The future of genomics in polar and alpine cyanobacteria

Chrismas, Nathan; Anesio, Alexandre M.; Sánchez‐Baracaldo, Patricia

doi:10.1093/femsec/fiy032

Cited by 25 publications

(28 citation statements)

References 145 publications

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“…Several molecular studies have focused on the cyanobacterial diversity of aquatic ecosystems in the Arctic and Antarctica (Comte et al., ; Strunecký et al, ; Taton et al., ), but studies focusing on the terrestrial ecosystems dominated by BSCs have been scarce (Pushkareva et al., ; Wood, Rueckert, Cowan, & Cary, ). Additionally, little is known concerning their phylogenetic affiliations, geographic distribution, physiology, and bioactive metabolites combined with the aspect of a limited number of Antarctic, Arctic or Alpine cyanobacterial strains available in culture collections.…”

Section: Discussionmentioning

confidence: 99%

“…Correct assignments of 16S rRNA sequences to publicly available sequences of species with unambiguous morphological characteristics such as the "eyespot" of Oculatella species proves the validity of the approach applied in this study. Although multigene analysis such as a combination of 16S and ITS is preferred, we could demonstrate that sequencing parts of the 16S in combination with light microscopy contributes to recent investigation pipelines for cyanobacteria of cold biomes (Chrismas et al, 2018).…”

Section: Species Level: Light Microscopy and Culture Derived Sequencesmentioning

confidence: 97%

“…Insights into cyanobacterial community compositions were made to critically challenge questions regarding biogeographic aspects. As recently highlighted by the group of Chrismas et al (2018), the applied approach contributes to genomic techniques to further our understanding of cyanobacteria in cold environments in terms of their evolution and ecology.…”

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confidence: 99%

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Strong in combination: Polyphasic approach enhances arguments for cold‐assigned cyanobacterial endemism

et al. 2018

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Cyanobacteria of biological soil crusts ( BSC s) represent an important part of circumpolar and Alpine ecosystems, serve as indicators for ecological condition and climate change, and function as ecosystem engineers by soil stabilization or carbon and nitrogen input. The characterization of cyanobacteria from both polar regions remains extremely important to understand geographic distribution patterns and community compositions. This study is the first of its kind revealing the efficiency of combining denaturing gradient gel electrophoresis ( DGGE ), light microscopy and culture‐based 16S rRNA gene sequencing, applied to polar and Alpine cyanobacteria dominated BSC s. This study aimed to show the living proportion of cyanobacteria as an extension to previously published meta‐transcriptome data of the same study sites. Molecular fingerprints showed a distinct clustering of cyanobacterial communities with a close relationship between Arctic and Alpine populations, which differed from those found in Antarctica. Species richness and diversity supported these results, which were also confirmed by microscopic investigations of living cyanobacteria from the BSC s. Isolate‐based sequencing corroborated these trends as cold biome clades were assigned, which included a potentially new Arctic clade of Oculatella . Thus, our results contribute to the debate regarding biogeography of cyanobacteria of cold biomes.

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Section: Discussionmentioning

confidence: 99%

Section: Species Level: Light Microscopy and Culture Derived Sequencesmentioning

confidence: 97%

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Strong in combination: Polyphasic approach enhances arguments for cold‐assigned cyanobacterial endemism

et al. 2018

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“…Details about genome bins are available in Table S2. We released scaffolded assemblies and protein predictions for all the bins having a completeness >90%, whether classified as cyanobacterial (14) or probable microbiome organisms (13). Raw read data for the 17 cyanobacterial cultutes have been deposited in the NCBI SRA (SAMN08623419 to SAMN08623435; bioproject PRJNA436342).…”

Section: Metagenome Sequencing and Assemblymentioning

confidence: 99%

“…Cyanobacteria are notoriously difficult to isolate and keep axenic in culture (1), especially polar strains (13), hence the need for tedious purification protocols (14). In consequence, all cyanobacterial culture collections include a majority of non-axenic cultures (e.g., Czech Collection of Algae and Cyanobacteria, CCALA; University of Toronto Culture Collection of Algae and Cyanobacteria, UTCC), with the notable exception of the Pasteur Culture Collection of Cyanobacteria, PCC.…”

Section: Introductionmentioning

confidence: 99%

Metagenomic assembly of new (sub)arctic Cyanobacteria and their associated microbiome from non-axenic cultures

Cornet

Bertrand

Hanikenne

et al. 2018

Preprint

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Cyanobacteria form one of the most diversified phylum of Bacteria. They are important ecologically as primary producers, for Earth evolution and biotechnological applications. Yet, Cyanobacteria are notably difficult to purify and grow axenically, 1 and most strains in culture collections contain heterotrophic bacteria that were likely associated to Cyanobacteria in the environment. Obtaining cyanobacterial DNA without contaminant sequences is thus a challenging and time-consuming task.Here, we deploy a metagenomic pipeline that enables the easy recovery of highquality genomes from non-axenic cultures. We tested this pipeline on 17 cyanobacterial cultures from the BCCM/ULC public collection and generated novel genome sequences for 15 arctic or subarctic strains, of which 14 early-branching organisms that will be useful for cyanobacterial phylogenomics. In parallel, we managed to assemble 31 co-cultivated bacteria from the same cultures and showed that they mostly belong to Bacteroidetes and Proteobacteria, some of them being very closely related in spite of geographically distant sampling sites. ImportanceComplete genomes of cold-adapted Cyanobacteria are underrepresented in databases, due to the difficulty to grow them axenically. In this work, we report the genome sequencing of 12 (sub)arctic and 3 temperate Cyanobacteria, along with 21 Proteobacteria and 5 Bacteroidetes recovered from their microbiome. Following the use of a state-of-the-art metagenomic pipeline, 12 of our new cyanobacterial genome assemblies are of high-quality, which indicates that even non-axenic cultures can yield complete genomes suitable for phylogenomics and comparative genomics. From a methodological point of view, we investigate the fate of SSU rRNA (16S) genes during metagenomic binning and observe that multi-copy rRNA operons are lost because of higher sequencing coverage and divergent tetranucleotide frequencies. Moreover, we devised a measure of genomic identity to compare metagenomic bins of different completeness, which allowed us to show that 2 Cyanobacteria-associated bacteria can be highly related in spite of considerable distance between collection points.

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Role of Cyanobacteria in the Ecology of Polar Environments

Goethem

Cowan

2019

Springer Polar Sciences

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The future of genomics in polar and alpine cyanobacteria

Cited by 25 publications

References 145 publications

Strong in combination: Polyphasic approach enhances arguments for cold‐assigned cyanobacterial endemism

Strong in combination: Polyphasic approach enhances arguments for cold‐assigned cyanobacterial endemism

Metagenomic assembly of new (sub)arctic Cyanobacteria and their associated microbiome from non-axenic cultures

Role of Cyanobacteria in the Ecology of Polar Environments

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