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黑暗中厌氧生长后,深红红螺菌对丙酮酸的发酵代谢。

Fermentative metabolism of pyruvate by Rhodospirillum rubrum after anaerobic growth in darkness.

作者信息

Gorrell T E, Uffen R L

出版信息

J Bacteriol. 1977 Aug;131(2):533-43. doi: 10.1128/jb.131.2.533-543.1977.

DOI:10.1128/jb.131.2.533-543.1977
PMID:18439
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC235462/
Abstract

Rhodospirillum rubrum grew anaerobically in darkness and fermented sodium pyruvate by a pyruvate formate-lyase reaction. During 30 min of anaerobic dark or light incubation with sodium pyrivate, crude extracts from fermentatively grown cells produced about 6 micronmol of acetylphosphate and formate per mg of protein in reactions performed at pH 8.3. Cell extracts also catalyzed the exchange of sodium [14C]formate into sodium pyruvate at an apparent pH optimum of 7.3 to 7.5, but only about 2.5 micronmol of acetylphosphate was produced at this lower pH value. R. rubrum may also form pyruvate:ferredoxin oxidoreductase activity, as evidenced by low bicarbonate exchange activity. However, its participation in pyruvate metabolism in anaerobic dark-grown cells was not understood. During anaerobic, dark growth with pyruvate, formate was an intermediate in H2 and CO2 gas evolution. In contrast with H2 production by a light-dependent H2-nitrogenase system in photosynthetically grown cells, H2 formation in fermenting R. rubrum occurred through a carbon monoxide-sensitive formic hydrogenlyase reaction not influenced by light.

摘要

深红红螺菌在黑暗中厌氧生长,并通过丙酮酸甲酸裂解酶反应发酵丙酮酸钠。在与丙酮酸钠进行30分钟的厌氧黑暗或光照培养期间,发酵生长细胞的粗提取物在pH 8.3进行的反应中,每毫克蛋白质产生约6微摩尔的乙酰磷酸和甲酸。细胞提取物还催化了[14C]甲酸钠与丙酮酸钠之间的交换,其表观最适pH为7.3至7.5,但在此较低pH值下仅产生约2.5微摩尔的乙酰磷酸。深红红螺菌也可能形成丙酮酸:铁氧化还原蛋白氧化还原酶活性,低碳酸氢盐交换活性证明了这一点。然而,其在厌氧黑暗生长细胞中参与丙酮酸代谢的情况尚不清楚。在以丙酮酸进行厌氧黑暗生长期间,甲酸是H2和CO2气体产生过程中的中间产物。与光合生长细胞中依赖光的H2-固氮酶系统产生H2不同,发酵性深红红螺菌中H2的形成是通过一氧化碳敏感的甲酸氢裂解酶反应,不受光的影响。

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