Hydrogenobacter thermophilus

Hydrogenobacter thermophilus is an extremely thermophilic, straight rod (bacillus) bacterium.^[1] TK-6 is the type strain for this species.^[1] It is a Gram negative, non-motile, obligate chemolithoautotroph.^[1] It belongs to one of the earliest branching order of Bacteria.^[2] H. thermophilus TK-6 lives in soil that contains hot water.^[1] It was one of the first hydrogen oxidizing bacteria described leading to the discovery, and subsequent examination of many unique proteins involved in its metabolism.^[1] Its discovery contradicted the idea that no obligate hydrogen oxidizing bacteria existed, leading to a new understanding of this physiological group.^[1] Additionally, H. thermophilus contains a fatty acid composition that had not been observed before.^[1]

History

Hydrogenobacter thermophilus TK-6 was originally discovered by Toshiyuki Kawasumi at the Department of Agricultural Chemistry, University of Tokyo in 1980.^[1] TK-6 was found with four other previously unknown hydrogen oxidizing bacteria.^[1] The bacterium was isolated from hot water containing soils samples from mines of the Izu Peninsula, Japan.^[1] The colonies were isolated onto a medium made of 1.5% Bacto-Agar and a specific trace element solution consisting of MoO₃, ZnSO₄·H₂O, CuSO₄·5H₂O, H₃BO₃, MnSO₄·H₂O and CoCl₂·H₂O.^[3] Prior to the discovery of Hydrogenobacter thermophilus, only one extremely thermophilic, aerobic and hydrogen-oxidizing bacterium had been described (Bacillus schlegelii).^[1] In addition, H. thermophilus has both morphological and physiological differences that vary from processes in B. schegelii, suggesting there are multiple means for being viable in different environments.^[1] Until the discovery of H. thermophilus, it was thought that no obligate chemolithotrophic hydrogen oxidizing bacteria existed.^[1]

Characterization

Biology

Hydrogenobacter thermophilus is a straight rod (bacillus) bacterium and an extreme thermophile.^[1] The size is about .3-.5 microns in width and 2-3 microns in length.^[1] Gram staining was done using a Hucker Modification and the reaction was found to be Gram negative.^[1] Motility and sporulation were tested using hanging cell method and Dorner method, respectively, and both were found to be negative.^[1] The novel fatty acid composition was freed though a nicotinamide adenine dinucleotide phosphate containing solution.^[1] The composition was found to be C18:0, C 20:1, 2 carbons longer than any composition seen before.^[1] The optimum growth conditions are: temperature between 70 and 75 °C, freshwater, pH around 7.2.^[1] The habitat is soil that contains hot, fresh water (70-75 °C) from springs of the Izu Peninsula, Japan.^[1]

Metabolism

Hydrogenobacter thermophilus is an obligate chemolithoautotroph.^[1] H. thermophilus undergoes aerobic respiration or anaerobic respiration via denitrification.^[4] The electron donor is the molecular form of hydrogen, thiosulfate, or elemental sulfur.^[4] Nitrogen sources are Ammonium and Nitrate salts.^[1] This bacterium utilizes a special form of the reductive tricyclic acid cycle (Reverse Krebs cycle) to fix CO2.^[4] Various metabolic processes were examined on a 1.5% Bacto-Agar with various organic compounds, incubated at 50-70 degrees C.^[1]

Phylogeny

16S rRNA gene sequencing places the family of H. thermolphilus, Aquificaceae, in close phylogenetic relationship to the family Aquifex based on 88.5% to 88.9% sequence similarity.^[2] H. thermophilus’s next immediate branch point is with the species Caldobacterium hydrogenopailum str. z-823 and the previous divergence branches with Hydrogenobacter strains.^[2] Genomic studies of the 16S ribosomal RNA gene in H. thermophilus also suggest that they are part of some of the earliest differentiating orders of bacteria termed the Aquificales.^[2] As a result of the early branch point in Aquificales’ genetic history, it indicates that the characteristics of the last common ancestor of life were possibly thermophilic and fixed carbon chemoautotrophically; this gives some direction to the evolution of life.^[2]

