''Trichodesmium'', also called sea sawdust, is a genus of filamentous cyanobacteria. They are found in nutrient poor

tropical The tropics are the regions of Earth surrounding the Equator. They are defined in latitude by the Tropic of Cancer in the Northern Hemisphere at N and the Tropic of Capricorn in the Southern Hemisphere at S. The tropics are also referred to ...

and

subtropical The subtropical zones or subtropics are geographical and climate zones to the north and south of the tropics. Geographically part of the temperate zones of both hemispheres, they cover the middle latitudes from to approximately 35° north and ...

ocean waters (particularly around Australia and in the

Red Sea The Red Sea ( ar, البحر الأحمر - بحر القلزم, translit=Modern: al-Baḥr al-ʾAḥmar, Medieval: Baḥr al-Qulzum; or ; Coptic: ⲫⲓⲟⲙ ⲛ̀ϩⲁϩ ''Phiom Enhah'' or ⲫⲓⲟⲙ ⲛ̀ϣⲁⲣⲓ ''Phiom ǹšari''; T ...

, where they were first described by

Captain Cook James Cook (7 November 1728 Old Style date: 27 October – 14 February 1779) was a British explorer, navigator, cartographer, and captain in the British Royal Navy, famous for his three voyages between 1768 and 1779 in the Pacific Ocean and ...

). ''Trichodesmium'' is a

diazotroph Diazotrophs are bacteria and archaea that fix gaseous nitrogen in the atmosphere into a more usable form such as ammonia. A diazotroph is a microorganism that is able to grow without external sources of fixed nitrogen. Examples of organisms that d ...

; that is, it fixes atmospheric nitrogen into ammonium, a nutrient used by other organisms. ''Trichodesmium'' is thought to fix nitrogen on such a scale that it accounts for almost half of the nitrogen fixation in marine systems globally. ''Trichodesmium'' is the only known

able to fix nitrogen in daylight under aerobic conditions without the use of

heterocysts Heterocysts or heterocytes are specialized nitrogen-fixing cells formed during nitrogen starvation by some filamentous cyanobacteria, such as '' Nostoc punctiforme'', ''Cylindrospermum stagnale'', and ''Anabaena sphaerica''. They fix nitrogen fr ...

. ''Trichodesmium'' can live as individual filaments, with tens to hundreds of cells strung together, or in colonies consisting of tens to hundreds of filaments clustered together. These colonies are visible to the naked eye and sometimes form blooms, which can be extensive on surface waters. These large blooms led to widespread recognition as "sea sawdust/straw"; in fact, the

gets most of its eponymous colouration from the corresponding pigment in '' Trichodesmium erythraeum''. Colonies of ''Trichodesmium'' provide a pseudobenthic substrate for many small oceanic organisms including bacteria,

diatoms A diatom ( Neo-Latin ''diatoma''), "a cutting through, a severance", from el, διάτομος, diátomos, "cut in half, divided equally" from el, διατέμνω, diatémno, "to cut in twain". is any member of a large group comprising se ...

dinoflagellates The dinoflagellates (Greek δῖνος ''dinos'' "whirling" and Latin ''flagellum'' "whip, scourge") are a monophyletic group of single-celled eukaryotes constituting the phylum Dinoflagellata and are usually considered algae. Dinoflagellates are ...

protozoa Protozoa (singular: protozoan or protozoon; alternative plural: protozoans) are a group of single-celled eukaryotes, either free-living or parasitic, that feed on organic matter such as other microorganisms or organic tissues and debris. Histo ...

, and

copepods Copepods (; meaning "oar-feet") are a group of small crustaceans found in nearly every freshwater and saltwater habitat. Some species are planktonic (inhabiting sea waters), some are benthic (living on the ocean floor), a number of species have p ...

(which are its primary predator); in this way, the genus can support complex microenvironments.

