Trichodesmium thiebautii
Classification
Higher order taxa
Bacteria; Cyanobacteria; Cyanophyceae; Oscillatoriales; Microcoleaceae; Trichodesmium
Species
Trichodesmium thiebautii
Description and Significance
M. Gomont was the first scientist to describe and name Trichodesmium thiebautii. He originally isolated the species from the "Atlantic Ocean to the islands of Canada and Guadalupe" (1). He published his findings in 1892, and not many papers have been written about T. thiebautii since (1). T. thiebautii doesn’t have extensive research because it has been so hard to study. Not many scientists have been successful in maintaining live cultures for more than three months (5).
From the short-lived cultures, scientists have been able to learn some information about T. thiebautii. T. thiebautii forms two types of colonies. The two colony shapes are radial and fusiform, with fusiform colonies being the most abundant type. The fusiform colonies are twisted like a rope (4). T. thiebautii has non-constricted trichomes surrounding the outside of its cell. The morphology of trichomes is similar within a colony, but varies between each different, separate colony (4,9).
The T. tiebautii cells themselves are coccus shaped and gram negative (9). They are found in tropical and subtropical oceans, and prefer those warm temperatures (9). T. tiebautii are dangerous because they are a marine cyanobacteria(9). Besides their dangers, they are very important to the ocean because they fix nitrogen. T. thiebautii are non-heterocystous and fix nitrogen gas. It fixes nitrogen gas during the day and night, which is unlike other cyanobacteria (3).
Genome and genetics
T. thiebautii’s genome has been sequenced using whole genome shotgun sequencing. The whole genome shotgun sequence can be found on the National Center for Biotechnology Information website with the following link: https://www.ncbi.nlm.nih.gov/nuccore/LAMW01000047.1. The total length of its genome is about 3.29 Mb with 35.4 %GC (15). It consists of about 39,217 base pairs (13). T. thiebautii has 3,370 genes (14). T. thiebautii have nifH genes, which are incredibly important because they produce nitrogen fixation proteins (nifH) (16).
T. thiebautii belong to the bacteria branch of prokaryotes (6). The genus that Trichodesmium, including T. thiebautii, are most closely related to are Oscillatoria sancta PCC 7515 (6). All of the species within the Trichodesmium genus are closely related. The species that is the most genetically different from T. thiebautii and the others is T. erythraeum. There are two different clades of Trichodesmium species. One clade includes T. thiebautii, along with T. tenue, T. hildebrandtii, and K. spiralis. The other clade only includes T. erythraeum (11).
Nutrition and metabolism
Trichodesmium thiebautii are primary producers, which means that they attain nutrients from inorganic compounds (17). Iron is vital to all Trichodesmium species, including T. thiebautii. Trichodesmium need 10 times as much iron than cyanobacteria that don’t fix nitrogen. Trichodesmium find most, if not all, of their iron in the open ocean from “aeolian-transported” particles (10). O2 is also incredibly important for the growth and function of Trichodesmiums. Although the nitrogenase in natural colonies are sensitive to it, there is an O2 requirement under certain conditions (10). Trichodesmium colonies only take in 15NO3 in the evening or at night. They also only take in 15NH4+ at night. Trichodesmiums prefer to get their nitrogen from urea. Trichodesmium blooms are formed due to different factors, such as “physical stability, high pH, and colony shape” (10). Phosphorus, iron, and physical forcing are believed to limit the growth of Trichodesmiums (17).
The way T. thiebautii divides is by binary fission and in one plane (6). This division is incredibly important, because it allows for more T. thiebautii’s to procue new nitrogen. The most important product of T. thiebautii is new nitrogen. Trichodesmiums produce the largest amount of new nitrogen to the euphotic zone of the ocean (10).
Trichodesmium species are tricky when it comes to culturing them. Many scientists have had trouble growing cultures of any of the Trichodesmium species. Rueter and Annete Hynes have both encountered problems while attempting to culture a Trichodesmium species (4, 8). Others have successfully cultured Trichodesmiums. Scientists have successfully cultured a Trichodesmium from Japan on a modified version of the defined medium “Aquil”. A Trichodesmium species was cultured on a medium with a seawater base in North Carolina (6).
Ecology / Pathology
T. thiebautii is a marine cyanobacteria. It is one of the two most common Trichodesmium species. It has been found in tropical, subtropical, and temperate waters at depths of 450 feet (8, 12). It has the ability to form massive seasonal blooms that expand kilometers of ocean (12).
