Rhodothermus marinus: Difference between revisions

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''Rhodothermus marinus'' is a heterotrophic obligate aerobe that is thermophilic and slightly although strictly halophilic. The growth of this organism is dependent on a multitude of factors including temperature, salt and oxygen concentration, and the availability of organic material. Growth occurs at a temperature range of 54-77 degrees Celsius with optimal growth occurring at 65 degrees Celsius. ''Rhodotherms marinus'' has also been characterized at growing at NaCl concentrations optimally at 2% and not above 6%. During osmotic stress and growth at low pH, small amounts of solutes such as formic acid, acetic acid and some alcohols accumulate. Optimum pH for growth is 7.0, with no growth observed below pH 5.0. This species only utilizes a single carbon source, with slight differences in carbon sources between strains. The physiology of this microbe dictates a narrow niche for it to occupy. ''Rhodothermus marinus'' can only grow close to the openings of hot springs where oxygen is readily available and close to the surface of the water where the temperatures are warm [3]. Not much is known about any symbiotic relationships that ''Rhodothermus marinus'' might hold.
''Rhodothermus marinus'' is a heterotrophic obligate aerobe that is thermophilic and slightly although strictly halophilic. The growth of this organism is dependent on a multitude of factors including temperature, salt and oxygen concentration, and the availability of organic material. Growth occurs at a temperature range of 54-77 degrees Celsius with optimal growth occurring at 65 degrees Celsius. ''Rhodotherms marinus'' has also been characterized at growing at NaCl concentrations optimally at 2% and not above 6%. During osmotic stress and growth at low pH, small amounts of solutes such as formic acid, acetic acid and some alcohols accumulate. Optimum pH for growth is 7.0, with no growth observed below pH 5.0. This species only utilizes a single carbon source, with slight differences in carbon sources between strains. The physiology of this microbe dictates a narrow niche for it to occupy. ''Rhodothermus marinus'' can only grow close to the openings of hot springs where oxygen is readily available and close to the surface of the water where the temperatures are warm [3]. Not much is known about any symbiotic relationships that ''Rhodothermus marinus'' might hold.
[[Image:Canfield figure.JPG||270px|thumb|right]]
[[Image:Canfield figure.JPG||270px|thumb|left]]
The role of this microbe in biogeochemical cycling is ambiguous and still being elucidated. The genome of ''Rhodothermus. marinus'' was found in a study by Canfield et al. that studied the cryptic sulfur cycle in oxygen-minimum zone (OMZ) waters off the Chilean coast [4]. This biogeochemical cycling was dubbed cryptic because evidence of this cycling in the environment is hidden. Generally, the reduction of sulfate through respiration of specialized microbes generates sulfide. As sulfate dissipates sulfide accumulates, indicating microbial sulfate reduction. In this case, the accumulation of sulfide is mediated by sulfide oxidizing bacteria instead of reducing bacteria. Because sulfide is so efficiently re-oxidized, it does not accumulate in the water column which prevents sulfide toxicity. Nitrate plays an important role in this process, too. Sulfide oxidation is limited by nitrate reduction in OMZ waters, preventing sulfide toxicity seen in waters where marine sediments are rich in degradable biomass. This biomass fuels sulfate reduction, drastically increases sulfide production and overwhelms the nitrate pool. Nitrogen cycling is a complex process, and certain factors which may have had an influence on this study such as microbial cycling of ammonia in the oxycline, microbial anaerobic ammonia oxidation, and novel mechanisms that microbes employ to cope with sulfide limitation, were neglected. To elucidate this further, Canfield et al. calls for long term seasonal studies [7]. The involvement of ''Rhodothermus marinus'' in this cryptic sulfur cycle was not discussed in the paper or in any subsequent literature. It's presence in this environment is puzzling, as it is an obligate aerobe and requires specific factors for growth that may not be met in this environment. Hopefully future studies will elucidate the role of ''Rhodotherms marinus'' in this process.
The role of this microbe in biogeochemical cycling is ambiguous and still being elucidated. The genome of ''Rhodothermus. marinus'' was found in a study by Canfield et al. that studied the cryptic sulfur cycle in oxygen-minimum zone (OMZ) waters off the Chilean coast [4]. This biogeochemical cycling was dubbed cryptic because evidence of this cycling in the environment is hidden. Generally, the reduction of sulfate through respiration of specialized microbes generates sulfide. As sulfate dissipates sulfide accumulates, indicating microbial sulfate reduction. In this case, the accumulation of sulfide is mediated by sulfide oxidizing bacteria instead of reducing bacteria. Because sulfide is so efficiently re-oxidized, it does not accumulate in the water column which prevents sulfide toxicity. Nitrate plays an important role in this process, too. Sulfide oxidation is limited by nitrate reduction in OMZ waters, preventing sulfide toxicity seen in waters where marine sediments are rich in degradable biomass. This biomass fuels sulfate reduction, drastically increases sulfide production and overwhelms the nitrate pool. Nitrogen cycling is a complex process, and certain factors which may have had an influence on this study such as microbial cycling of ammonia in the oxycline, microbial anaerobic ammonia oxidation, and novel mechanisms that microbes employ to cope with sulfide limitation, were neglected. To elucidate this further, Canfield et al. calls for long term seasonal studies [7]. The involvement of ''Rhodothermus marinus'' in this cryptic sulfur cycle was not discussed in the paper or in any subsequent literature. It's presence in this environment is puzzling, as it is an obligate aerobe and requires specific factors for growth that may not be met in this environment. Hopefully future studies will elucidate the role of ''Rhodotherms marinus'' in this process.



