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Rhodopseudomonas palustris

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Rhodopseudomonas palustris
Scientific classification
Domain:
Phylum:
Class:
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Genus:
Species:
R. palustris
Binomial name
Rhodopseudomonas palustris
(Molisch 1907) van Niel 1944
Synonyms[1]
  • Rhodopseudomonas rutila Akiba et al. 1983

Rhodopseudomonas palustris is a rod-shaped, Gram-negative purple nonsulfur bacterium, notable for its ability to switch between four different modes of metabolism.[2]

R. palustris is found extensively in nature, and has been isolated from swine waste lagoons, earthworm droppings, marine coastal sediments, and pond water. Although purple nonsulfur bacteria are normally photoheterotrophic, R. palustris can flexibly switch among any of the four modes of metabolism that support life: photoautotrophic, photoheterotrophic, chemoautotrophic, or chemoheterotrophic.[2]

Etymology

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R. palustris is usually found as a wad of slimy masses, and cultures appear from pale brown to peach-colored. Etymologically, rhodum is a Greek noun meaning rose, pseudes is the Greek adjective for false, and monas refers to a unit in Greek. Therefore, Rhodopseudomonas, which implies a unit of false rose, describes the appearance of the bacteria. Palustris is Latin for marshy, and indicates the common habitat of the bacterium.[3]

Modes of metabolism

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R. palustris can grow with or without oxygen, or it can use light or inorganic or organic compounds for energy. It can also acquire carbon from either carbon dioxide fixation or green plant-derived compounds. Finally, R. palustris is also capable of fixing nitrogen for growth. This metabolic versatility has raised interest in the research community, and it makes this bacterium suitable for potential use in biotechnological applications.

Efforts are currently being made to understand how this organism adjusts its metabolism in response to environmental changes. The complete genome of the strain Rhodopseudomonas palustris CGA009 was sequenced in 2004 (see list of sequenced bacterial genomes) to get more information about how the bacterium senses environmental changes and regulates its metabolic pathways. R. palustris can deftly acquire and process various components from its environment, as necessitated by fluctuations in the levels of carbon, nitrogen, oxygen, and light.

R. palustris has genes that encode for proteins that make up light-harvesting complexes (LHCs) and photosynthetic reaction centers. LHCs and photosynthetic reaction centers are typically found in photosynthetic organisms such as green plants. Moreover, R. palustris can modulate photosynthesis according to the amount of light available, like other purple bacteria. For instance, in low-light circumstances, it responds by increasing the level of these LHCs that allow light absorption. The wavelengths of the light absorbed by R. palustris differ from those absorbed by other phototrophs.

R. palustris also has genes that encode for the protein ruBisCO, an enzyme necessary for carbon dioxide fixation in plants and other photosynthetic organisms. The genome of CGA009 also reveals the existence of proteins involved in nitrogen fixation (see diazotroph).

In addition, this bacterium can combine oxygen-sensitive and oxygen-requiring enzyme reaction processes for metabolism, thus it can thrive under varying and even very little levels of oxygen.

Commercial applications

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Biodegradation

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The genome of R. palustris consists of a variety of genes that are responsible for biodegradation. It can metabolize lignin and acids found in degrading plant and animal waste by metabolizing carbon dioxide.[4] In addition, it can degrade aromatic compounds found in industrial waste.[5] This bacterium is an efficient biodegradation catalyst in both aerobic and anaerobic environments. [citation needed]

Hydrogen production

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Purple phototrophic bacteria have drawn interest for their biotechnological applications. These bacteria can be used for bioplastic synthesis and hydrogen production. R. palustris has the unique characteristic of encoding for a vanadium-containing nitrogenase. It produces, as a byproduct of nitrogen fixation, three times more hydrogen than do molybdenum-containing nitrogenases of other bacteria.[2] The potential to manipulate R. palustris to be used as a reliable hydrogen production source or for biodegradation still lacks detailed knowledge of its metabolic pathways and regulation mechanisms.

Electricity generation

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R. palustris DX-1

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A strain of R. palustris (DX-1) is one of the few microorganisms and the first Alphaproteobacteria found to generate electricity at high power densities in low-internal resistance microbial fuel cells (MFCs).[6] DX-1 produces electric current in MFCs in the absence of a catalyst, without light or hydrogen production. This strain is exoelectrogenic, meaning that it can transfer electrons outside the cell. Other microorganisms isolated from MFCs cannot produce power densities higher than mixed cultures of microbes can under the same fuel-cell conditions, but R. palustris DX-1 can produce significantly higher power densities.

