UGA is an additional glycine codon in uncultured SR1 bacteria from the human microbiota

Campbell, James H.; O’Donoghue, Patrick; Campbell, Alisha G.; Schwientek, Patrick; Sczyrba, Alexander; Woyke, Tanja; Söll, Dieter; Podar, Mircea

doi:10.1073/pnas.1303090110

Cited by 272 publications

(320 citation statements)

References 37 publications

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“…13a). The same recoding was found and biochemically validated in candidate phylum SR1 very recently 41 , suggesting that this codon reassignment may be phylogenetically widespread in uncharacterized lineages. This expands the known alternative coding for UGA, which has previously been reported for selenocysteine 42 and tryptophan 43,44 .…”

Section: Functional Diversity and Novel Findingssupporting

confidence: 56%

Insights into the phylogeny and coding potential of microbial dark matter

Rinke

Schwientek

Sczyrba

et al. 2013

Nature

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2,134

2,042

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Genome sequencing enhances our understanding of the biological world by providing blueprints for the evolutionary and functional diversity that shapes the biosphere. However, microbial genomes that are currently available are of limited phylogenetic breadth, owing to our historical inability to cultivate most microorganisms in the laboratory. We apply single-cell genomics to target and sequence 201 uncultivated archaeal and bacterial cells from nine diverse habitats belonging to 29 major mostly uncharted branches of the tree of life, so-called 'microbial dark matter'. With this additional genomic information, we are able to resolve many intra-and inter-phylum-level relationships and to propose two new superphyla. We uncover unexpected metabolic features that extend our understanding of biology and challenge established boundaries between the three domains of life. These include a novel amino acid use for the opal stop codon, an archaeal-type purine synthesis in Bacteria and complete sigma factors in Archaea similar to those in Bacteria. The single-cell genomes also served to phylogenetically anchor up to 20% of metagenomic reads in some habitats, facilitating organism-level interpretation of ecosystem function. This study greatly expands the genomic representation of the tree of life and provides a systematic step towards a better understanding of biological evolution on our planet.Microorganisms are the most diverse and abundant cellular life forms on Earth, occupying every possible metabolic niche. The large majority of these organisms have not been obtained in pure culture and we have only recently become aware of their presence mainly through cultivationindependent molecular surveys based on conserved marker genes (chiefly small subunit ribosomal RNA; SSU rRNA) or through shotgun sequencing (metagenomics) 1,2 . As an increasing number of environments are deeply sequenced using next-generation technologies, diversity estimates for Bacteria and Archaea continue to rise, with the number of microbial 'species' predicted to reach well into the millions 3 . According to SSU rRNA-based phylogeny, these fall into at least 60 major lines of descent (phyla or divisions) within the bacterial and archaeal domains 4

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Section: Functional Diversity and Novel Findingssupporting

confidence: 56%

Insights into the phylogeny and coding potential of microbial dark matter

Rinke

Schwientek

Sczyrba

et al. 2013

Nature

Self Cite

2,134

2,042

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“…For example, we demonstrated that single-cell genomes from uncultivated phyla substantially improve the phylogenetic anchoring of metagenomic reads 1 . Mapping of metagenome sequences to single-cell genomes has not only been applied to validating metagenome assembly and binning 7 but also to subsequently improving the single-cell assemblies, as has been shown for SR1 bacteria, atribacteria and ammoniaoxidizing archaea [8][9][10] . Other studies successfully used fragment recruitment by single-cell genomes to investigate biogeographic distribution of uncultivated, marine taxa 11,12 .…”

Section: Introductionmentioning

confidence: 99%

Obtaining genomes from uncultivated environmental microorganisms using FACS–based single-cell genomics

et al. 2014

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single-cell genomics is a powerful tool for exploring the genetic makeup of environmental microorganisms, the vast majority of which are difficult, if not impossible, to cultivate with current approaches. Here we present a comprehensive protocol for obtaining genomes from uncultivated environmental microbes via high-throughput single-cell isolation by Facs. the protocol encompasses the preservation and pretreatment of differing environmental samples, followed by the physical separation, lysis, whole-genome amplification and 16s rrna-based identification of individual bacterial and archaeal cells. the described procedure can be performed with standard molecular biology equipment and a Facs machine. It takes <12 h of bench time over a 4-d time period, and it generates up to 1 mg of genomic Dna from an individual microbial cell, which is suitable for downstream applications such as pcr amplification and shotgun sequencing. the completeness of the recovered genomes varies, with an average of ~50%.