Species

'' Trichodesmium erythraeum'' – described by Ehrenberg in 1830. ''T. erythraeum'' is the species responsible for discoloring the

during blooms. This is the only sequenced genome in the genus thus far and is the focus of most laboratory studies (''Trichodesmium'' IMS 101). '' Trichodesmium thiebautii'' – Described by Gomont in 1892. '' Trichodesmium hildebrantii'' – Described by Gomont in 1892. '' Trichodesmium contortum'' – Described by Wille in 1904. '' Trichodesmium tenue'' – Described by Wille in 1904. '' Trichodesmium radians'' – Described by Wille in 1904.

Cell structure

Like most cyanobacteria, ''Trichodesmium'' has a

gram negative cell wall The gram (originally gramme; SI unit symbol g) is a unit of mass in the International System of Units (SI) equal to one one thousandth of a kilogram. Originally defined as of 1795 as "the absolute weight of a volume of pure water equal to th ...

. However, unlike other aerobic

diazotrophs Diazotrophs are bacteria and archaea that fix gaseous nitrogen in the atmosphere into a more usable form such as ammonia. A diazotroph is a microorganism that is able to grow without external sources of fixed nitrogen. Examples of organisms that ...

heterocyst Heterocysts or heterocytes are specialized nitrogen-fixing cells formed during nitrogen starvation by some filamentous cyanobacteria, such as '' Nostoc punctiforme'', '' Cylindrospermum stagnale'', and ''Anabaena sphaerica''. They fix nitrogen f ...

s (structures found in cyanobacteria which protect nitrogenase from oxygenation) are lacking in ''Trichodesmium''. This is a unique characteristic among aerobic diazotrophs which fix nitrogen in daylight. Photosynthesis occurs using

phycoerythrin Phycoerythrin (PE) is a red protein-pigment complex from the light-harvesting phycobiliprotein family, present in cyanobacteria, red algae and cryptophytes, accessory to the main chlorophyll pigments responsible for photosynthesis.The red pigment ...

- light-harvesting

phycobiliprotein Phycobiliproteins are water-soluble proteins present in cyanobacteria and certain algae ( rhodophytes, cryptomonads, glaucocystophytes). They capture light energy, which is then passed on to chlorophylls during photosynthesis. Phycobiliproteins ar ...

which is normally found within heterocysts in other diazotrophs. Instead of having localized stacks of

thylakoid Thylakoids are membrane-bound compartments inside chloroplasts and cyanobacteria. They are the site of the light-dependent reactions of photosynthesis. Thylakoids consist of a thylakoid membrane surrounding a thylakoid lumen. Chloroplast thyl ...

s, ''Trichodesmium'' has unstacked thylakoids found throughout the cell. ''Trichodesmium'' is highly vacuolated and the content and size of the vacuoles shows diurnal variation. Large gas vesicles (either along the periphery as seen in ''T. erythaeum'' or found distributed throughout the cell as seen in ''T. thiebautii'') allow ''Trichodesmium'' to regulate buoyancy in the water column. These gas vesicles can withstand high pressure, presumably those up to 100 – 200 m in the water column, allowing ''Trichodesmium'' to move vertically through the water column harvesting nutrients.

Nitrogen-fixation

N₂ is the most abundant chemical in the atmosphere. However, diatomic nitrogen is not usable for most biological processes.

Nitrogen fixation Nitrogen fixation is a chemical process by which molecular nitrogen (), with a strong triple covalent bond, in the air is converted into ammonia () or related nitrogenous compounds, typically in soil or aquatic systems but also in industry. A ...

is the process of converting atmospheric diatomic nitrogen into biologically usable forms of nitrogen such as ammonium and

nitrogen oxides Nitrogen oxide may refer to a binary compound of oxygen and nitrogen, or a mixture of such compounds: Charge-neutral *Nitric oxide (NO), nitrogen(II) oxide, or nitrogen monoxide *Nitrogen dioxide (), nitrogen(IV) oxide *Nitrogen trioxide (), or ni ...

