinity and nutrient stress by improving the biosynthesis of sterols, non-toxic antioxidants, and osmo-protectants. Alkaline wastewater cultivation regulated the activation of carbon concentration mechanism (CCM), glycolysis, fatty-acid biosynthesis, and shikimate pathway. The data revealed the importance of alkaline wastewater cultivation for improved CO fixation, wastewater treatment, and producing valuable bioproducts including phytoene, Lyso PC 18:0, and sterols. These metabolic pathways could be future targets of metabolic engineering for improving biomass and metabolite production. SIGNIFICANCE: Alkalinity is an imperative factor, responsible for the contamination control and biochemical regulation in cyanobactera, especially during the wastewater cultivation. Currently, understanding of alkaline wastewater responsive molecular mechanism is lacking and most of the studies are focused on transcriptomics of model organisms for this purpose. In this study, untargeted metabolomics was employed to analyze the impact of wastewater and alkaline wastewater on the growth, CO assimilation, nutrient uptake, and associated metabolic modulations of the alkaliphilic cyanobacterium Plectonema terebrans BERC10. Results unveiled that alkaline wastewater cultivation regulated the activation of carbon concentration mechanism (CCM), glycolysis, fatty-acid biosynthesis, and shikimate pathway. It indicated the feasibility of alkaline wastewater as promising low-cost media for cyanobacterium cultivation. The identified stress-responsive pathways could be future genetic targets for strain improvement.
嗜堿性蓝藻是研究堿性废水培养对分子代谢反应影响的合适候选者。在本研究中,通过代谢组学研究了废水、堿度和堿性废水培养对生物量生产、生物化学组成和堿响应分子机制的影响。结果表明,在堿性废水培养下,生物量生产提高了 1.29 至 1.44 倍,同时脂质、碳水化合物和色素的生产也得到了改善。代谢组学分析表明,吲哚乙酸和番茄红素生物合成分别增加了 1.2 倍和 5.54 倍,这有助于整体增强细胞分化和光保护。此外,1,5-二磷酸核酮糖(RuBP)水平降低,2-磷酸甘油酸和 3-磷酸甘油酸水平升高,表明 CO2 有效地固定到生物量中,并且包括多糖、脂质和甾醇在内的储存化合物也增加。有趣的是,除了 L-组氨酸和 L-苯丙氨酸外,所有与蛋白质生物合成相关的代谢物都因废水和堿性废水培养而下调。细胞通过提高甾醇、无毒抗氧化剂和渗透保护剂的生物合成来保护自己免受堿度和营养胁迫。堿性废水培养调节了碳浓缩机制(CCM)、糖酵解、脂肪酸生物合成和莽草酸途径的激活。数据揭示了堿性废水培养对提高 CO2 固定、废水处理和生产有价值的生物制品(如番茄红素、Lyso PC 18:0 和甾醇)的重要性。这些代谢途径可能成为未来通过代谢工程提高生物量和代谢产物生产的目标。意义:堿度是控制蓝藻污染和生化调节的重要因素,特别是在废水培养过程中。目前,对堿性废水响应的分子机制缺乏了解,大多数研究都是针对该目的的模型生物的转录组学。在这项研究中,采用非靶向代谢组学分析了废水和堿性废水对嗜堿蓝藻 Plectonema terebrans BERC10 的生长、CO2 同化、养分吸收和相关代谢调节的影响。结果表明,堿性废水培养调节了碳浓缩机制(CCM)、糖酵解、脂肪酸生物合成和莽草酸途径的激活。这表明堿性废水作为蓝藻培养的有前途的低成本培养基是可行的。鉴定出的应激响应途径可能成为未来遗传改良的目标。
