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一种蓝绿藻——纤细席藻对糖的暗代谢和光代谢

Dark and photometabolism of sugars by a blue green alga: Tolypothrix tenuis.

作者信息

Cheung W Y, Gibbs M

出版信息

Plant Physiol. 1966 Apr;41(4):731-7. doi: 10.1104/pp.41.4.731.

DOI:10.1104/pp.41.4.731

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1086413/

Abstract

The carbohydrate metabolism of the autotrophically grown blue-green alga, Tolypothrix tenuis, was studied. The alga respires glucose, fructose, galactose, and ribose. About 60% of the glucose consumed is converted by starved cells into a glucose polysaccharide. Glucose uptake and O(2) consumption are not inhibited by 0.01 m arsenite or by 0.005 m iodoacetamide. The distribution of (14)C in the polysaccharide glucose was established after feeding of glucose-1-(14)C, -2-(14)C, -6-(14)C, ribose-1-(14)C, and fructose-6-(14)C. Randomization of isotope between the 2 halves of the glucose from polysaccharide is limited when the experiments are carried out in the dark. After an extended incubation glucose-2-(14)C yields a glucose molecule with isotope labeled approximately equal in C-1, C-2 and C-3. When the labeled glucoses were fed at a light intensity of compensation point, and in the presence of carbon dioxide, a greater degree of randomization of isotope occurred. The enhanced randomization of isotope is thought to result from an additional supply of triose phosphates as a result of photosynthesis which creates an environment favorable to the reversal of the glycolytic reactions.To account for the labeling patterns and the resistance of respiration to the inhibitors, it is proposed that the oxidative pentose phosphate cycle is the major pathway of carbohydrate breakdown in this alga.

摘要

对自养生长的蓝藻纤细席藻的碳水化合物代谢进行了研究。该藻类能呼吸利用葡萄糖、果糖、半乳糖和核糖。饥饿细胞会将大约60%消耗的葡萄糖转化为一种葡萄糖多糖。0.01 m的亚砷酸盐或0.005 m的碘乙酰胺不会抑制葡萄糖摄取和氧气消耗。在投喂葡萄糖-1-(14)C、-2-(14)C、-6-(14)C、核糖-1-(14)C和果糖-6-(14)C后，确定了多糖葡萄糖中(14)C的分布。当实验在黑暗中进行时，多糖中葡萄糖两半部分之间的同位素随机化受到限制。长时间孵育后，葡萄糖-2-(14)C产生一个在C-1、C-2和C-3中同位素标记大致相等的葡萄糖分子。当在补偿点光照强度下且有二氧化碳存在时投喂标记葡萄糖，会发生更大程度的同位素随机化。同位素随机化增强被认为是由于光合作用额外提供了磷酸丙糖，从而创造了有利于糖酵解反应逆转的环境。为了解释标记模式以及呼吸对抑制剂的抗性，有人提出氧化戊糖磷酸循环是该藻类碳水化合物分解的主要途径。