. This process requires a substantial amount of energy (in the form of ATP) in order to break the triple bond between the nitrogen atoms. ''Trichodesmium'' is the major

in marine pelagic systems and is an important source of "new" nitrogen in the nutrient poor waters it inhabits. It has been estimated that the global input of nitrogen fixation by ''Trichodesmium'' is approximately 60-80 Tg (megatonnes or 10¹² grams) N per year. Nitrogen fixation in ''Trichodesmium'' is unique among diazotrophs because the process occurs concurrently with oxygen production (via photosynthesis). In other cyanobacteria, N₂ and CO₂ reduction are separated either in space (using heterocysts to protect the sensitive

nitrogenase Nitrogenases are enzymes () that are produced by certain bacteria, such as cyanobacteria (blue-green bacteria) and rhizobacteria. These enzymes are responsible for the reduction of nitrogen (N2) to ammonia (NH3). Nitrogenases are the only fa ...

enzyme from oxygen) or time. However, ''Trichodesmium'' lacks heterocysts and nitrogen fixation peaks during daylight hours (following a diel flux initiated in the morning, reaching a maximum fixation rate midday, and ceasing activity at night). Since the first realization of this enigma, ''Trichodesmium'' has been the focus of many studies to try and discover how nitrogen fixation is able to occur in the presence of oxygen production without any apparent structure separating the two processes. Inhibitor studies even revealed that

photosystem II Photosystem II (or water-plastoquinone oxidoreductase) is the first protein complex in the light-dependent reactions of oxygenic photosynthesis. It is located in the thylakoid membrane of plants, algae, and cyanobacteria. Within the photosystem ...

activity is essential for nitrogen fixation in this organism. All this may seem contradictory at first glance, because the enzyme responsible for nitrogen fixation,

, is irreversibly inhibited by oxygen. However, ''Trichodesmium'' utilises

photosynthesis Photosynthesis is a process used by plants and other organisms to convert light energy into chemical energy that, through cellular respiration, can later be released to fuel the organism's activities. Some of this chemical energy is stored in ...

for nitrogen fixation by carrying out the

Mehler reaction The Mehler reaction is named after Alan H. Mehler, who, in 1951, presented data to the effect that isolated chloroplasts reduce oxygen to form hydrogen peroxide (). Mehler observed that the formed in this way does not present an active intermediat ...

, during which the oxygen produced by PSII is reduced again after PSI. This regulation of photosynthesis for nitrogen fixation involves rapidly reversible coupling of their light-harvesting antenna, the

phycobilisome Phycobilisomes are light harvesting antennae of photosystem II in cyanobacteria, red algae and glaucophytes. It was lost in the plastids of green algae / plants ( chloroplasts). General structure Phycobilisomes are protein complexes (up to ...

s, with PSI and PSII.

Ecology

Trichodesmium colonies sorted into the morphological classes

Trichodesmium interact with bacteria to acquire iron from dust

''Trichodesmium'' is found in oligotrophic waters, often when waters are calm and the mixed layer depth is shallow (around 100 m). ''Trichodesmium'' is found primarily in water between 20 and 34 °C and is frequently encountered in tropical and sub-tropical oceans in western boundary currents. Its presence is more pronounced in nitrogen poor water and can easily be seen when blooms form, trapping large ''Trichodesmium'' colonies at the surface. As a

, ''Trichodesmium'' contributes a large portion of the marine ecosystem’s new nitrogen, estimated to produce between 60 and 80 Tg of nitrogen per year. Nitrogen fixed by ''Trichodesmium'' can either be used directly by the cell, enter the food chain through grazers, be released into dissolved pools, or get exported to the deep sea. Compared to eukaryotic phytoplankton, ''Trichodesmium'' has a slow growth rate, which has been hypothesized to be an adaptation to survival in high energy but low nutrient conditions of oligotrophic waters. Growth rate is limited by iron and phosphate concentrations in the water. In order to obtain these limiting nutrients, ''Trichodesmium'' is able to regulate buoyancy using its gas vacuole and move vertically throughout the water column, harvesting nutrients.

