Phytoplankton

Phytoplankton (English pronunciation: /ˌfaɪtoʊˈplæŋktən/) are the autotrophic component of the plankton community. The name comes from the Greek words φυτόν (phyton), meaning "plant", and πλαγκτός (planktos), meaning "wanderer" or "drifter".[1] Most phytoplankton are too small to be individually seen with the unaided eye. However, when present in high enough numbers, they may appear as a green discoloration of the water due to the presence of chlorophyll within their cells (although the actual color may vary with the species of phytoplankton present due to varying levels of chlorophyll or the presence of accessory pigments such as phycobiliproteins, xanthophylls, etc.).

Contents

Ecology

Phytoplankton are photosynthesizing microscopic organisms that inhabit the upper sunlit layer of almost all oceans and bodies of fresh water. They are agents for "primary production," the creation of organic compounds from carbon dioxide dissolved in the water, a process that sustains the aquatic food web.[2] Phytoplankton obtain energy through the process of photosynthesis and must therefore live in the well-lit surface layer (termed the euphotic zone) of an ocean, sea, lake, or other body of water. Phytoplankton account for half of all photosynthetic activity on Earth.[3] Thus phytoplankton are responsible for much of the oxygen present in the Earth's atmosphere – half of the total amount produced by all plant life.[4] Their cumulative energy fixation in carbon compounds (primary production) is the basis for the vast majority of oceanic and also many freshwater food webs (chemosynthesis is a notable exception). The effects of anthropogenic warming on the global population of phytoplankton is an area of active research. Changes in the vertical stratification of the water column, the rate of temperature-dependent biological reactions, and the atmospheric supply of nutrients are not expected to have important effects on future phytoplankton productivity.[5][6] Additionally, changes in the mortality of phytoplankton due to rates of zooplankton grazing may be significant. As a side note, one of the more remarkable food chains in the ocean – remarkable because of the small number of links – is that of phytoplankton-feeding krill (a crustacean similar to a tiny shrimp) feeding baleen whales.

Phytoplankton are also crucially dependent on minerals. These are primarily macronutrients such as nitrate, phosphate or silicic acid, whose availability is governed by the balance between the so-called biological pump and upwelling of deep, nutrient-rich waters. However, across large regions of the World Ocean such as the Southern Ocean, phytoplankton are also limited by the lack of the micronutrient iron. This has led to some scientists advocating iron fertilization as a means to counteract the accumulation of human-produced carbon dioxide (CO2) in the atmosphere.[7] Large-scale experiments have added iron (usually as salts such as iron sulphate) to the oceans to promote phytoplankton growth and draw atmospheric CO2 into the ocean. However, controversy about manipulating the ecosystem and the efficiency of iron fertilization has slowed such experiments.[8]

While almost all phytoplankton species are obligate photoautotrophs, there are some that are mixotrophic and other, non-pigmented species that are actually heterotrophic (the latter are often viewed as zooplankton). Of these, the best known are dinoflagellate genera such as Noctiluca and Dinophysis, that obtain organic carbon by ingesting other organisms or detrital material.

The term phytoplankton encompasses all photoautotrophic microorganisms in aquatic food webs. Phytoplankton serve as the base of the aquatic food web, providing an essential ecological function for all aquatic life. However, unlike terrestrial communities, where most autotrophs are plants, phytoplankton are a diverse group, incorporating protistan eukaryotes and both eubacterial and archaebacterial prokaryotes. There are about 5,000 known species of marine phytoplankton.[9] There is uncertainty in how such diversity has evolved in an environment where competition for only a few resources would suggest limited potential for niche differentiation.[10]

In terms of numbers, the most important groups of phytoplankton include the diatoms, cyanobacteria and dinoflagellates, although many other groups of algae are represented. One group, the coccolithophorids, is responsible (in part) for the release of significant amounts of dimethyl sulfide (DMS) into the atmosphere. DMS is converted to sulfate and these sulfate molecules act as cloud condensation nuclei, increasing general cloud cover. In oligotrophic oceanic regions such as the Sargasso Sea or the South Pacific Gyre, phytoplankton is dominated by the small sized cells, called picoplankton, mostly composed of cyanobacteria (Prochlorococcus, Synechococcus) and picoeucaryotes such as Micromonas.

Environmental threats

A 2010 study published in Nature found that marine phytoplankton have declined substantially in the world's oceans over the past century. Since 1950 alone, phytoplankton concentrations in surface waters were reported to have decreased by about 40%, possibly in response to ocean warming.[11][12] The study generated debate among scientists and led to several communications, also published in Nature.[13][14][15][16] This study has not yet been substantiated.

