Enigmatic Diphyllatea eukaryotes: culturing and targeted PacBio RS amplicon sequencing reveals a higher order taxonomic diversity and global distribution

Orr, Russell J. S.; Zhao, Sen; Klaveness, Dag; Yabuki, Akinori; Ikeda, Keiji; Watanabe, Makoto M.; Shalchian-Tabrizi, Kamran

doi:10.1186/s12862-018-1224-z

Cited by 11 publications

(14 citation statements)

References 66 publications

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“…The use of both genes was proposed to more robustly derive the origin of environmental sequences, particularly in the case of fast‐evolving taxa, but this was based on Sanger sequencing of clone libraries (Marande, López‐García, & Moreira, ). Near full‐length 18S amplicons and even longer fragments including parts of the 28S gene have also recently been sequenced with PacBio for group‐specific investigations, demonstrating that long‐read high‐throughput sequencing is a promising complement to Illumina for investigating the environmental diversity of eukaryotes (Heeger et al, ; Orr et al, ). Here, we extended the approach to ~4,500 bp of the rDNA operon across the whole phylogenetic diversity of eukaryotes.…”

Section: Discussionmentioning

confidence: 99%

“…In the last few years, PacBio sequencing has started to be applied to metabarcoding studies, primarily on prokaryotic 16S rDNA (Mosher et al, 2014;Schloss, Jenior, Koumpouras, Westcott, & Highlander, 2016;Wagner et al, 2016) and most recently on larger amplicons also including the 23S rDNA (Martijn et al, 2019). For eukaryotes, the 18S rDNA was nearly fully sequenced for targeted microbial groups (Orr et al, 2018), whilst longer regions also spanning the ITS and the large subunit (LSU) 28S gene were used to analyse fungal diversity (Heeger et al, 2018;Tedersoo & Anslan, 2019;Tedersoo, Tooming-Klunderud, & Anslan, 2018). These studies showed that in spite of the high error rates of PacBio, when applying a corrective process based on multiple sequence passes (Circular Consensus Sequences [CCS]) together with rigorous quality filtering, long-amplicon sequencing is emerging as a robust approach for studying environmental diversity.…”

Section: Introductionmentioning

confidence: 99%

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Long‐read metabarcoding of the eukaryotic rDNA operon to phylogenetically and taxonomically resolve environmental diversity

Jamy

Foster

Barbera

et al. 2019

Molecular Ecology Resources

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High‐throughput DNA metabarcoding of amplicon sizes below 500 bp has revolutionized the analysis of environmental microbial diversity. However, these short regions contain limited phylogenetic signal, which makes it impractical to use environmental DNA in full phylogenetic inferences. This lesser phylogenetic resolution of short amplicons may be overcome by new long‐read sequencing technologies. To test this idea, we amplified soil DNA and used PacBio Circular Consensus Sequencing (CCS) to obtain an ~4500‐bp region spanning most of the eukaryotic small subunit (18S) and large subunit (28S) ribosomal DNA genes. We first treated the CCS reads with a novel curation workflow, generating 650 high‐quality operational taxonomic units (OTUs) containing the physically linked 18S and 28S regions. To assign taxonomy to these OTUs, we developed a phylogeny‐aware approach based on the 18S region that showed greater accuracy and sensitivity than similarity‐based methods. The taxonomically annotated OTUs were then combined with available 18S and 28S reference sequences to infer a well‐resolved phylogeny spanning all major groups of eukaryotes, allowing us to accurately derive the evolutionary origin of environmental diversity. A total of 1,019 sequences were included, of which a majority (58%) corresponded to the new long environmental OTUs. The long reads also allowed us to directly investigate the relationships among environmental sequences themselves, which represents a key advantage over the placement of short reads on a reference phylogeny. Together, our results show that long amplicons can be treated in a full phylogenetic framework to provide greater taxonomic resolution and a robust evolutionary perspective to environmental DNA.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Long‐read metabarcoding of the eukaryotic rDNA operon to phylogenetically and taxonomically resolve environmental diversity

Jamy

Foster

Barbera

et al. 2019

Molecular Ecology Resources

View full text Add to dashboard Cite

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“…Using PacBio, near‐full‐length 18S rRNA gene sequences were obtained from environmental samples for the enigmatic protistan group of Diphyllatea (Orr et al. ). A few other studies mainly targeting fungal diversity were able to sequence longer fragments including also the ITS and 28S rRNA gene (Heeger et al.…”

Section: Current and Future Directionsmentioning

confidence: 99%

Perspectives from Ten Years of Protist Studies by High‐Throughput Metabarcoding

Santoferrara

Burki

Filker

et al. 2020

J Eukaryotic Microbiology

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During the last decade, high‐throughput metabarcoding became routine for analyzing protistan diversity and distributions in nature. Amid a multitude of exciting findings, scientists have also identified and addressed technical and biological limitations, although problems still exist for inference of meaningful taxonomic and ecological knowledge based on short DNA sequences. Given the extensive use of this approach, it is critical to settle our understanding on its strengths and weaknesses and to synthesize up‐to‐date methodological and conceptual trends. This article summarizes key scientific and technical findings, and identifies current and future directions in protist research that uses metabarcoding.

