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海洋次表层亚微米细菌的光流控单细胞基因组扩增

Optofluidic Single-Cell Genome Amplification of Sub-micron Bacteria in the Ocean Subsurface.

作者信息

Landry Zachary C, Vergin Kevin, Mannenbach Christopher, Block Stephen, Yang Qiao, Blainey Paul, Carlson Craig, Giovannoni Stephen

机构信息

Department of Microbiology, Oregon State University, Corvallis, OR, United States.

Institut für Umweltingenieurwissenschaften, ETH Zurich, Zurich, Switzerland.

出版信息

Front Microbiol. 2018 Jun 8;9:1152. doi: 10.3389/fmicb.2018.01152. eCollection 2018.

DOI:10.3389/fmicb.2018.01152
PMID:29937754
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6003095/
Abstract

Optofluidic single-cell genome amplification was used to obtain genome sequences from sub-micron cells collected from the euphotic and mesopelagic zones of the northwestern Sargasso Sea. Plankton cells were visually selected and manually sorted with an optical trap, yielding 20 partial genome sequences representing seven bacterial phyla. Two organisms, E01-9C-26 (), represented by four single cell genomes, and Opi.OSU.00C, an uncharacterized , were the first of their types retrieved by single cell genome sequencing and were studied in detail. Metagenomic data showed that E01-9C-26 is found throughout the dark ocean, while Opi.OSU.00C was observed to bloom transiently in the nutrient-depleted euphotic zone of the late spring and early summer. The E01-9C-26 genomes had an estimated size of 4.76-5.05 Mbps, and contained "O" and "W"-type monooxygenase genes related to methane and ammonium monooxygenases that were previously reported from ocean metagenomes. Metabolic reconstruction indicated E01-9C-26 are likely versatile methylotrophs capable of scavenging C1 compounds, methylated compounds, reduced sulfur compounds, and a wide range of amines, including D-amino acids. The genome sequences identified E01-9C-26 as a source of "O" and "W"-type monooxygenase genes related to methane and ammonium monooxygenases that were previously reported from ocean metagenomes, but are of unknown function. In contrast, Opi.OSU.00C genomes encode genes for catabolizing carbohydrate compounds normally associated with eukaryotic phytoplankton. This exploration of optofluidics showed that it was effective for retrieving diverse single-cell bacterioplankton genomes and has potential advantages in microbiology applications that require working with small sample volumes or targeting cells by their morphology.

摘要

光流体单细胞基因组扩增技术被用于从马尾藻海西北部透光层和中层采集的亚微米级细胞中获取基因组序列。通过视觉筛选浮游生物细胞,并使用光阱进行手动分选,得到了代表七个细菌门的20个部分基因组序列。两种生物,由四个单细胞基因组代表的E01-9C-26()和未鉴定的Opi.OSU.00C,是通过单细胞基因组测序首次获得的此类生物,并进行了详细研究。宏基因组数据显示,E01-9C-26在整个黑暗海洋中都有发现,而Opi.OSU.00C在晚春和初夏营养耗尽的透光层中短暂大量繁殖。E01-9C-26基因组估计大小为4.76-5.05 Mbps,包含与甲烷和铵单加氧酶相关的“O”型和“W”型单加氧酶基因,这些基因先前已在海洋宏基因组中报道。代谢重建表明,E01-9C-26可能是多功能甲基营养菌,能够清除C1化合物、甲基化化合物、还原态硫化合物以及包括D-氨基酸在内的多种胺类。基因组序列将E01-9C-26鉴定为与甲烷和铵单加氧酶相关的“O”型和“W”型单加氧酶基因的来源,这些基因先前已在海洋宏基因组中报道,但功能未知。相比之下,Opi.OSU.00C基因组编码分解通常与真核浮游植物相关的碳水化合物化合物的基因。这项光流体学探索表明,它对于获取多样的单细胞浮游细菌基因组是有效的,并且在需要处理小样本量或根据形态靶向细胞的微生物学应用中具有潜在优势。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/179c/6003095/1b7253fdb3fd/fmicb-09-01152-g0007.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/179c/6003095/d1ebf5dee38d/fmicb-09-01152-g0001.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/179c/6003095/171bf59a4979/fmicb-09-01152-g0002.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/179c/6003095/8e0364dd7684/fmicb-09-01152-g0006.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/179c/6003095/1b7253fdb3fd/fmicb-09-01152-g0007.jpg

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