This Rhodopseudomonas species is widely found in wastewaters, and DX-1 generates electricity using compounds that Rhodopseudomonas is known to degrade. Therefore, this technology can be harnessed to produce bioelectricity from biomass and for wastewater treatment. However, the energy generated through this process is currently not sufficient for large-scale wastewater treatment.[7]

Rhodopseudomonas palustris TIE-1

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A 2014 study explained the cellular processes that allow the strain R. palustris TIE-1 to obtain energy through extracellular electron transfer.[8] TIE-1 curiously takes in electrons from materials rich in iron, sulfur, and other minerals found in the sediment beneath the surface. In an extraordinary strategy, as the microbes pull electrons away from iron, iron oxide crystallizes in the soil, eventually becomes conductive, and facilitates TIE-1 in oxidizing other minerals.

TIE-1 then converts these electrons into energy using carbon dioxide as an electron receptor. A gene that produces ruBisCo helps this strain of R. palustris to achieve energy generation through electrons. TIE-1 uses ruBisCo to convert carbon dioxide into nutrition for itself. This metabolism has phototrophic aspects, since the gene and the ability to uptake electrons are stimulated by sunlight. Therefore, R. palustris TIE-1 charges itself using minerals located deep in the soil, while using light by remaining on the surface itself. The ability of TIE-1 to use electricity can be used to manufacture batteries, but its efficiency as a fuel source remains questionable, but it has possible applications in the pharmaceutical industry.

References

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  1. ^ Hiraishi A, Santos TS, Sugiyama J, Komagata K (1992). "Rhodopseudomonas rutila is a Later Subjective Synonym of Rhodopseudomonas palustris". International Journal of Systematic Bacteriology. 42: 186–188. doi:10.1099/00207713-42-1-186.
  2. ^ a b c Larimer FW, Chain P, Hauser L, Lamerdin J, Malfatti S, Do L, et al. (January 2004). "Complete genome sequence of the metabolically versatile photosynthetic bacterium Rhodopseudomonas palustris". Nature Biotechnology. 22 (1): 55–61. doi:10.1038/nbt923. PMID 14704707.
  3. ^ Smith AW (1997). A gardener's handbook of plant names: their meanings and origins (Dover ed.). Mineola, NY: Dover Publications. p. 258. ISBN 978-0-486-29715-6.
  4. ^ Oshlag JZ, Ma Y, Morse K, Burger BT, Lemke RA, Karlen SD, et al. (January 2020). "Anaerobic Degradation of Syringic Acid by an Adapted Strain of Rhodopseudomonas palustris". Applied and Environmental Microbiology. 86 (3). doi:10.1128/AEM.01888-19. PMC 6974649. PMID 31732577.
  5. ^ Haq, Irshad; Christensen, Annika; Fixen, Kathryn (11 January 2024). "Evolution of Rhodopseudomonas palustris to degrade halogenated aromatic compounds involves changes in pathway regulation and enzyme specificity". Applied and Environmental Microbiology. 90 (2): e02104-23. doi:10.1128/aem.02104-23. PMC 10880631. Retrieved 15 March 2024.
  6. ^ Xing D, Zuo Y, Cheng S, Regan JM, Logan BE (June 2008). "Electricity generation by Rhodopseudomonas palustris DX-1". Environmental Science & Technology. 42 (11): 4146–4151. Bibcode:2008EnST...42.4146X. doi:10.1021/es800312v. PMID 18589979.
  7. ^ Pant D, Van Bogaert G, Diels L, Vanbroekhoven K (March 2010). "A review of the substrates used in microbial fuel cells (MFCs) for sustainable energy production". Bioresource Technology. 101 (6): 1533–1543. doi:10.1016/j.biortech.2009.10.017. PMID 19892549.
  8. ^ Bose A, Gardel EJ, Vidoudez C, Parra EA, Girguis PR (February 2014). "Electron uptake by iron-oxidizing phototrophic bacteria". Nature Communications. 5: 3391. Bibcode:2014NatCo...5.3391B. doi:10.1038/ncomms4391. PMID 24569675.
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