Thermomicrobia Explained

The Thermomicrobia is a group of thermophilic green non-sulfur bacteria. Based on species Thermomicrobium roseum (type species) and Sphaerobacter thermophilus, this bacteria class has the following description:[1] [2]

The class Thermomicrobia subdivides into two orders with validly published names: Thermomicrobiales Garrity and Holt 2001 and Sphaerobacterales Stackebrandt, Rainey and Ward-Rainey 1997. Gram negative. Pleomorphic, non-motile, non-spore-forming rods. Non-sporulating. No diamino acid present. No peptidoglycan in significant amount. Atypical proteinaceous cell walls. Hyper-thermophilic, optimum growth temperature at 70-75 °C. Obligatory aerobic and chemoorganotrophic.

As thermophilic bacteria, members of this class are usually found in environments which are distant from human activity. However, they have features like improved growth in antibiotics and CO oxidizing activity, making them interesting topics of research (e.g. for biotechnology application).

History

In 1973, a strain of rose-pink thermophilic bacteria was isolated from Toadstool Spring in Yellowstone National Park, which was later named Thermomicrobium roseum and proposed as a novel species of the novel genus Thermomicrobium.[3] At that time the genus was categorized under family Achromobacteraceae, but it became a distinct phylum by 2001.

In 2004, it was proposed, on the basis of an analysis of genetic affiliations, that the Thermomicrobia should more properly be reclassified as a class belonging to the phylum Chloroflexota (formerly Chloroflexi). The bacteria Sphaerobacter thermophilus originally described as an Actinobacteria is now considered a Thermomicrobia.[4] In the same year, another strain of rose-pink thermophilic bacteria was isolated from Yellowstone National Park, which was named Thermobaculum terrenum.[5] Later analysis based on genome put this species under Thermomicrobia class.[6] However, the current standing of Thermobaculum terrenum is disputed.

In 2012, a thermo-tolerant nitrite-oxidizing bacterium was isolated from a bioreactor, which was named Nitrolancetus hollandica and proposed as a novel species later in 2014.[7] While it has nitrite-oxidizing activity, which is unique in the Thermomicrobia class, it is placed under the Thermomicrobia class based on 16s rRNA phylogeny.[8]

In 2014, two thermophilic, Gram-positive, rod-shaped, non-spore-forming bacteria (strains KI3T and KI4T) isolated from geothermally heated biofilms growing on a tumulus in the Kilauea Iki pit crater on the flank of Kilauea Volcano (Hawai'i) were proposed as representatives of new species based on 16s rRNA phylogeny. The KI3T strain, later named as Thermomicrobium carboxidum, is closely related to Thermomicrobium roseum. The KI4T strain, later named as Thermorudis peleae, was proposed as a type strain of new genus Thermorudis.[9]

In 2015, a thermophilic bacteria strain WKT50.2 isolated from geothermal soil in Waitike (New Zealand) was proposed to be a novel species, later named Thermorudis pharmacophila. Phylogenic analysis based on 16s rRNA place it within Thermomicrobia class, as close relative to Thermorudis peleae.

Characteristics

Living environment

Members of the class Thermomicrobia are broadly distributed across a wide range of both aquatic and terrestrial habitats. Thermomicrobium roseum was found in geothermally heated hot springs, Thermorudis pharmacophila and Thermobaculum terrenum from heated soils, and Thermomicrobium carboxidum and Thermorudis peleae from heated sediments[9] [10] In addition, Sphaerobacter thermophilus was found in sewage sludge that went through thermophilic treatment. The common features of their habitats include temperature ranging from around 65~75 °C and a pH around 6.0~8.0 (except for Nitrolancea hollandica which grow around 40 °C).

Metabolism

Members of Thermomicrobia class have variation in their basic metabolism. Nitrolancetus hollandica has nitrifying activity that utilize NO2 as energy source, which is unique in the whole Chloroflexota phylum. Thermomicrobium spp. and Sphaerobacter thermophilus have constitutive CO oxidizing not found in other species in this class.[11] However, species of this class do share some features, as listed below:

Antibiotic resistance

Members of Thermomicrobia class exhibit certain level of resistance against metronidazole and/or trimethoprim, which are clinically relevant for humans.[12] [13] Thermomicrobium carboxidum and Thermorudis peleae show resistance against both of those antibiotics, while Sphaerobacter thermophilus shows resistance against only metronidazole. Interestingly, Thermomicrobium roseum and Thermorudis pharmacophila have an increased growth in both metronidazole and trimethoprim, a rare trait even within antibiotic resistant bacteria. The mechanisms behind are currently undocumented, and further study is required on this topic.