Revision as of 01:27, 24 April 2012

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Classification

The Blue Lagoon Geothermal Spa Close to Reykjavik, Iceland. From: [1]

Domain: Bacteria; Phylum: Bacteroidetes; Class: Bacteriodetes (Chlorobi group); Order: Incertae sedis; Family: Rhodothermaceae; Genus: Rhodothermus

Description and Significance

Rhodothermus marinus form reddish-coloured, low convex colonies, 3-4 mm in diameter and with an entire edge. The bacteria also has Gram negative rods about 0.5 µm in diameter and 2-2.5 µm long.

Rhodothermus marinus can be found in several similar but distantly located geothermal habitats. Many have large fluctuations in environmental conditions. Temperatures higher than 65 ̊C allow for optimum activity and growth. Shallow water hot springs of Iceland have been a place for studying populations of Rhodothermus marinus. Rhodothermus marinus has also been found in other regions of the world including Portugal, Italy and Monserrat Island in the Caribbean Sea.

Most thermophiles that have been studied in the past have been found in deep-sea hydrothermal vents in the Pacific Ocean. The study of Rhodothermus marinus found in shallow-water hot springs in comparison to similar thermophiles found deep in the ocean can bring more understanding to these organisms’ ability to survive in extreme environments.

Phylogenetic tree highlighting the position of Rhodothermus. marinus strain R-10T relative to S. ruber, the second species within the ‘Rhodothermaceaea’.

Genome Structure

Complete genome sequencing of Rhodothermus marinus (strain R-10=DSM4252=ATCC43812) is a part of the Genomic Encyclopedia of Bacteria and Archaea project. This is the first time to obtain the complete genome sequence of the genus Rhodothermus, and the second sequence from members of the family Rhodothermaceae. The whole genome (3,386,737 bp) includes one main circular chromosome and one circular plasmid. The GC content is 64.3%, and the DNA coding region is about 92.5%. The length of the plasmid is 125 kbp. There are 2,914 protein-coding and 48 RNA genes among the total 2,962 predicted genes. Only 71.6% (2,122) genes were identified with a putative function. However, the other genes are designated as hypothetical proteins. Moreover, there were 51 pseudogenes identified. The genome project is deposited in the Genomes Online Database, and the complete genome sequence in Genebank (Nolan et al).

Cell Structure, Metabolism and Life Cycle

Scanning electron micrograph of R. marinus strain R-10T (Manfred Rohde, Helmholtz Centre for Infection Research, Braunschweig)

Rhodothermus marinus cells are rod shaped and are 0.5 µm in diameter and 2-2.5 µm long. They are convex, reddish in color, and contain a slime capsule. They are aerobic and halophilic. They require a high concentration of sodium chloride to grow. The cells are catalase positive and oxidase negative (Nolan et al). According to Batista et al, Rhodothermus marinus has a complex I structure, which consists of fourteen subunits. Seven are hydrophilic proteins located in the peripheral arm, the other 7 hydrophobic proteins in the membrane arm. There were many protein and peptide separation strategies. The combination of all of the methodologies allowed the identification of complex I canonical subunits, there was also a possible novel subunit, a PCD (pterin-4[alpha]-carbinolamine dehydratase). PCD possibly plays a regulatory role, though further research needs to be conducted.

