PAM 荧光法作为评估微藻营养胁迫和监测细胞中性脂的工具。

PAM fluorometry as a tool to assess microalgal nutrient stress and monitor cellular neutral lipids.

机构信息

Institute of Water and Wastewater Research, Durban University of Technology, P.O. Box 1334, Durban 4000, South Africa.

出版信息

Bioresour Technol. 2011 Jan;102(2):1675-82. doi: 10.1016/j.biortech.2010.09.097. Epub 2010 Oct 1.

DOI:10.1016/j.biortech.2010.09.097

PMID:20965719

Abstract

This study investigated the use of Pulse Amplitude Modulated (PAM) fluorometry to measure nutrient induced physiological stress and subsequent synthesis of cellular neutral lipids. A freshwater Chlorella sp. was subjected to complete nutrient stress (distilled H2O) and selective nutrient stress in modified BG-11 media (BG-11-N, BG-11-P and BG-11-Fe). Physiological stress was recorded using parameters, rETR, Fv/Fm, Ek, α and NPQ. Induced stress became evident when these parameters were significantly altered, suggesting the onset of neutral lipid synthesis. Complete nutrient stress induced the highest yield of cellular neutral lipids (∼49%) compared to absence of selected nutrients (∼30%). Physiological stress was recorded by a significant decrease in rETR (75%), Fv/Fm (36%), and Ek (60%) and an increase in NPQ (83%). Optimization of neutral lipids occurred by initially maximizing the biomass and subsequently subjecting the harvested biomass to complete nutrient stress.

摘要

本研究利用脉冲调制荧光法（PAM）测量营养诱导的生理胁迫和随后细胞中性脂质的合成。将淡水栅藻（Chlorella sp.）置于完全营养胁迫（蒸馏水）和改良 BG-11 培养基中的选择性营养胁迫（BG-11-N、BG-11-P 和 BG-11-Fe）下。使用参数 rETR、Fv/Fm、Ek、α 和 NPQ 记录生理胁迫。当这些参数发生显著变化时，表明开始合成中性脂质。与缺乏选定营养素（约 30%）相比，完全营养胁迫诱导产生的细胞中性脂质产量最高（约 49%）。生理胁迫表现为 rETR（75%）、Fv/Fm（36%）和 Ek（60%）显著下降，NPQ（83%）增加。通过最初最大化生物量并随后将收获的生物量置于完全营养胁迫下，实现了中性脂质的最佳优化。

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PAM 荧光法作为评估微藻营养胁迫和监测细胞中性脂的工具。

PAM fluorometry as a tool to assess microalgal nutrient stress and monitor cellular neutral lipids.

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