Cell envelope structure

Members of Thermomicrobia class have various Gram-staining results. Thermomicrobium roseum, Sphaerobacter thermophilus and Thermorudis pharmacophila are reported to be Gram-negative and have a typical layered diderm cell envelope structure. However, their cell envelope composition are atypical compared to typical Gram-negative bacteria. Cell envelope of Thermomicrobium roseum lacks significant amount of peptidoglycan, which is fundamental for typical Gram-negative bacteria, while being rich in protein. Membrane lipids of Thermomicrobium roseum are mostly long chain diols instead of glycerol-based lipids commonly found in bacteria.[14] The same feature was found in Sphaerobacter thermophilus and Thermorudis pharmacophila. It was suggested that the high-protein and diol-based lipid composition are responsible for heat resistance of these bacteria.[15]

Meanwhile, other members of Thermomicrobia class are reported to be Gram-positive and have typical monoderm cell envelope.[9] There are some possible explanations of the inconsistency of Gram-staining result within the class. For Thermorudis pharmacophila, a possible explanation suggested by Houghton et al. is that it is actually an atypical monoderm bacterium, because its cell envelope contains amino acids usually associated with Gram-positive bacteria, have reaction to KOH, vancomycin and ampicillin, and lacks genes responsible for diderm formation. It is also suggested that further study is required to resolve this problem, since the inconsistent reports of cell envelope structure are found for the whole Chloroflexota phylum.

Taxonomy

The currently accepted taxonomy is based on the List of Prokaryotic names with Standing in Nomenclature (LPSN)[22] and National Center for Biotechnology Information (NCBI).[23]