Rhodothermus marinus is in a group of bacteria that are important degraders of organic matter under aerobic conditions. This bacteria contains all three main groups of enzymes: endocellulase, exocellulase, and beta-glucosidase. Endocellulase and exocellulase degrade cellulose to oligosaccharides and cellobiose. Cellobiose is hydrolyzed to glucose monomers by beta-glucosidase. (Hreggvidsson et al). Most strains use several common sugars, such as glucose, galactose, lactose, maltose, raffinose, and sucrose. Rhodothermus marinus JCM 9785 utilizes several amino acids while other strains are only reported to use aspartate, glutamate, asparagine, and glutamine.

Not much is known about the life cycle of Rhodothermus marinus.

Ecology

Reykjanes, Iceland.

Rhodothermus marinus was first isolated from submarine alkaline freshwater hot springs in Isafjardardjup, Iceland in 1988 and from other geothermal sites in Iceland including coastal springs from a borehole effluent in Oxarfjordur, Iceland, from borehole effluents from a powerplant at the Blue Lagoon, and from a salt factory in Reykjanes, Iceland. As well, it has been isolated from similar habitats in geothermal environments at various regions around the world, including Praia de Ribeira Quenta, Ferraria, Sa˜o Miguel in the Azores, Portugal, Stufe di Nerone near Naples, Italy, and on Monserrat island in the Carribean Sea. It should be noted that the populations of Rhodothermus marinus in these geographic locations are genetically distinct. High genetic diversity and low horizontal gene transfer indicate the populations at these geographically distinct sites are evolving independently and indicate that genetic drift and geographic isolation is an important mechanism in species divergence [3].

Rhodothermus marinus is a heterotrophic obligate aerobe that is thermophilic and slightly although strictly halophilic. The growth of this organism is dependent on a multitude of factors including temperature, salt and oxygen concentration, and the availability of organic material. Growth occurs at a temperature range of 54-77 degrees Celsius with optimal growth occurring at 65 degrees Celsius. Rhodotherms marinus has also been characterized at growing at NaCl concentrations optimally at 2% and not above 6%. During osmotic stress and growth at low pH, small amounts of solutes such as formic acid, acetic acid and some alcohols accumulate. Optimum pH for growth is 7.0, with no growth observed below pH 5.0. This species only utilizes a single carbon source, with slight differences in carbon sources between strains. The physiology of this microbe dictates a narrow niche for it to occupy. Rhodothermus marinus can only grow close to the openings of hot springs where oxygen is readily available and close to the surface of the water where the temperatures are warm [3]. Not much is known about any symbiotic relationships that Rhodothermus marinus might hold.

Canfield figure.JPG

The role of this microbe in biogeochemical cycling is ambiguous and still being elucidated. The genome of Rhodothermus. marinus was found in a study by Canfield et al. that studied the cryptic sulfur cycle in oxygen-minimum zone (OMZ) waters off the Chilean coast [4]. This biogeochemical cycling was dubbed cryptic because evidence of this cycling in the environment is hidden. Generally, the reduction of sulfate through respiration of specialized microbes generates sulfide. As sulfate dissipates sulfide accumulates, indicating microbial sulfate reduction. In this case, the accumulation of sulfide is mediated by sulfide oxidizing bacteria instead of reducing bacteria. Because sulfide is so efficiently re-oxidized, it does not accumulate in the water column which prevents sulfide toxicity. Nitrate plays an important role in this process, too. Sulfide oxidation is limited by nitrate reduction in OMZ waters, preventing sulfide toxicity seen in waters where marine sediments are rich in degradable biomass. This biomass fuels sulfate reduction, drastically increases sulfide production and overwhelms the nitrate pool. Nitrogen cycling is a complex process, and certain factors which may have had an influence on this study such as microbial cycling of ammonia in the oxycline, microbial anaerobic ammonia oxidation, and novel mechanisms that microbes employ to cope with sulfide limitation, were neglected. To elucidate this further, Canfield et al. calls for long term seasonal studies [7]. The involvement of Rhodothermus marinus in this cryptic sulfur cycle was not discussed in the paper or in any subsequent literature. It's presence in this environment is puzzling, as it is an obligate aerobe and requires specific factors for growth that may not be met in this environment. Hopefully future studies will elucidate the role of Rhodotherms marinus in this process.

