补充碳酸氢盐对从废水中分离出的用于可再生生物燃料原料的绿藻BHU1生物量和脂质含量的生理生化响应

Physiological and Biochemical Responses of Bicarbonate Supplementation on Biomass and Lipid Content of Green Algae sp. BHU1 Isolated From Wastewater for Renewable Biofuel Feedstock.

作者信息

Singh Rahul Prasad, Yadav Priya, Kumar Ajay, Hashem Abeer, Al-Arjani Al-Bandari Fahad, Abd Allah Elsayed Fathi, Rodríguez Dorantes Angélica, Gupta Rajan Kumar

机构信息

Laboratory of Algal Research, Centre of Advanced Study in Botany, Institute of Science, Banaras Hindu University, Varanasi, India.

Botany and Microbiology Department, College of Science, King Saud University, Riyadh, Saudi Arabia.

出版信息

Front Microbiol. 2022 Mar 29;13:839800. doi: 10.3389/fmicb.2022.839800. eCollection 2022.

DOI:10.3389/fmicb.2022.839800

PMID:35444634

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9015788/

Abstract

In the present study, different microalgae were isolated from wastewater environment and evaluated for higher growth and lipid accumulation. The growth adaptability of all the isolated microalgae were tested for carbon source with supplementation of sodium bicarbonate in BG-11 N medium. Further based on the uptake rate of sodium bicarbonate and growth behavior, microalgal strains were selected for biofuel feedstock. During the study, growth parameters of all the isolates were screened after supplementation with various carbon sources, in which strain sp. BHU1 was found highly effective among all. The efficacy of sp. BHU1 strain under different sodium bicarbonate (4-20 mM) concentration, in which higher growth 1.4 times greater than control was observed at the concentration 12 mM sodium bicarbonate. In addition, total chlorophyll content (Chl-a + Chl-b), chlorophyll fluorescence (Fv/Fm, Y(II), ETR max, and NPQmax), and biomass productivity were found to be 11.514 μg/ml, 0.673, 0.675, and 31.167 μmol electrons m s, 1.399, 59.167 mg/L/day, respectively, at the 12 mM sodium bicarbonate. However, under optimum sodium bicarbonate supplementation, 56.920% carbohydrate and 34.693% lipid content were accumulated, which showed potential of sodium bicarbonate supplementation in renewable biofuel feedstock by using sp. BHU1 strain.

摘要

在本研究中，从废水环境中分离出不同的微藻，并对其进行评估以实现更高的生长和脂质积累。在BG-11 N培养基中添加碳酸氢钠，测试所有分离出的微藻对碳源的生长适应性。进一步根据碳酸氢钠的吸收速率和生长行为，选择微藻菌株作为生物燃料原料。在研究过程中，在添加各种碳源后筛选所有分离株的生长参数，其中发现sp. BHU1菌株在所有菌株中效果最佳。sp. BHU1菌株在不同碳酸氢钠（4-20 mM）浓度下的效果，在12 mM碳酸氢钠浓度下观察到其生长比对照高1.4倍。此外，在12 mM碳酸氢钠浓度下，总叶绿素含量（叶绿素a +叶绿素b）、叶绿素荧光（Fv/Fm、Y(II)、ETR max和NPQmax）以及生物量生产力分别为11.514 μg/ml、0.673、0.675和31.167 μmol电子m s、1.399、59.167 mg/L/天。然而，在最佳碳酸氢钠添加量下，积累了56.920%的碳水化合物和34.693%的脂质含量，这表明使用sp. BHU1菌株在可再生生物燃料原料中添加碳酸氢钠具有潜力。

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补充碳酸氢盐对从废水中分离出的用于可再生生物燃料原料的绿藻BHU1生物量和脂质含量的生理生化响应

Physiological and Biochemical Responses of Bicarbonate Supplementation on Biomass and Lipid Content of Green Algae sp. BHU1 Isolated From Wastewater for Renewable Biofuel Feedstock.

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