T. thiebautii is an important part of maintaining a healthy ocean and world because it fixes nitrogen in the ocean. It is a major part of the marine primary production and the global nitrogen cycle (12). This fixed nitrogen is incredibly beneficial to not only the environment, but also other microbes. Scientists believe that the nitrogen produced by Trichodesmium blooms helps initiate the blooms of other bacteria, such as Karenie brevis (2). Most nonheterocystous diazotrophic cyanobacteria only fix nitrogen at certain times, but not T. thiebautii. Every Trichodesmium species can fix nitrogen during the day and night. Their nitrogen fixation and photosynthesis occur at the same time, even though they seem as if they would conflict with each other (6, 18).
Although the nitrogen from T. thiebautii is good, the bacteria species itself has been classified as toxic (12). Trichophycin A, a cytotoxin isolated from a T. thiebautii bloom, has shown cytotoxicity against Neuro-2A murine neuroblastoma cells and HCT-166 human colon cancer cells (2). Another cytotoxin present in T. thiebautii are trichotoxins (12). In several laboratories, T. thiebautii has shown neurotoxic effects, and is known as one of the two toxic Trichodesmium species. The deaths of several marine animals, such as fish, oysters, and crabs have been linked to T. thiebautii. It has also killed different types of copepods and brine shrimp (12). Some scientists claimed to have had “respiratory distress” and “contact dermatitis” when working with T. thiebautii (12). On top of that, hundreds of Brazilians were diagnosed with Tamandare Fever in 1963. They experienced respiratory problems, fevers, muscle pains, and rashes on their chests and arms. The Tamandare Fever was the first and only reported human illness associated with any Trichodesmium species (12).
Current Research
Trichodesmium thiebautii is classified as toxic (12). The most current research being conducted on T. thiebautii is to identify the toxins that it produces. By understanding its toxins, we can better understand the bacteria itself and how it interacts with other living organisms. Scientists have isolated the cytotoxin, Trichophycin A, from a T. thiebautii bloom. They have compared it to other toxins that T. thiebautii produces, such as Trichotoxin A and Trichotoxin B. It has been tested against different types of cells, like Neuro-2A murine neuroblastoma cells and HCT-166 human colon cancer cells. It has shown to have a cytotoxic effect on all of them (2).
References
1. Bergman, B., Carpenter, E. J., Larsson, J., Lin, S., Sandh, G. “Trichodesmium – a widespread marine cyanobacterium with unusual nitrogen fixation properties”. FEMS Microbial Rev. 2013 May; 37(3): 286-302 [PubMed] 2. Bertin, Matthew J., Paul G. Wahome, Paul V. Zimba, Haiyin He, and Peter D. R. Moeller. "Trichophycin A, a Cytotoxic Linear Polyketide Isolated from a Trichodesmium thiebautii Bloom." Marine Drugs 15, no. 1 (January 6, 2017). Accessed March 29, 2017. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5295230/. 3. Capone, D. G., Ferrier, M. D., Carpenter, E. J. “Amino Acid Cycling in Colonies of the Planktonic Marine Cyanobacterium Trichodesmium thiebautii”. Applied and Environmental Microbiology, Nov. 1994, p. 3989-3995. 4. Carpenter, E. J., and D. G. Capone, eds. Marine Pelagic Cyanobacteria: Trichodesmium and other Diazotrophs. Vol. 362. C: Mathematical and Physical Sciences. Bamberg, Germany: NATO Advanced Research Workshop, 1991. Accessed March 29, 2017. https://books.google.com/books?id=CXnoCAAAQBAJ&pg=PA305&lpg=PA305&dq=Trichodesmium theibautii&source=bl&ots=qsD8M26_P6&sig=aPaTRRa_k2sqvIXa_wvh7WhT66o&hl=en&sa=X&ved=0ahUKEwjw-d3CtYbSAhVY6GMKHeb8BdgQ6AEIKTAD#v=onepage&q=Trichodesmium%20theibautii&f=false. 5. Carpenter, E. J., McCarthy, J. J., Rueter, J. G. 1979. “The toxic effect of copper on Oscillatoria (Trichodesmium) theibautii”. Limnol. Oceanogr., 24(3):558-562. 