See also

Notes and References

  1. Book: Bergey's Manual of Systematic Bacteriology, 2nd edn, vol. 1, The Archaea and the Deeply Branching and Phototrophic Bacteria. Garrity GM, Holt JG . Springer. 2001 . Boone DR, Castenholz RW, Garrity GM . New York. Phylum BVII. Thermomicrobia phy. nov..
  2. Hugenholtz P, Stackebrandt E . Reclassification of Sphaerobacter thermophilus from the subclass Sphaerobacteridae in the phylum Actinobacteria to the class Thermomicrobia (emended description) in the phylum Chloroflexi (emended description) . International Journal of Systematic and Evolutionary Microbiology . 54 . Pt 6 . 2049–51 . November 2004 . 15545432 . 10.1099/ijs.0.03028-0 . free .
  3. Jackson TJ, Ramaley RF, Meinschein WG . Thermomicrobium, a new genus of extremely thermophilic bacteria. . International Journal of Systematic and Evolutionary Microbiology . January 1973 . 23 . 1 . 28–36 . 10.1099/00207713-23-1-28 . free .
  4. Boone DR, Baker CC . Validation of publication of new names and new combinations previously effectively published outside the IJSEM. . International Journal of Systematic and Evolutionary Microbiology . 2002 . 52 . Pt 3 . 685–90 . https://web.archive.org/web/20100606222954/http://ijs.sgmjournals.org/cgi/reprint/52/3/685 . 6 June 2010 . dead . 10.1099/ijs.0.02358-0 . 12054225 .
  5. Botero LM, Brown KB, Brumefield S, Burr M, Castenholz RW, Young M, McDermott TR . Thermobaculum terrenum gen. nov., sp. nov.: a non-phototrophic gram-positive thermophile representing an environmental clone group related to the Chloroflexi (green non-sulfur bacteria) and Thermomicrobia . Archives of Microbiology . 181 . 4 . 269–77 . April 2004 . 14745485 . 10.1007/s00203-004-0647-7 . 31431143 .
  6. Kunisawa T . The phylogenetic placement of the non-phototrophic, Gram-positive thermophile 'Thermobaculum terrenum' and branching orders within the phylum 'Chloroflexi' inferred from gene order comparisons . International Journal of Systematic and Evolutionary Microbiology . 61 . Pt 8 . 1944–53 . August 2011 . 20833875 . 10.1099/ijs.0.026088-0 . free .
  7. Sorokin DY, Vejmelkova D, Lücker S, Streshinskaya GM, Rijpstra WI, Damste JS, Kleerbezem R, van Loosdrecht M, Muyzer G, Daims H . Nitrolancea hollandica gen. nov., sp. nov., a chemolithoautotrophic nitrite-oxidizing bacterium isolated from a bioreactor belonging to the phylum Chloroflexi . June 2014 . International Journal of Systematic and Evolutionary Microbiology . 64 . 6 . 1859–1865 . 10.1099/ijs.0.062232-0 . 24573161 .
  8. Sorokin DY, Lücker S, Vejmelkova D, Kostrikina NA, Kleerebezem R, Rijpstra WI, Damsté JS, Le Paslier D, Muyzer G, Wagner M, van Loosdrecht MC, Daims H . Nitrification expanded: discovery, physiology and genomics of a nitrite-oxidizing bacterium from the phylum Chloroflexi . The ISME Journal . 6 . 12 . 2245–56 . December 2012 . 22763649 . 3504966 . 10.1038/ismej.2012.70 .
  9. King CE, King GM . Thermomicrobium carboxidum sp. nov., and Thermorudis peleae gen. nov., sp. nov., carbon monoxide-oxidizing bacteria isolated from geothermally heated biofilms . International Journal of Systematic and Evolutionary Microbiology . 64 . Pt 8 . 2586–92 . August 2014 . 24814334 . 10.1099/ijs.0.060327-0 . free .
  10. Costa KC, Navarro JB, Shock EL, Zhang CL, Soukup D, Hedlund BP . Microbiology and geochemistry of great boiling and mud hot springs in the United States Great Basin . Extremophiles . 13 . 3 . 447–59 . May 2009 . 19247786 . 10.1007/s00792-009-0230-x . 24375281 .
  11. Wu D, Raymond J, Wu M, Chatterji S, Ren Q, Graham JE, Bryant DA, Robb F, Colman A, Tallon LJ, Badger JH, Madupu R, Ward NL, Eisen JA . Complete genome sequence of the aerobic CO-oxidizing thermophile Thermomicrobium roseum . PLOS ONE . 4 . 1 . e4207 . 2009-01-16 . 19148287 . 2615216 . 10.1371/journal.pone.0004207 . 2009PLoSO...4.4207W . free .
  12. News: Metronidazole Monograph for Professionals - Drugs.com. Drugs.com. 2018-10-11. en-US.
  13. News: Trimethoprim Monograph for Professionals - Drugs.com. Drugs.com. 2018-10-11. en-US.
  14. Pond JL, Langworthy TA, Holzer G . Long-chain diols: a new class of membrane lipids from a thermophilic bacterium . Science . 231 . 4742 . 1134–6 . March 1986 . 17818542 . 10.1126/science.231.4742.1134 . 1696788 . 1986Sci...231.1134P . 42023577 .
  15. Pond JL, Langworthy TA . Effect of growth temperature on the long-chain diols and fatty acids of Thermomicrobium roseum . Journal of Bacteriology . 169 . 3 . 1328–30 . March 1987 . 3818547 . 10.1128/jb.169.3.1328-1330.1987 . 211939 .
  16. Web site: The LTP . 20 November 2023.
  17. Web site: LTP_all tree in newick format. 20 November 2023.
  18. Web site: LTP_08_2023 Release Notes. 20 November 2023.
  19. Web site: GTDB release 08-RS214 . Genome Taxonomy Database. 10 May 2023.
  20. Web site: bac120_r214.sp_label . Genome Taxonomy Database. 10 May 2023.
  21. Web site: Taxon History . Genome Taxonomy Database. 10 May 2023.
  22. Web site: J.P. Euzéby . Thermomicrobia . List of Prokaryotic names with Standing in Nomenclature (LPSN) . 2022-07-20.
  23. Web site: Sayers. Thermomicrobia . 2022-03-20 . National Center for Biotechnology Information (NCBI) taxonomy database . etal.