绿假单胞菌亚种的分子和遗传特征。Aurantiaca突变株对过氧化氢的抗性增强

K. Verameyenka, K. S. Bondarava, A. Liaudanskaya, N. Maximova
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引用次数: 0

摘要

对自然和突变的生产菌株进行全基因组测序是分析基因组和寻找突变的最佳方法,这些突变可能导致生物技术和制药工业获得许多有价值的特性。目前研究的主要目标是鉴定突变菌株Рseudomonas绿蚜亚种基因组中由化学诱变诱导的突变。aurantiaca B-162/15耐过氧化氢。这将为发现可能参与非那嗪类化合物生物合成的新基因提供机会。这种方法也使鉴定基因成为可能,这些基因的产物不直接参与非那嗪的合成,但影响非那嗪的解毒、排泄和抗氧化系统活性的优化。最重要的是,它可以帮助我们发现可能参与这一过程的新的不可预测的酶系统。叶绿素亚种的基因组大小。aurantiaca B-162/15全长7109863磅,包含6493个开放阅读框和66个编码转运和核糖体RNA的序列。野生型菌株与B-162/15突变体基因组比较发现16个突变,其中13个位于编码序列,3个位于基因间区。6个突变导致编码蛋白氨基酸序列的自由基替换(格兰瑟姆距离超过80)。我们成功地鉴定了四个潜在的候选基因,它们可以影响非那嗪的代谢,并提供突变菌株的超生产力能力。它们分别是精氨酸n-琥珀基转移酶、磷酸烯醇丙酮酸合成酶、含铁氧化还原酶家族蛋白、类二十烷和谷胱甘肽代谢中的膜相关蛋白。鉴定出三个前噬菌体区域,其中两个区域完整,一个区域不完整。原噬菌体基因和细菌基因都在这些区域内。我们还成功地在原噬菌体2区鉴定了根癌农杆菌的两个基因。这些区域可能是通过病毒转导被引入到所研究菌株的基因组中。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Molecular and genetic characterization of the Pseudomonas chlororaphis subsp. aurantiaca mutant strain with increased resistance to hydrogen peroxide
A whole genome sequencing of natural and mutant producer strains is the best way to analyze the genome and to search for mutations that could cause the acquisition of a number of properties valuable for biotechnological and pharmaceutical industry.The main goal of current research was to identify mutations that had been induced by chemical mutagenesis in the genome of the mutant strain Рseudomonas chlororaphis subsp. aurantiaca B-162/15 resistant to hydrogen peroxide. It would give an opportunity to discover new genes potentially participating in phenazine compounds biosynthesis. Such an approach also makes it possible to identify genes, whose products do not directly participate in the phenazine synthesis, but influence the phenazine detoxification, excretion, and optimization of antioxidant system activity. Most of all, it could help us to discover new unpredicted enzyme systems that might be involved into this process.The genome size of P. chlororaphis subsp. aurantiaca B-162/15 was 7109863 b. p. It contained 6493 open reading frames and 66 sequences encoding transport and ribosomal RNA. Comparison of a wild-type strain and B-162/15 mutant genomes revealed 16 mutations, 13 of which were located in coding sequences and 3 were located in intergenic regions. Six mutations led to radical replacements in amino acid sequences of coded proteins (with a Grantham distance of more than 80). We managed to identify four potential gene-candidates, which could influence the phenazine metabolism and provided the ability of mutant strain to superproductivity. They were arginine N-succinyltransferase, phosphoenolpyruvate synthase, iron-contain-ing redox enzyme family protein, membrane-associated proteins in eicosanoid and glutathione metabolism. Three prophage regions were identified, two regions of which were intact and one region was incomplete. The prophage genes, as well as the bacterial genes were inside these regions. We also managed to identify two genes of Agrobacterium tumefaciens inside prophage region 2. It was possible that these regions were introduced into the genome of studied strain by viral transduction. 
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