Archaeal Richmond Mine acidophilic nanoorganisms

Archaeal Richmond Mine acidophilic nanoorganisms (ARMAN) were first discovered in an extremely acidic mine located in northern California (Richmond Mine at Iron Mountain) by Brett Baker in Jill Banfield's laboratory at the University of California Berkeley. These novel groups of archaea named ARMAN-1, ARMAN-2 (Candidatus Micrarchaeum acidiphilum ARMAN-2 ), and ARMAN-3 were missed by previous PCR-based surveys of the mine community because the ARMANs have several mismatches with commonly used PCR primers for 16S rRNA genes. Baker et al.[1] detected them in a later study using shotgun sequencing of the community. The three groups were originally thought to represent three unique lineages deeply branched within the Euryarchaeota, a subgroup of the Archaea. However, this has been revised, based on more complete archaeal genomic tree, that they belong to a super phylum named DPANN.[2] The ARMAN groups now comprise deeply divergent phyla named Micrarchaeota and Parvarchaeota.[3] Their 16S rRNA genes differ by as much as 17% between the three groups. Prior to their discovery all of the Archaea shown to be associated with Iron Mountain belonged to the order Thermoplasmatales (e.g., Ferroplasma acidarmanus).

ARMAN (uncultured acidophilic lineages)
Scientific classification
Domain:
Phylum:

Distribution

Examination of different sites in the mine using fluorescent probes specific to the ARMAN groups has revealed that they are always present in communities associated with acid mine drainage (AMD), at Iron Mountain in northern California, that have pH < 1.5. They are usually found in low abundance (5–25%) in the community. Recently, closely related organisms have been detected in an acidic boreal mire or bog in Finland,[4] another acid mine drainage site in extreme environments of Rio Tinto, southwestern Spain[5] and from weak alkaline deep subsurface hot spring in Yunohama, Japan.[6]

Cell structure and ecology


Using cryo-electron tomography an extensive 3D characterization of uncultivated ARMAN cells within mine biofilms has been done (Comolli et al. 2009[7]). This has revealed that they are right at the cell size predicted to be the lower limit for life, 0.009 µm3 and 0.04 µm3 (NRC Steering group). They also found that despite their unusually small cell size it is common to find more than one type of virus attached to the cells while in the biofilms. Furthermore, the cells contain on average ≈92 ribosomes per cell, whereas the average E. coli cell grown in culture contains ≈10,000 ribosomes. This suggests that for ARMAN cells a much more limited number of metabolites are present in a given cell. It raises questions about what the minimal requirements are for a living cell.

3D reconstructions of ARMAN cells in the environment has revealed that a small number of them attach to other Archaea of the order Thermoplasmatales (Baker et al. 2010 [8]). The Thermoplasmatales cells appear to penetrate the cell wall to the cytoplasm of the ARMAN cells.[9] The nature of this interaction hasn't been determined. It could be some sort of parasitic or symbiotic interaction. It is possible that ARMAN is getting some sort of metabolite that it is not able to produce on its own.

Genomics and proteomics

The genomes of three ARMAN groups have been sequenced at the DOE Joint Genome Institute during a 2006 Community Sequencing Program (CSP). These three genomes were successfully binned from the community genomic data using ESOM or Emergent Self-Organizing Map clustering of tetra-nucleotide DNA signatures (Dick et al. 2009[10]).

The first draft of Candidatus Micrarchaeum acidiphilum ARMAN-2 is ≈1 Mb (3 scaffolds, Baker et al.). PNAS 2010.[8] The ARMAN-2 has recently been closed using 454 and Solexa sequencing of other biofilms to close the gaps and is being prepared for submission to NCBI. The genomes of ARMAN-4 and ARMAN-5 (roughly 1 Mb as well) have unusually average genes sizes, similar to those seen in endosymbiotic and parasitic bacteria. This may be signature of their inter-species interactions with other Archaea in nature (Baker et al. 2010 [8]). Furthermore, the branching of these groups near the Euryarchaea/Crenarchaea divide is reflected in them sharing many genetic aspects of both Crenarchaea and Euryarchaea. Specifically they have many genes that had previously only been identified in Crenarchaea. It is difficult to elucidate many of the commonly known metabolic pathways in ARMAN due to the unusually high number of unique genes that have been identified in their genomes.

A novel type of tRNA splicing endonuclease, involved in the processing of tRNA, has been discovered in ARMAN groups 1 and 2 (Fujishima et al. 2011[11]). The enzyme consists of two duplicated catalytic units and one structural unit encoded on a single gene, representing a novel three-unit architecture.

References

  1. Baker, Brett J.; et al. (2006). "Lineages of Acidophilic Archaea Revealed by Community Genomic Analysis". Science. 314 (5807): 1933–1935. Bibcode:2006Sci...314.1933B. doi:10.1126/science.1132690. PMID 17185602.
  2. Rinke, C; Schwientek, P; Sczyrba, A; Ivanova, NN; Anderson, IJ; Cheng, JF; Darling, A; Malfatti, S; Swan, BK; Gies, EA; Dodsworth, JA; Hedlund, BP; Tsiamis, G; Sievert, SM; Liu, WT; Eisen, JA; Hallam, SJ; Kyrpides, NC; Stepanauskas, R; Rubin, EM; Hugenholtz, P; Woyke, T (2013). "Insights into the phylogeny and coding potential of microbial dark matter". Nature. 499 (7459): 431–437. Bibcode:2013Natur.499..431R. doi:10.1038/nature12352. hdl:1912/6194. PMID 23851394.
  3. Castelle, CJ; Wrighton, KC; Thomas, BC; Hug, LA; Brown, CT; Wilkins, MJ; Frischkorn, KR; Tringe, SG; Singh, A; Markillie, LM; Taylor, RC; Williams, KH; Banfield, JF (2015). "Genomic Expansion of Domain Archaea Highlights Roles for Organisms from New Phyla in Anaerobic Carbon Cycling". Current Biology. 25 (6): 690–701. doi:10.1016/j.cub.2015.01.014. PMID 25702576.
  4. Juottonen et al. Seasonality of rDNA- and rRNA-derived archaeal communities and methanogenic potential in a boreal mire, ISME Journal 24 July 2008
  5. Amaral-Zettler et al. Microbial community structure across the tree of life in the extreme Río Tinto, ISME Journal 2010
  6. Murakami et al. Metatranscriptomic analysis of microbes in an ocean-front deep subsurface hot spring reveals novel small RNAs and type-specific tRNA degradation, Appl Environ Microbiol 2011
  7. Commolli, LR et al. Three-dimensional analysis of the structure and ecology of a novel, ultra-small archaeon, ISME Journal 3, 159–167.
  8. Baker; et al. (2010). "Enigmatic, ultrasmall, uncultivated Archaea". Proc. Natl. Acad. Sci. 107 (19): 8806–8811. Bibcode:2010PNAS..107.8806B. doi:10.1073/pnas.0914470107. PMC 2889320. PMID 20421484.
  9. Sanders, Robert (3 May 2010). "Weird, ultra-small microbes turn up in acidic mine drainage".
  10. Dick et al. Community-wide analysis of microbial genome sequence signatures. Genome Biology 10:R85
  11. Fujishima; et al. (2011). "A novel three-unit tRNA splicing endonuclease found in ultrasmall Archaea possesses broad substrate specificity". Nucleic Acids Res. 39 (22): 9695–704. doi:10.1093/nar/gkr692. PMC 3239211. PMID 21880595.
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