基因组序列分析及相关戈登氏菌噬菌体 GTE5 和 GRU1 的特性研究及其作为潜在生物防治剂的应用。
Genome sequences and characterization of the related Gordonia phages GTE5 and GRU1 and their use as potential biocontrol agents.
机构信息
La Trobe Institute for Molecular Sciences, La Trobe University, Bundoora, Victoria, Australia.
出版信息
Appl Environ Microbiol. 2012 Jan;78(1):42-7. doi: 10.1128/AEM.05584-11. Epub 2011 Oct 28.
Abstract
Activated sludge plants suffer frequently from the operational problem of stable foam formation on aerobic reactor surfaces, which can be difficult to prevent. Many foams are stabilized by mycolic acid-containing Actinobacteria, the mycolata. The in situ biocontrol of foaming using phages is an attractive strategy. We describe two polyvalent phages, GTE5 and GRU1, targeting Gordonia terrae and Gordonia rubrupertincta, respectively, isolated from activated sludge. Phage GRU1 also propagates on Nocardia nova. Both phages belong to the family Siphoviridae and have similar-size icosahedral heads that encapsulate double-stranded DNA genomes (∼65 kb). Their genome sequences are similar to each other but markedly different from those of other sequenced phages. Both are arranged in a modular fashion. These phages can reduce or eliminate foam formation by their host cells under laboratory conditions.
摘要
活性污泥厂经常面临好氧反应器表面稳定泡沫形成的操作问题,这很难预防。许多泡沫是由含有分枝菌酸的放线菌(mycolata)稳定的。使用噬菌体原位控制泡沫是一种有吸引力的策略。我们描述了两种多价噬菌体,GTE5 和 GRU1,分别针对从活性污泥中分离出的戈登氏菌( Gordonia terrae )和戈登氏红球菌( Gordonia rubrupertincta )。噬菌体 GRU1 也在新诺卡氏菌( Nocardia nova )上繁殖。这两种噬菌体都属于肌尾噬菌体科( Siphoviridae ),具有相似大小的二十面体头部,其中包含双链 DNA 基因组(约 65kb)。它们的基因组序列彼此相似,但与其他已测序的噬菌体明显不同。它们都以模块化的方式排列。在实验室条件下,这些噬菌体可以减少或消除其宿主细胞产生的泡沫。
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