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“…The use of both genes was proposed to more robustly derive the origin of environmental sequences, particularly in the case of fast-evolving taxa, but this was based on Sanger sequencing of clone libraries (Marande, López-García, & Moreira, 2009). Near full-length 18S amplicons and even longer fragments including parts of the 28S have also recently been sequenced with PacBio for group-specific investigations, demonstrating that long-read high-throughput sequencing is a promising alternative to Illumina for investigating the environmental diversity of eukaryotes (Heeger et al, 2018;Orr et al, 2018). Here, we extended the approach to ~4500bp of the rDNA operon across the whole phylogenetic diversity of eukaryotes.…”

Section: Discussionmentioning

confidence: 99%

“…In the last two years, PacBio sequencing has started to be applied to metabarcoding studies, primarily on prokaryotic 16S rDNA (Mosher et al, 2014;Schloss, Jenior, Koumpouras, Westcott, & Highlander, 2016;Wagner et al, 2016) and most recently on larger amplicons also including the 23S rDNA (Martijn et al, 2017). For eukaryotes, the 18S rDNA was nearly fully sequenced for targeted microbial groups (Orr et al, 2018), whilst longer regions also spanning the ITS and the 28S gene were used to analyze fungal diversity (Heeger et al, 2018;Tedersoo, Tooming-Klunderud, & Anslan, 2018). These studies showed that in spite of the high error rates of PacBio, when applying a corrective process based on multiple sequence passes (Circular Consensus Sequences -CCS) together with rigorous quality filtering, long-amplicon sequencing is emerging as a robust approach for studying environmental diversity.…”

Section: Introductionmentioning

confidence: 99%

Long metabarcoding of the eukaryotic rDNA operon to phylogenetically and taxonomically resolve environmental diversity

Jamy

Foster

Barbera

et al. 2019

Preprint

View full text Add to dashboard Cite

High-throughput environmental DNA metabarcoding has revolutionized the analysis of microbial diversity, but this approach is generally restricted to amplicon sizes below 500 base pairs. These short regions contain limited phylogenetic signal, which makes it impractical to use environmental DNA in full phylogenetic inferences. However, new long-read sequencing technologies such as the Pacific Biosciences platform may provide sufficiently large sequence lengths to overcome the poor phylogenetic resolution of short amplicons. To test this idea, we amplified soil DNA and used PacBio Circular Consensus Sequencing (CCS) to obtain a ~4500 bp region of the eukaryotic rDNA operon spanning most of the small (18S) and large subunit (28S) ribosomal RNA genes. The CCS reads were first treated with a novel curation workflow that generated 650 high-quality OTUs containing the physically linked 18S and 28S regions of the long amplicons. In order to assign taxonomy to these OTUs, we developed a phylogeny-aware approach based on the 18S region that showed greater accuracy and sensitivity than similarity-based and phylogenetic placement-based methods using shorter reads. The taxonomically-annotated OTUs were then combined with available 18S and 28S reference sequences to infer a well-resolved phylogeny spanning all major groups of eukaryotes, allowing to accurately derive the evolutionary origin of environmental diversity.A total of 1019 sequences were included, of which a majority (58%) corresponded to the new long environmental CCS reads. Comparisons to the 18S-only region of our amplicons revealed that the combined 18S-28S genes globally increased the phylogenetic resolution, recovering specific groupings otherwise missing. The long-reads also allowed to directly investigate the relationships among environmental sequences themselves, which represents a key advantage over the placement of short reads on a reference phylogeny. Altogether, our results show that long amplicons can be treated in a full phylogenetic framework to provide greater taxonomic resolution and a robust evolutionary perspective to environmental DNA.

show abstract

Enigmatic Diphyllatea eukaryotes: culturing and targeted PacBio RS amplicon sequencing reveals a higher order taxonomic diversity and global distribution

Cited by 11 publications

References 66 publications

Long‐read metabarcoding of the eukaryotic rDNA operon to phylogenetically and taxonomically resolve environmental diversity

Long‐read metabarcoding of the eukaryotic rDNA operon to phylogenetically and taxonomically resolve environmental diversity

Perspectives from Ten Years of Protist Studies by High‐Throughput Metabarcoding

Long metabarcoding of the eukaryotic rDNA operon to phylogenetically and taxonomically resolve environmental diversity

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