三种不同南极寒漠矿质土壤中的细菌多样性

Bacterial diversity in three different Antarctic Cold Desert mineral soils.

作者信息

Smith Jacques J, Tow Lemese Ah, Stafford William, Cary Craig, Cowan Donald A

机构信息

Department of Biotechnology, University of the Western Cape, Bellville 7535, Cape Town, South Africa.

出版信息

Microb Ecol. 2006 May;51(4):413-21. doi: 10.1007/s00248-006-9022-3. Epub 2006 Apr 5.

DOI:10.1007/s00248-006-9022-3

PMID:16596438

Abstract

A bacterial phylogenetic survey of three environmentally distinct Antarctic Dry Valley soil biotopes showed a high proportion of so-called "uncultured" phylotypes, with a relatively low diversity of identifiable phylotypes. Cyanobacterial phylotypic signals were restricted to the high-altitude sample, whereas many of the identifiable phylotypes, such as the members of the Actinobacteria, were found at all sample sites. Although the presence of Cyanobacteria and Actinobacteria is consistent with previous culture-dependent studies of microbial diversity in Antarctic Dry Valley mineral soils, many phylotypes identified by 16S rDNA analysis were of groups that have not hitherto been cultured from Antarctic soils. The general belief that such "extreme" environments harbor a relatively low species diversity was supported by the calculation of diversity indices. The detection of a substantial number of uncultured bacterial phylotypes showing low BLAST identities (< 95%) suggests that Antarctic Dry Valley mineral soils harbor a pool of novel psychrotrophic taxa.

摘要

对三个环境特征不同的南极干谷土壤生物群落进行的细菌系统发育调查显示，所谓“未培养”的系统型比例很高，可识别系统型的多样性相对较低。蓝细菌系统型信号仅限于高海拔样本，而许多可识别的系统型，如放线菌成员，在所有样本地点均有发现。尽管蓝细菌和放线菌的存在与之前关于南极干谷矿质土壤微生物多样性的依赖培养的研究结果一致，但通过16S rDNA分析鉴定出的许多系统型属于迄今尚未从南极土壤中培养出来的类群。多样性指数的计算支持了这样一种普遍观点，即此类“极端”环境中物种多样性相对较低。检测到大量未培养的细菌系统型，其BLAST同源性较低（<95%），这表明南极干谷矿质土壤中存在着一批新的嗜冷类群。

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三种不同南极寒漠矿质土壤中的细菌多样性

Bacterial diversity in three different Antarctic Cold Desert mineral soils.

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