Natranaerobius thermophilus

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Classification

Phylogenetic tree of N. thermophilus

Domain: Bacteria

Phylum: Firmicutes

Class: Clostridia

Order: Natranaerobiales

Family: Natranaerobiaceae


Species

Natranaerobius thermophilus

NCBI Taxonomy ID: 59001

Description and Significance

Electron microscopy of N. thermophilus

First discovered and isolated in 2005, N. thermophilus was characterized as the first identified truly anaerobic, halophilic alkalithermophilic organism. The bacterium is a rod-shaped, non-motile, non-sporeforming bacteria. It is an obligate anaerobe and Gram-positive.

Being a polyextremophile, it thrives in multiple extremes of the environment. The bacteria are obligate alkaphiles and obligate halophiles. As such, N. thermophilus has various growth optima. Its preferred temperature is 53°C, with a culturable temperature range of 30-57°C. Its pH optima is 9.5, with a range of pH 8.5-10.6, at 55°C. Optimal growth occurs with a salt concentration of around 3.3-3.9 M Na+ (range 1.5-4.9 M Na+). This polyextremophile provides significant scientific insight as to the strategies it uses for sirvival.

Genome Structure

The genome of N. thermophilus was sequenced in 2011 and consists of one circular 3.16 mbp chromosome and two smaller plasmids, one being 17.2 kbp and the other 8.69 kbp. The G+C content of the whole genome was found to be 36.4%. Its plasmids, pNTHE01 and pNTHE02 have GC contents of 34.1% and 35.7%, respectively. [4]

Many genes were recognized that are believed to be associated with the bacteria's polyextremophile capabilities. From the genome sequence analysis, there are many proteins that allow for life under such extreme conditions: alkaline pH, elevated temperature, and high salinity. Three genes for L-glutamine synthetase, 15 genes for glycine betaline ABC transporters, four genes for glycine betaine/L-proline ABC transporters, and three genes for betaine/carnitine/chlorine transporters have been found, as well as the gsmA gene and the sdmA gene that endode for de novo synthesis of solute glycine betaine. [4]

Cell Structure, Metabolism and Life Cycle

Schematic of N. thermophilus bioenergetic membrane transport proteins

The cell structure are straight to curved rods, 0.2-0.4 µm in diameter, and 3-5 µm in length. Cells either aggregated into chains or were found singular and non-motile.

Some of the carbon and energy sources utilized by N. thermophilus are: tryptone, fructose, ribose, pyruvate, trimethylamine, acetate, xylose, peptone, among others. Its main organic fermentation products from sucrose are formate and acetate. It utilizes fumarate, sulface, nitrate, and iron(III) citrate as electron acceptors. [3]

Many of the extremophile capabilities of N. thermophilus are attributed to the membrane transport proteins, like anitporters and symporters. "The genome sequence analysis revealed five genes that encode Na+/proline symporters, two for Na+/glutamate symporters, and seven for K+ transport systems, which together with a specific K+/H+ antiporter regulate the intracellular K+ concentration." [4] There were also seven sodium and potassium proton antiporters found, with a K+ antiporter and 3 K+ transporters being experimentally verified.

The extreme halophilic alkaline conditions that N. thermohiilus lives in require that it has mechanisms for cytoplasm acidification. To achieve this, its chromosome "contains genes for 11 monovalent cation/proton antiporters of the NhaC type, a gene cluster encoding a multisubunit cation/proton antiporter of the CPA-3 family, four monovalent cation/proton antiporters of the CPA1 and CPA2 family, and one gene encoding a cation/proton antiporter of the NdhF-a family." [4]

In order to maintain structural stability, N. thermophilus was found to contain four genes that encoded orthologous rRNA MTases and three orthologous tRNA MTases. These assist with stabilization of DNA and RNA at high temperatures. 12 heat shock proteins were also identified.


Ecology and Pathogenesis

Original discovery of N. thermophilus was isolated from the sediment in an alkaline, hypersaline, Lake Fazda in Wadi An Natrun, Egypt, in 2005. The salinity of the water in the lake was 4.7 M and had a pH of 9.8. At the time, the family, order, genus, and species identified were all novel lineages discovered.

As this organism utilizes unique combinations of adaptation mechanisms, it is considered to be an excellent model organism. From this bacterium, scientists have been able to further study anaerobic halophilic alkalithermophiles and their features that allow them to thrive in a vast array of environmental extremes.

No known pathogenicity has been determined in this organism.

References

[1]Mesbah, Noha., Cook, Gregory., Wiegel, Juergen. "The halophilic alkalithermophile "Natranaerobius thermophilus" adapts to multiple environmental extremes using a large repertoire of Na+(K+)/H+ antiporters". Molecular Microbiology. 2009. Volume 74. p. 270-281.

[2]Mesbah, Noha., Hedrick, David., Peacock, Aaron., Rohde, Manfred., Wiegel, Juergen. "Natranaerobius thermophilus gen. nov., sp. nov., a halophilic, alkalithermophilic bacterium from soda lakes of the Wadi An Natrun, Egypt, and proposal of Natranaerobiaceae fam. nov. and Natranaerobiales ord. nov.

[3]"Natranaerobius thermophilus". I. V. Grigoriev, H. Nordberg, I. Shabalov, A. Aerts, M. et. al. Nucleic Acids Res 2011 0: gkr947v1-gkr947

[4]Zhao, Baisuo., Mesbah, Noha., Dalin, Eileen., Goodwin, Lynne., et. al. Complete Genome Sequence of the Anaerobic, Halophilic Alkalithermophile "Natranaerobius thermophilus". Journal of Bacteriology. 2011. Volume 193. p. 4023-4024.

Author

Page authored by Zach Geurin, Caroline Moon, and Mike Reitmeyer, student of Prof. Jay Lennon at Michigan State University.

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