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渗透剂对酿酒酵母细胞增殖、形态和存活力的影响 被引量:10

INFLUENCES OF OSMOLYTES ON CELLULAR PROLIFERATION, MORPHOLOGY AND VIABILITY OF Saccharomyces cerevisiae
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摘要 为了揭示渗透作用机制 ,考察了氯化钠、山梨醇、甘油和聚乙二醇 (PEG6 0 0 )等 4种化合物对模式生物S cerevisiae细胞生长、形态结构和代谢的影响 . 2 4h细胞培养结果表明 ,渗透剂的抑制作用与其浓度的增加一致 ,细胞的比生长速率下降 .高渗环境使细胞形态发生改变 ,趋于球状 .细胞生长动力学表明 ,0 5mol·L-1氯化钠显著延缓耗糖速率 ,降低比生长速率 ,延长细胞指数生长期 ;0 33mol·L-1PEG6 0 0对指数生长期的细胞无显著影响 ,但缩短了细胞平衡期 .在生理可接受的渗透强度内 ,与对照组相比较 ,0 5mol·L-1氯化钠和0 33mol·L-1PEG6 0 0不影响最终残糖水平和生物量浓度 . To evaluate the impacts of different osmolytes on cellular proliferation, morphology and viability of the model microbe Saccharomyces cerevisiae FL 1, in additon to the commonly used sodium chloride, glycerol, poly (ethyleneglycol) 600, and sorbitol were used. Moreover, the dynamic behavior of cell proliferation and metabolism under physiologicallg acceptable hyperosmotic condition were examined. Results indicated that these osmolytes had significant negative impacts on proliferation with increasing concentration, compared to the control treatment composed of YEPD media. The cellular morphology was close to sphere after exposure to high osmotic pressure for 24 h. After analyzing the dynamics data, sodium chloride of 0.5 mol&middotL-1 was found to markedly reduce the specific cell growth rate, sugar consumption but prolong the duration of exponential growth phase. At the same time, PEG600 of 0.33 mol&middotL-1 had no marked influence on cell proliferation but shortened the stationary phase. However, under the physiologically acceptable hyperosmotic condition, the final biomass density among all the treatments was similar.
出处 《化工学报》 EI CAS CSCD 北大核心 2004年第7期1150-1154,共5页 CIESC Journal
基金 国家自然科学基金资助项目 (No 2 0 2 760 65 )~~
关键词 酿酒酵母 氯化钠 聚乙二醇 渗透应激 生物量 增殖 存活力 Biomass Glycerol Metabolism Morphology Osmosis Sodium chloride
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