锰过氧化氢酶在植物乳杆菌中的功能意义
Functional significance of manganese catalase in Lactobacillus plantarum.
作者信息
Kono Y, Fridovich I
出版信息
J Bacteriol. 1983 Aug;155(2):742-6. doi: 10.1128/jb.155.2.742-746.1983.
Abstract
A strain of Lactobacillus plantarum which was unable to produce manganese (Mn)catalase (ATCC 8014) grew somewhat more rapidly and to a slightly higher plateau density than did an Mn catalase-positive strain (ATCC 14421), and this was the case during aerobic or anaerobic growth. However, when maintenance of viability was measured during the stationary phase of the growth cycle, the advantage provided by Mn catalase was obvious. Thus, the viability of ATCC 14431 was undiminished over 21 h of aerobic incubation, during the stationary phase, whereas that of ATCC 8014 decreased by seven orders of magnitude. Addition of catalase to the medium or growth in the presence of hemin, which allows catalase synthesis, protected ATCC 8014 against this loss of viability. Suppression of Mn catalase within ATCC 14431 by treatment with NH2OH caused the cells to lose viability when exposed to 4 mM H2O2.
摘要
一株无法产生锰(Mn)过氧化氢酶的植物乳杆菌(ATCC 8014),与一株锰过氧化氢酶阳性菌株(ATCC 14421)相比,生长速度稍快,稳定期密度略高,需氧或厌氧生长时均如此。然而,在生长周期的稳定期测量存活率时,锰过氧化氢酶的优势就很明显了。因此,在稳定期进行21小时的需氧培养后,ATCC 14431的存活率没有降低,而ATCC 8014的存活率下降了七个数量级。向培养基中添加过氧化氢酶或在血红素存在下生长(血红素可促进过氧化氢酶合成),可保护ATCC 8014免受这种存活率损失。用NH2OH处理抑制ATCC 14431中的锰过氧化氢酶,会导致细胞在暴露于4 mM H2O2时失去活力。
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