利用玛氏陷阱与 DNA 条码技术快速评估陆地节肢动物多样性。

Expedited assessment of terrestrial arthropod diversity by coupling Malaise traps with DNA barcoding .

机构信息

a Centre for Biodiversity Genomics, Biodiversity Institute of Ontario, University of Guelph, Guelph, Ontario, Canada.

b Department of Biology, Carleton University, Ottawa, Ontario, Canada.

出版信息

Genome. 2019 Mar;62(3):85-95. doi: 10.1139/gen-2018-0093. Epub 2018 Sep 26.

DOI:10.1139/gen-2018-0093

PMID:30257096

Abstract

Monitoring changes in terrestrial arthropod communities over space and time requires a dramatic increase in the speed and accuracy of processing samples that cannot be achieved with morphological approaches. The combination of DNA barcoding and Malaise traps allows expedited, comprehensive inventories of species abundance whose cost will rapidly decline as high-throughput sequencing technologies advance. Aside from detailing protocols from specimen sorting to data release, this paper describes their use in a survey of arthropod diversity in a national park that examined 21 194 specimens representing 2255 species. These protocols can support arthropod monitoring programs at regional, national, and continental scales.

摘要

监测陆地节肢动物群落随时间和空间的变化，需要大幅提高处理样本的速度和准确性，而形态学方法无法实现这一点。DNA 条码技术与巴氏诱捕器的结合，可以快速、全面地对物种丰度进行编目，而且随着高通量测序技术的进步，其成本将迅速降低。除了详细说明从标本分拣到数据发布的各个步骤外，本文还描述了它们在国家公园节肢动物多样性调查中的应用，该调查共检查了 21944 个标本，代表 2255 个物种。这些方案可以为区域、国家和大陆尺度的节肢动物监测计划提供支持。

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利用玛氏陷阱与 DNA 条码技术快速评估陆地节肢动物多样性。

Expedited assessment of terrestrial arthropod diversity by coupling Malaise traps with DNA barcoding .

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