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. 2013 Apr 22:8:9.
doi: 10.1186/1745-6150-8-9.

Insights into archaeal evolution and symbiosis from the genomes of a nanoarchaeon and its inferred crenarchaeal host from Obsidian Pool, Yellowstone National Park

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Insights into archaeal evolution and symbiosis from the genomes of a nanoarchaeon and its inferred crenarchaeal host from Obsidian Pool, Yellowstone National Park

Mircea Podar et al. Biol Direct. .

Abstract

Background: A single cultured marine organism, Nanoarchaeum equitans, represents the Nanoarchaeota branch of symbiotic Archaea, with a highly reduced genome and unusual features such as multiple split genes.

Results: The first terrestrial hyperthermophilic member of the Nanoarchaeota was collected from Obsidian Pool, a thermal feature in Yellowstone National Park, separated by single cell isolation, and sequenced together with its putative host, a Sulfolobales archaeon. Both the new Nanoarchaeota (Nst1) and N. equitans lack most biosynthetic capabilities, and phylogenetic analysis of ribosomal RNA and protein sequences indicates that the two form a deep-branching archaeal lineage. However, the Nst1 genome is more than 20% larger, and encodes a complete gluconeogenesis pathway as well as the full complement of archaeal flagellum proteins. With a larger genome, a smaller repertoire of split protein encoding genes and no split non-contiguous tRNAs, Nst1 appears to have experienced less severe genome reduction than N. equitans. These findings imply that, rather than representing ancestral characters, the extremely compact genomes and multiple split genes of Nanoarchaeota are derived characters associated with their symbiotic or parasitic lifestyle. The inferred host of Nst1 is potentially autotrophic, with a streamlined genome and simplified central and energetic metabolism as compared to other Sulfolobales.

Conclusions: Comparison of the N. equitans and Nst1 genomes suggests that the marine and terrestrial lineages of Nanoarchaeota share a common ancestor that was already a symbiont of another archaeon. The two distinct Nanoarchaeota-host genomic data sets offer novel insights into the evolution of archaeal symbiosis and parasitism, enabling further studies of the cellular and molecular mechanisms of these relationships.

Reviewers: This article was reviewed by Patrick Forterre, Bettina Siebers (nominated by Michael Galperin) and Purification Lopez-Garcia.

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Figures

Figure 1
Figure 1
Maximum likelihood of theArchaeabased on SSU rRNA (872 sites) and the relationship of Nst1 and Acd1 with representative cultured and uncultured Archaea. The branch numbers indicate bootstrap support, shown only for major clades (* is <50%).
Figure 2
Figure 2
Composition analysis (sliding window of kmer tetranucleotide frequencies) of the Nst1 and Acd1 genomes, compared to those ofN.equitans and I.hospitalis.
Figure 3
Figure 3
Maximum likelihood phylogeny of theArchaeabased on concatenated ribosomal protein gene sequences (8077 sites) from representative complete genomes.
Figure 4
Figure 4
Reconstruction of the central carbon metabolism of Acd1 and Nst1 in comparison with pathways of thermoacidophilic Archaea (based on Zaparty and Siebers, 2011)[[32]].
Figure 5
Figure 5
Organization of archaeal flagellum (archaellum) genes in Nst1 and comparison to operons fromCrenarchaeota(S.a.) andEuryarchaeota(P.h.). The archaella genes are in shaded rectangles. The numbers represent the gene loci in the genomes. Several paralogs of FlaI (Nst1_088, 227 and 260) and one FlaG paralog (Nst1_560) are not shown.
Figure 6
Figure 6
Evolution of gene families inNanoarchaeotaandSulfolobales. (A) Predicted pattern of arCOG gene families gains (green) and losses (red) in the Nanoarchaeota and the Sulfolobales lineages. (B) Paralog density in the Crenarchaeota and Nanoarchaeota genomes.
Figure 7
Figure 7
Comparison between tRNAs ofN. equitansand Nst1. (A) Secondary structure models of Nst1 single transcript tRNAs that are transcribed from split genes in N. equitans. In red are the nucleotide differences present in N. equitans. (B) Secondary structures of tRNAs that are interrupted by an intron in both Nanoarchaeota, using the Nst1 sequence frames. The intron sequences and their insertion site (blue arrow) are indicated as well as the nucleotide polymorphisms in N. equitans (Insertions-red arrows, deletions-Δ).

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References

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