Rhodothermus marinus may have implications for bioremediation, biotechnology, and bioengineering. Naturally, it decomposes organic matter releasing essential nutrients back into the environment. Being a thermophile, it has many thermostable enzymes, namely polysaccharide hydorlizing and DNA synthesis enzymes, which can be used in research [5]. Other enzymes belonging to Rhodothermus marinus have been found in multiple biochemical pathways. These enzymes are capable of degrading toluene, xylene, DDT, dioxin, naphthalene and aromatic hydrocarbons among others. Other enzymes are capable of synthesizing antibiotics such as streptomycin, penicillin, puromycin, cephalosporin, neomycin and novobiocin [8]. This is important because of the possibility to harness these enzymes in bioremediation efforts and in the production of pharmaceuticals beneficial to human health.

References

1. Nolan, M., Tindall, B., Pomrenke, H., Lapidus, A., Copeland, A., Glavina Del Rio, T., Lucas, S., Chen, F., Tice, H., Chen, J., Saunders, E., Han, C., Bruce, D., Goodwin, L., Chain, P., Pitluck, S., Ovchinikova, G., Pati, A., Lvanova, N., Mavromatis, K., Chen, A., Palaniappan, K., Land, M., Hauser, L., Chang, Y., Jeffries, C., Brettin, T., Göker, M., Bristow, J., Eisen, J., Markowitz, V., Hugenholtz, P., Kyrpides, N., Klenk, H., Detter, J. "Complete genome sequence of Rhodothermus marinus type strain (R-10T)". Standards in Genomic Sciences. 2009. Volume 1. p. 283–290.

2. Alfredsson, G., Jakob, K., Kristjansson, T., Hjorleifsdottir, S., and Stetter, K. "Rhodothermus marinus, gen. nov., sp. nov., a Thermophibic, Halophilic Bacterium from Submarine Hot Springs in Iceland". Journal of General Microbiology. 1988. Volume 134. p. 299-306.

3. S.H., Blondal, T., Hreggvidsson, G.O., Eggertsson, G., Petursdottir, S,. Hjorleifsdottir, S., Thorbjarnardottir, S.H., and Kristjansson, J.K. "Rhodothermus marinus : physiology and molecular biology" Extremophiles. 2006. Volume 10. p. 1-16.

4. Canfield, D., Stewart, F., Thamdrup, B., De Brabandere, L., Dalsgaard, T., Delong, E., Revsbech, D.,and Ulloa, O.Don E. "A Cryptic Sulfur Cycle in Oxygen-Minimum–Zone Waters off the Chilean Coast". Science. 2010. Volume 330. p. 1375-1377.

5. Hreggvidsson, GO., Kaiste, E., Holst, O., Eggertsson G., Palsdottir A., and Kristjansson, JK. "An Extremely Thermostable Cellulase from the Thermophilic Eubacterium Rhodothermus marinus". Applied and Environmental Microbiology. 1996. Volume 62. p. 3047-3049.

6. Batista, Ana P., et al. "Subunit composition of Rhodothermus marinus respiratory complex I." Analytical Biochemistry. 2010. 407(1). 104+.

7. Teske, A. "Cryptic Links in the Ocean". Science. 2010. Volume 330. p. 1326-1327

8. Kanehisa, M., Goto, S., Sato, Y., Furumichi, M., and Tanabe, M.; KEGG for integration and interpretation of large-scale molecular datasets. Nucleic Acids Res. 40, D109-D114 (2012)

Author

Page authored by Cassandra Martin, Michelle Meng, Lauren Masek, and Robert Marks, students of Prof. Jay Lennon at Michigan State University.

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