Your search keyword '"Pavel Senin"' showing total 2 results

1. Assembling the marine metagenome, one cell at a time.

Author

Tanja Woyke, Gary Xie, Alex Copeland, José M González, Cliff Han, Hajnalka Kiss, Jimmy H Saw, Pavel Senin, Chi Yang, Sourav Chatterji, Jan-Fang Cheng, Jonathan A Eisen, Michael E Sieracki, and Ramunas Stepanauskas

Subjects

Medicine, Science

Abstract

The difficulty associated with the cultivation of most microorganisms and the complexity of natural microbial assemblages, such as marine plankton or human microbiome, hinder genome reconstruction of representative taxa using cultivation or metagenomic approaches. Here we used an alternative, single cell sequencing approach to obtain high-quality genome assemblies of two uncultured, numerically significant marine microorganisms. We employed fluorescence-activated cell sorting and multiple displacement amplification to obtain hundreds of micrograms of genomic DNA from individual, uncultured cells of two marine flavobacteria from the Gulf of Maine that were phylogenetically distant from existing cultured strains. Shotgun sequencing and genome finishing yielded 1.9 Mbp in 17 contigs and 1.5 Mbp in 21 contigs for the two flavobacteria, with estimated genome recoveries of about 91% and 78%, respectively. Only 0.24% of the assembling sequences were contaminants and were removed from further analysis using rigorous quality control. In contrast to all cultured strains of marine flavobacteria, the two single cell genomes were excellent Global Ocean Sampling (GOS) metagenome fragment recruiters, demonstrating their numerical significance in the ocean. The geographic distribution of GOS recruits along the Northwest Atlantic coast coincided with ocean surface currents. Metabolic reconstruction indicated diverse potential energy sources, including biopolymer degradation, proteorhodopsin photometabolism, and hydrogen oxidation. Compared to cultured relatives, the two uncultured flavobacteria have small genome sizes, few non-coding nucleotides, and few paralogous genes, suggesting adaptations to narrow ecological niches. These features may have contributed to the abundance of the two taxa in specific regions of the ocean, and may have hindered their cultivation. We demonstrate the power of single cell DNA sequencing to generate reference genomes of uncultured taxa from a complex microbial community of marine bacterioplankton. A combination of single cell genomics and metagenomics enabled us to analyze the genome content, metabolic adaptations, and biogeography of these taxa.

Published

2009

2. Assembling the Marine Metagenome, One Cell at a Time

Author

Michael E. Sieracki, Gary Xie, José M. González, Ramunas Stepanauskas, Pavel Senin, Chi Yang, Jonathan A. Eisen, Tanja Woyke, Sourav Chatterji, Jimmy H. Saw, Hajnalka Kiss, Cliff Han, Jan Fang Cheng, and Alex Copeland

Subjects

Rhodopsin, Science, Marine and Aquatic Sciences/Genetics, Genomics, and Barcoding, Marine and Aquatic Sciences, Marine Biology, Genomics, Biology, Ecology/Marine and Freshwater Ecology, Genome, DNA sequencing, 03 medical and health sciences, Marine and Aquatic Sciences/Microbiology, RNA, Ribosomal, 16S, Rhodopsins, Microbial, Marine and Aquatic Sciences/Biological Oceanography, Animals, Microbiology/Environmental Microbiology, 14. Life underwater, Genetics and Genomics/Genomics, Phylogeny, 030304 developmental biology, Marine and Aquatic Sciences/Ecology, Genetics, Comparative genomics, Marine biology, 0303 health sciences, Multidisciplinary, 030306 microbiology, Shotgun sequencing, Biodiversity, Sequence Analysis, DNA, Marine and Aquatic Sciences/Bioinformatics, Plankton, Computational Biology/Metagenomics, Genetics and Genomics/Genome Projects, Single cell sequencing, Genes, Bacterial, Metagenomics, Evolutionary biology, Medicine, Genome, Bacterial, Ecology/Environmental Microbiology, Research Article, Computational Biology/Genomics

Abstract

The difficulty associated with the cultivation of most microorganisms and the complexity of natural microbial assemblages, such as marine plankton or human microbiome, hinder genome reconstruction of representative taxa using cultivation or metagenomic approaches. Here we used an alternative, single cell sequencing approach to obtain high-quality genome assemblies of two uncultured, numerically significant marine microorganisms. We employed fluorescence-activated cell sorting and multiple displacement amplification to obtain hundreds of micrograms of genomic DNA from individual, uncultured cells of two marine flavobacteria from the Gulf of Maine that were phylogenetically distant from existing cultured strains. Shotgun sequencing and genome finishing yielded 1.9 Mbp in 17 contigs and 1.5 Mbp in 21 contigs for the two flavobacteria, with estimated genome recoveries of about 91% and 78%, respectively. Only 0.24% of the assembling sequences were contaminants and were removed from further analysis using rigorous quality control. In contrast to all cultured strains of marine flavobacteria, the two single cell genomes were excellent Global Ocean Sampling (GOS) metagenome fragment recruiters, demonstrating their numerical significance in the ocean. The geographic distribution of GOS recruits along the Northwest Atlantic coast coincided with ocean surface currents. Metabolic reconstruction indicated diverse potential energy sources, including biopolymer degradation, proteorhodopsin photometabolism, and hydrogen oxidation. Compared to cultured relatives, the two uncultured flavobacteria have small genome sizes, few non-coding nucleotides, and few paralogous genes, suggesting adaptations to narrow ecological niches. These features may have contributed to the abundance of the two taxa in specific regions of the ocean, and may have hindered their cultivation. We demonstrate the power of single cell DNA sequencing to generate reference genomes of uncultured taxa from a complex microbial community of marine bacterioplankton. A combination of single cell genomics and metagenomics enabled us to analyze the genome content, metabolic adaptations, and biogeography of these taxa.

Published

2009