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“…To estimate the number of bacterial genomes in a given collection of scaffolds in a raw assembly or in a curated genome bin, and to visualize the distribution of HMM hits for each bacterial single-copy gene, we used the anvi'o script 'gen-stats-for-single-copy-genes', which reports the most frequent number in the list of number of hits per single-copy gene as the estimated number of bacterial genomes in a collection of scaffolds. The script uses HMMer v3.1b2 [39] to search for Hidden Markov Profiles (HMMs) of 139 bacterial single-copy genes identified by Campbell et al [11], and the R library 'ggplot' v1.0.0 [40,41] to plot results.…”

Section: Methodsmentioning

confidence: 99%

“…Although Boothby et al reported the lack of 16S rRNA genes in their assembly [29], anvi'o estimated that it contained at least 10 complete bacterial genomes (Fig. 2) using a bacterial single-copy gene collection [11]. This simple yet powerful step could identify cases of extensive contamination, and alert researchers to be diligent in identifying scaffolds originating from bacterial organisms.…”

Section: Best Practices To Assess Bacterial Contaminationmentioning

confidence: 99%

“…Due to the extensive diversity of bacteria and archaea in most environmental samples [6,7], the field of metagenomics has rapidly evolved to accurately delineate genomes in assembly results. Today, microbiologists often exploit two essential properties of bacterial and archaeal genomes to improve the "binning" step: (1) k-mer frequencies that are somewhat preserved throughout a single microbial genome [8], to identify contigs that likely originate from the same genome [9], and (2) a set of genes that occur in the vast majority of bacterial genomes as a single copy, to estimate the level of completion and contamination of genome bins [10,11,12]. These properties, along with differential coverage of contigs across multiple samples when such data exist, are routinely used to identify coherent microbial draft genomes in metagenomic assemblies [13,14,15,16].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Identifying contamination with advanced visualization and analysis practices: metagenomic approaches for eukaryotic genome assemblies

Delmont

Eren

2016

Preprint

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View the peer-reviewed version (peerj.com/articles/1839), which is the preferred citable publication unless you specifically need to cite this preprint.Delmont TO, Eren AM. 2016. Identifying contamination with advanced visualization and analysis practices: metagenomic approaches for eukaryotic genome assemblies. PeerJ 4:e1839 https://doi.org/10.7717/peerj.1839Identifying contamination with advanced visualization and analysis practices: metagenomic approaches for eukaryotic genome assemblies High-throughput sequencing provides a fast and cost effective mean to recover genomes of organisms from all domains of life. However, adequate curation of the assembly results against potential contamination of non-target organisms requires advanced bioinformatics approaches and practices. Here, we re-analyzed the sequencing data generated for the tardigrade Hypsibius dujardini using approaches routinely employed by microbial ecologists who reconstruct bacterial and archaeal genomes from metagenomic data. We created a holistic display of the eukaryotic genome assembly using DNA data originating from two groups and eleven sequencing libraries. By using bacterial single-copy genes, k- AbstractHigh-throughput sequencing provides a fast and cost effective mean to recover genomes of organisms from all domains of life. However, adequate curation of the assembly results against potential contamination of non-target organisms requires advanced bioinformatics approaches and practices. Here, we re-analyzed the sequencing data generated for the tardigrade Hypsibius dujardini using approaches routinely employed by microbial ecologists who reconstruct bacterial and archaeal genomes from metagenomic data. We created a holistic display of the eukaryotic genome assembly using DNA data originating from two groups and eleven sequencing libraries. By using bacterial single-copy genes, k-mer frequencies, and coverage values of scaffolds we could identify and characterize multiple near-complete bacterial genomes, and curate a 182 Mbp draft genome for H. dujardini supported by RNA-Seq data. Our results indicate that most contaminant scaffolds were assembled from Moleculo long-read libraries, and most of these contaminants have differed between library preparations. Our re-analysis shows that visualization and curation of eukaryotic genome assemblies can benefit from tools designed to address the needs of today's microbiologists, who are constantly challenged by the difficulties associated with the identification of distinct microbial genomes in complex environmental metagenomes.

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UGA is an additional glycine codon in uncultured SR1 bacteria from the human microbiota

Cited by 272 publications

References 37 publications

Insights into the phylogeny and coding potential of microbial dark matter

Insights into the phylogeny and coding potential of microbial dark matter

Obtaining genomes from uncultivated environmental microorganisms using FACS–based single-cell genomics

Identifying contamination with advanced visualization and analysis practices: metagenomic approaches for eukaryotic genome assemblies

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