影响枯草芽孢杆菌马堡株中α-淀粉酶产量的基因。

Genes affecting the productivity of alpha-amylase in Bacillus subtilis Marburg.

作者信息

Sekiguchi J, Takada N, Okada H

出版信息

J Bacteriol. 1975 Feb;121(2):688-94. doi: 10.1128/jb.121.2.688-694.1975.

DOI:10.1128/jb.121.2.688-694.1975

PMID:803484

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC245983/

Abstract

Genetic control of alpha-amylase (alpha-1,4-glucan glucanohydrolase, EC 3.2.1.1.) production by Bacillus subtilis 168 was studied from the standpoint that alpha-amylase production by bacteria is dependent on a long-lived messenger ribonucleic acid and obeys the following equation: E = kappa integral of X-DT where x = cell mass at time t, E = alpha amylase produced, t = culture time, and kappa = productivity constant. So a productivity constand (kappa) is obtained from the slope of the straight line plot of alpha-amylase formed versus the total mass of cells accumulated over that time during the culture process. The following results were obtained. (i) Two sequential mutants, derived from the 168(kappa = 20) strain and having improved alpha-amylase productivity (168 leads to 196), were analyzed for their serine and metal protease production. Strain 128 (kappa = 40) produced half the amount of both proteases, but strain 196 (kappa = 60 similar to 80) produced 20 times that in the original strain. (ii) Amy+ transformants, using the 196 strain as the other three had higher productivity (kappa = 37 similar to 46). These transformants (J71, J47, groups. Seventy-one of 74 Amy+ transformants had a kappa value of 21.0 plus or minus 2.1 and the other three had higher productivity (kappa = 37 similar to 46). These transformants (J71,J47, and J10) produced levels of serine and metal proteases 20 times higher than the other transformants. (iii) Strains 196, J71, J47, and J10 were found to be nonmotile and resistant to phage PBS1, whereas other strains, including strains 168, 128, 3 revertants of strain J71 and 2 revertants of strain 196, were all motile and sensitive to the phage. (iv) Strains 196 and J71 were nonflagellated under electron microscopic observation but strain 168, 128 and a revertant of J71 were flagellated. From the above experimental results, the existence of a quality controlling gene (amyB) was deduced, which is loosely linked to the structural gene and controls productivities of alpha-amylase and proteases, and flagellation. The probable existence of another regulatory gene, amyC, is also discussed.

摘要

从细菌产生α-淀粉酶依赖于长寿命信使核糖核酸且符合以下方程的角度，研究了枯草芽孢杆菌168产生α-淀粉酶（α-1,4-葡聚糖葡聚糖水解酶，EC 3.2.1.1.）的遗传控制：E = κ∫Xdt，其中x为时间t时的细胞质量，E为产生的α-淀粉酶，t为培养时间，κ为生产力常数。因此，生产力常数（κ）可从培养过程中α-淀粉酶形成量与该时间段内积累的细胞总质量的直线图斜率获得。得到了以下结果。（i）分析了从168（κ = 20）菌株衍生而来且具有提高的α-淀粉酶生产力（168→196）的两个连续突变体的丝氨酸和金属蛋白酶产生情况。128菌株（κ = 40）产生的两种蛋白酶量均为原来的一半，但196菌株（κ = 60至80）产生的量是原始菌株的20倍。（ii）以196菌株为受体的Amy +转化体，其他三个具有较高的生产力（κ = 37至46）。这些转化体（J71、J47和J10）产生的丝氨酸和金属蛋白酶水平比其他转化体高20倍。74个Amy +转化体中有71个的κ值为21.0±2.1，另外三个具有较高的生产力（κ = 37至46）。（iii）发现196、J71、J47和J10菌株无运动能力且对噬菌体PBS1有抗性，而其他菌株，包括168、128菌株、J71的3个回复突变体和196的2个回复突变体，均有运动能力且对噬菌体敏感。（iv）电子显微镜观察显示，196和J71菌株无鞭毛，但168、128和J71的一个回复突变体有鞭毛。从上述实验结果推断，存在一个质量控制基因（amyB），它与结构基因松散连锁，控制α-淀粉酶和蛋白酶的生产力以及鞭毛形成。还讨论了另一个调控基因amyC可能存在的情况。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4f82/245983/f3ea2e6a7657/jbacter00332-0306-a.jpg

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影响枯草芽孢杆菌马堡株中α-淀粉酶产量的基因。

Genes affecting the productivity of alpha-amylase in Bacillus subtilis Marburg.

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