通过优化利用无机碳源和铵盐来提高 F51 螺旋藻的细胞生长和叶黄素产量。

Enhancing cell growth and lutein productivity of Desmodesmus sp. F51 by optimal utilization of inorganic carbon sources and ammonium salt.

机构信息

College of Biological Science and Engineering, Fuzhou University, Fuzhou 350108, China.

College of Oceanography and Food Science, Quanzhou Normal University, Quanzhou 362000, China.

出版信息

Bioresour Technol. 2017 Nov;244(Pt 1):664-671. doi: 10.1016/j.biortech.2017.08.022. Epub 2017 Aug 8.

DOI:10.1016/j.biortech.2017.08.022

PMID:28813692

Abstract

The type and concentration of inorganic carbon and nitrogen sources were manipulated to improve cell growth and lutein productivity of Desmodesmus sp. F51. Using nitrate as nitrogen source, the better cell growth and lutein accumulation were obtained under 2.5% CO supply when compared to the addition of NaHCO or NaCO. To solve the pH variation problem of ammonium consumption, the strategy of using dual carbon sources (NaHCO and CO) was explored. A lower bicarbonate-C: ammonium-N ratio led to a lower culture pH as well as lower lutein productivity, but significantly enhanced the auto-flocculation efficiency of the microalgal cells. The highest biomass productivity (939mg/L/d) and lutein productivity (5.22mg/L/d) were obtained when the bicarbonate-C/ammonium-N ratio and ammonium-N concentration were 1:1 and 150mg/L, respectively. The lutein productivity of 5.22mg/L/d is the highest value ever reported in the literature using batch phototrophic cultivation.

摘要

通过操纵无机碳和氮源的类型和浓度，以提高小球藻 F51 的细胞生长和叶黄素产量。当使用硝酸盐作为氮源时，与添加碳酸氢钠或碳酸钠相比，在 2.5% CO 供应下，可获得更好的细胞生长和叶黄素积累。为了解决铵消耗过程中 pH 值变化的问题，探索了使用双碳源（碳酸氢钠和 CO）的策略。较低的碳酸氢盐-C：铵-N 比例会导致较低的培养 pH 值和较低的叶黄素产量，但会显著提高微藻细胞的自絮凝效率。当碳酸氢盐-C/铵-N 比例和铵-N 浓度分别为 1:1 和 150mg/L 时，可获得最高的生物量生产力（939mg/L/d）和叶黄素生产力（5.22mg/L/d）。5.22mg/L/d 的叶黄素生产力是使用间歇光养培养在文献中报道的最高值。

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通过优化利用无机碳源和铵盐来提高 F51 螺旋藻的细胞生长和叶黄素产量。

Enhancing cell growth and lutein productivity of Desmodesmus sp. F51 by optimal utilization of inorganic carbon sources and ammonium salt.

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