在一个永久冰冻的南极湖泊中,光合紫色细菌具有显著的多样性。
Remarkable diversity of phototrophic purple bacteria in a permanently frozen Antarctic lake.
作者信息
Karr Elizabeth A, Sattley W Matthew, Jung Deborah O, Madigan Michael T, Achenbach Laurie A
机构信息
Department of Microbiology, Southern Illinois University, Carbondale, Illinois 62901-6508, USA.
出版信息
Appl Environ Microbiol. 2003 Aug;69(8):4910-4. doi: 10.1128/AEM.69.8.4910-4914.2003.
Abstract
Although anoxygenic photosynthesis is thought to play an important role in the primary productivity of permanently frozen lakes in the Antarctic dry valleys, the bacterial communities responsible for this metabolism remain uncharacterized. Here we report the composition and activity of phototrophic purple bacteria in Lake Fryxell, Antarctica, as determined by analysis of a photosynthesis-specific gene, pufM. The results revealed an extensive diversity and highly stratified distribution of purple nonsulfur bacteria in Lake Fryxell and showed which phylotypes produced pufM transcripts in situ. Enrichment cultures for purple bacteria yielded two morphotypes, each with a pufM signature identical to signatures detected by environmental screening. The isolates also contained gas vesicles, buoyancy structures previously unknown in purple nonsulfur bacteria, that may be necessary for these organisms to position themselves at specific depths within the nearly freezing water column.
摘要
尽管无氧光合作用被认为在南极干谷永久冻土湖泊的初级生产力中发挥着重要作用,但负责这种代谢的细菌群落仍未得到表征。在此,我们报告了通过对光合作用特异性基因pufM的分析确定的南极弗里克塞尔湖光合紫色细菌的组成和活性。结果揭示了弗里克塞尔湖紫色非硫细菌的广泛多样性和高度分层分布,并显示了哪些系统型在原位产生了pufM转录本。紫色细菌的富集培养产生了两种形态类型,每种形态类型的pufM特征与通过环境筛选检测到的特征相同。分离物还含有气体小泡,这是紫色非硫细菌以前未知的浮力结构,对于这些生物体在接近冰点的水柱中定位到特定深度可能是必要的。
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