6. Garrity, George M., David R. Boone, and Richard W. Castenholz, eds. Bergey's Manual of Systematic Bacteriology. 2nd ed. Vol. 1. The Archaea and the Deeply Branching and Phototrophic Bacteria. New York, NY: Springer , 2001. pages 560-561 7. Hewson, Ian, Rachel S. Poretsky, Sonya T. Dyhrman, Brian Zielinski, Angelicque E. White, H. James Tripp, Joseph P. Montoya, and Jonathon P. Zehr. "Microbial community gene expression within colonies of the diazotroph, Trichodesmium, from the Southwest Pacific Ocean." The ISME Journal 3 (July 2, 2009): 1286-300. Accessed March 29, 2017. http://www.nature.com/ismej/journal/v3/n11/full/ismej200975a.html#bib8. 8. Hynes, Annette. "A Most Ingenious Paradoxical Plankton: How do similar organisms co-exist in the same ecological niche?" Oceanus Magazine, November 25, 2008. Accessed March 29, 2017. http://www.whoi.edu/oceanus/feature/a-most-ingenious-paradoxical-plankton. 9. Monteiro, J., Leca, E., Koening, M., Macedo, S. “New record of Trichodesmium thiebautii Gomont ex Gomont (Oscillatoriales – Cyanophyta) for the continental shelf of northeastern Brazil”. Acta Bot. Bras. vol.24 no.4 Feira de Santana Oct./Dec. 2010 10. Okafor, Nduka. Environmental Microbiology of Aquatic and Waste Systems. Springer Science Business Media, 2011. 2011. Accessed March 29, 2017. https://books.google.com/books?id=wrs2oc-wdpAC&pg=PA146&lpg=PA146&dq=Trichodesmium wastes&source=bl&ots=-QVvGJCOn-&sig=skW4WgV3o5DysqM5EjUQJ6IqUgw&hl=en&sa=X&ved=0ahUKEwjV_IejnP3SAhVmwFQKHf7jBzYQ6AEIODAH#v=onepage&q=Trichodesmium%20wastes&f=false. 11. Orcutt, K. M., U. Rasmussen, E. A. Webb, J. B. Waterbury, K. Gundersen, and B. Bergman. "Characterization of Trichodesmium spp. by Genetic Techniques." Applied and Environmental Microbiology 68, no. 5 (May 2002). Accessed March 29, 2017. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC127538/. 12. Schock, Tracey B., Kevin Huncik, Kevin R. Beauchesne, Tracey A. Villareal, and Peter D. R. Moeller. "Identification of Trichotoxin, a Novel Chlorinated Compound Associated with the Bloom Forming Cyanobacterium, Trichodesmium thiebautii." Environmental Science & Technology 45, no. 17 (July 8, 2011). Accessed March 29, 2017. http://pubs.acs.org/doi/full/10.1021/es201034r. 13. "Trichodesmium thiebautii H9-4 contig47, whole genome shotgun sequence." National Center for Biotechnology Information. May 1, 2015. Accessed March 29, 2017. https://www.ncbi.nlm.nih.gov/nuccore/LAMW01000047.1. 14. "Trichodesmium thiebautii H9-4." Joint Genome Institute. Accessed March 29, 2017. https://img.jgi.doe.gov/cgi-bin/m/main.cgi?section=TaxonDetail&page=taxonDetail&taxon_oid=2627854162#statistics. Facts about the genome of T. thiebautii 15. "Trichodesmium thiebautii." National Center for Biotechnology Information. Accessed March 29, 2017. https://www.ncbi.nlm.nih.gov/genome/?term=trichodesmium thiebautii. Facts about the T. thiebautii genome 16. "T.thiebautii nitrogen fixation protein (nifH) gene, partial cds." National Center for Biotechnology Information. April 26, 1993. Accessed March 29, 2017. https://www.ncbi.nlm.nih.gov/nuccore/M29709.1. 17. Webb, Eric A., Rachel Wisniewski Jakuba, James W. Moffett, and Sonya T. Dyhrman. "Molecular assessment of phosphorus and iron physiology in Trichodesmium populations from the western Central and western South Atlantic." Limnol. Oceanogr. 52, no. 5 (2007). Accessed March 29, 2017. http://onlinelibrary.wiley.com/store/10.4319/lo.2007.52.5.2221/asset/lno20075252221.pdf?v=1&t=j0vpsxbp&s=9cf9e351c60683ce9a00cf4948080ed85292fac2. 18. Wyman, Michael, Jonathan P. Zehr, and Douglas G. Capone. " Temporal Variability in Nitrogenase Gene Expression in Natural Populations of the Marine Cyanobacterium Trichodesmium thiebautii." Applied and Environmental Microbiology 62, no. 3 (March 1996): 1073-075. Accessed March 29, 2017. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC1388815/pdf/hw1073.pdf.
Authored by Lily Harter, a student of CJ Funk at John Brown University.