Genomics

In 2010, the entire genome of Hydrogenobacter thermophilus TK-6 was sequenced by Hiroyuki Arai et al.^[4] Sequencing was done via whole genome shotgun approach through the Sanger sequencing method, and assembled via the Paracel Genome Assembler.^[4] It was found to consist of 1,743,135 base pairs arranged in a circular chromosome with an estimated 1,864 protein coding genes and 22 pseudogenes.^[4] The genome was found to contain one 16S-23S-5S rRNA operon and 44 tRNA coding genes.^[4] The GC content of the genome is 44%,^[4] which at the time of its discovery was the lowest among any hydrogen oxidizing bacteria.^[1] H. thermophilus contains four gene clusters for membrane-bound hydrogenases.^[4] It should also be noted that H. thermophilus lacks the typical PSP (phosphoserine phosphatase) genes involved in amino acid metabolism.^[4] In addition, it is an obligate chemolithoautotroph, and so genes commonly used in carbon fixation were present.^[4] Genes that encode proteins involved in the RTCA (reductive tricyclic acid cycle) and gluconeogenesis were observed.^[4] The sox gene cluster, sqr gene and sorAB genes were also noted, and are involved in the sulfur oxidation protein complex, sulfide:quinone oxidoreductase and sulfite:cytochrome c oxidoreductase respectively.^[1] H. thermophilus also contains the necessary genes for nitrate reduction and assimilation.^[4]

Proteomics

Hydrogenobacter thermophilus has several unique proteins that allow it to be viable in its environment. Cytochrome b and cytochrome c are present in all strains.^[1] H. thermophilus strains also possess a very distinctive sulfur containing quinone, 2-Methylthio-1,4-naphthoquinone.^[1] This is the first case of non-Calvin-type pathway that is utilized to convert carbon dioxide into cellular components.^[5] In addition to the unique quinone, novel types of phosphoserine phosphatase (PSPs) were discovered and have been analyzed by preliminary crystallization and X-ray diffraction.^[6] Both iPSP1 and iPSP2 proteins found in H. thermophilus employ metal-ion-independent pathways while typical PSPs need Mg2+ for activity and are considered to be part of the haloacid dehalogenase-like hydrolase superfamily.^[6] iPSP1 is composed of two PspA subunits, while iPSP2 is a heterodimer and has both PspA and PspB subunits.^[6] iPSP1 and iPSP2 were observed to share a strong binding affinity towards L-phosphoserine, which supports its activity as a PSP.^[6] Novel proteins such as citryl-CoA synthetase (CCS) and ciitryl-CoA (CLL)are utilized within the reductive TCA cycle (Reverse Krebs cycle).^[7] These proteins were discovered and characterized through activity purification, SDS-PAGE analysis, and gel filtration chromatography.^[7] Additionally, oligionucleotide probes were employed in order to sequence and clone the related genes.^[7] The cleavage of citryl-CoA to acetyl-CoA and oxaloacetate occurs in a two step process.^[7] First, citryl-coA synthetase catalyzes the formation of citryl-CoA, which is immediately cleaved by citryl-CoA lyase.^[7] It was also observed that there is significant level of protein sequence homology between the CCL protein and the C-terminal region of ATP citrate lyase (ACL), an enzyme commonly employed by the reductive TCA cycle.^[7]

References

Further reading

• Ishii, Masaharu (August 2012). "Crystallization and preliminary X-ray diffraction analysis of a novel type of phosphoserine phosphatase from Hydrogenobacter thermophilus TK-6". Acta Crystallographica Section F. 68 (Part 8): 911–913. doi:10.1107/S1744309112025213. 

External links

• Type strain of Hydrogenobacter thermophilus at BacDive - the Bacterial Diversity Metadatabase