Colonies

Various species of ''Trichodesmium'' have been described based on morphology and structure of colonies formed. Colonies may consist of aggregates of several to several hundred trichomes and form fusiform (called "Tufts") colonies when aligned in parallel, or spherical (called "Puffs") colonies when aligned radially. ''Trichodesmium'' colonies have been shown to have large degree of associations with other organisms, including bacteria, fungi, diatoms, copepods, tunicates, hydrozoans, and protozoans among other groups. These colonies may provide a source of shelter, buoyancy, and possibly food in the surface waters. Most of these associations appear to be commensal, with the ''Trichodesmium'' providing substrate and nutrition while deriving no obvious benefit from the organisms dwelling within the colonies.

Blooms

''Trichodesmium'' forms large, visible blooms in the surface waters. Blooms have been described in the Baltic Sea, the Red Sea, the Caribbean Sea, the Indian Ocean, the North and South Atlantic and the North Pacific, and off the coast of Australia. One of the earliest blooms was described by E. Dupont in the Red Sea, noticed for turning the surface of the water a reddish color. This bloom was said to extend about 256 nautical miles. Most blooms are several kilometers long and last one to several months. Blooms can form in coastal or oceanic waters, most frequently when the water has been still for some time and surface temperatures exceed 27 °C. ''Trichodesmium'' blooms release carbon, nitrogen and other nutrients into the environment. Some species of ''Trichodesmium'' have been shown to release toxins which cause mortalities in some copepods, fish, and oysters. Blooms have also been credited with releasing the toxin which causes clupeotoxism in humans after ingesting fish which have bioaccumulated the toxin during ''Trichodesmium'' blooms. The larger impact of these blooms is likely important to the oceanic ecosystem and is the source of many studies. Blooms are traced and tracked using satellite imaging where the highly reflective gas vacuole makes ''Trichodesmium'' blooms easily detectable. It is expected that blooms may increase due to anthropogenic effects in the coming years. Phosphate loading of the environment (through fertilizer pollution, waste disposal, and mariculture) will reduce the growth constraints associated with limited phosphate and likely increase bloom occurrences. Likewise, global warming is projected to increase stratification and cause a shallowing of the mixed layer depth. Both of these factors are associated with ''Trichodesmium'' blooms and may also cause an increase in the occurrence of blooms in the future.

References

Bibliography

* Kana, T.M. (1993) Rapid oxygen cycling in ''Trichodesmium thiebautii''. ''Limnology and Oceanography'' 38: 18–24. * Berman-Frank, I., Lundgren, P., Chen, Y.-B., Küpper, H., Kolber, Z., Bergman, B., and Falkowski, P. (2001) Segregation of nitrogen fixation and oxygenic photosynthesis in the marine cyanobacterium ''Trichodesmium''. ''Science'' 294: 1534–1537. * Küpper, H., Ferimazova, N., Šetlík, I., and Berman-Frank, I. (2004) Traffic lights in ''Trichodesmium'': regulation of photosynthesis for nitrogen fixation studied by chlorophyll fluorescence kinetic microscopy. ''Plant Physiology'' 135: 2120–2133. * Capone, D.G., Zehr, J., Paerl, H., Bergman, B., and Carpenter, E.J. (1997) ''Trichodesmium'': A globally significant marine cyanobacterium. ''Science'' 276: 1221–1229.

External links

Publications on ''Trichodesmium'' from a Marine Biogeochemistry laboratory at the University of Southern CaliforniaCharles Darwin's description of sailing through a ''Trichodesmium'' bloomTrichodesmium in Florida — 2004
Florida Fish and Wildlife Conservation Commissio
Fish and Wildlife Research Institute
{{Taxonbar, from=Q7840756 Cyanobacteria genera Oscillatoriales