Aquaculture

Phytoplankton are a key food item in both aquaculture and mariculture. Both utilize phytoplankton as food for the animals being farmed. In mariculture, the phytoplankton is naturally occurring and is introduced into enclosures with the normal circulation of seawater. In aquaculture, phytoplankton must be obtained and introduced directly. The plankton can either be collected from a body of water or cultured, though the former method is seldom used. Phytoplankton is used as a foodstock for the production of rotifers,[17] which are in turn used to feed other organisms. Phytoplankton is also used to feed many varieties of aquacultured molluscs, including pearl oysters and giant clams.

The production of phytoplankton under artificial conditions is itself a form of aquaculture. Phytoplankton is cultured for a variety of purposes, including foodstock for other aquacultured organisms,[17] a nutritional supplement for captive invertebrates in aquaria. Culture sizes range from small-scale laboratory cultures of less than 1L to several tens of thousands of liters for commercial aquaculture.[17] Regardless of the size of the culture, certain conditions must be provided for efficient growth of plankton. The majority of cultured plankton is marine, and seawater of a specific gravity of 1.010 to 1.026 may be used as a culture medium. This water must be sterilized, usually by either high temperatures in an autoclave or by exposure to ultraviolet radiation, to prevent biological contamination of the culture. Various fertilizers are added to the culture medium to facilitate the growth of plankton. A culture must be aerated or agitated in some way to keep plankton suspended, as well as to provide dissolved carbon dioxide for photosynthesis. In addition to constant aeration, most cultures are manually mixed or stirred on a regular basis. Light must be provided for the growth of phytoplankton. The colour temperature of illumination should be approximately 6,500 K, but values from 4,000 K to upwards of 20,000 K have been used successfully. The duration of light exposure should be approximately 16 hours daily; this is the most efficient artificial day length.[17]

See also

References

  1. ^ Thurman, H. V. (2007). Introductory Oceanography. Academic Internet Publishers. ISBN 9781428833142. 
  2. ^ Ghosal; Rogers; Wray, S.; M.; A.. "The Effects of Turbulence on Phytoplankton". Aerospace Technology Enterprise. NTRS. http://ntrs.nasa.gov/search.jsp?R=20040171754&qs=Ntx%3Dmode%2520matchany%26Ntk%3DTitle%26Ns%3DLoaded-Date. Retrieved 2011-06-16. 
  3. ^ "NASA Satellite Detects Red Glow to Map Global Ocean Plant Health" NASA, 28 May 2009.
  4. ^ "Satellite Sees Ocean Plants Increase, Coasts Greening". NASA. 2 March 2005. http://earthobservatory.nasa.gov/Newsroom/NasaNews/2005/2005030218443.html. Retrieved 12 January 2009. 
  5. ^ Henson, SA.et al.; Sarmiento, J. L.; Dunne, J. P.; Bopp, L.; Lima, I.; Doney, S. C.; John, J.; Beaulieu, C. (2010). "Detection of anthropogenic climate change in satellite records of ocean chlorophyll and productivity". Biogeosciences 7(2) (2): 621–640. doi:10.5194/bg-7-621-2010. 
  6. ^ Steinacher et al. (2010). "Projected 21st century decrease in marine productivity: a multi-model analysis". Biogeosciences 7(3): 979–1005. 
  7. ^ Richtel, M. (May 1, 2007). "Recruiting Plankton to Fight Global Warming". New York Times. http://www.nytimes.com/2007/05/01/business/01plankton.html?ref=science 
  8. ^ See: Monastersky, R.: "Iron versus the greenhouse." Science News, 30 September 1995, p. 220.
  9. ^ Hallegraeff, G.M. (2003). Harmful algal blooms: a global overview. in Hallegraeff, G.M., Andewrson, D.M. and Cembella, A.D. (eds) 2003. Manual on Harmful Marine Microalgae. UNESCO, Paris
  10. ^ G.E. Hutchinson (1961). "The paradox of the plankton". Am. Nat. 95 (882): 137–145. doi:10.1086/282171. 
  11. ^ Boyce, D., Lewis, M. & Worm, B. (2010) "Global phytoplankton decline over the past century" Nature, 466: 591–596.
  12. ^ "Ocean greenery under warming stress" Nature News, 28 July 2010. doi:10.1038/news.2010.379
  13. ^ Mackas D. L. (2011) Does blending of chlorophyll data bias temporal trend? Nature, 472: E4–E5. doi:10.1038/nature09951
  14. ^ Rykaczewski, R. R.; and J. P. Dunne (2011) "A measured look at ocean chlorophyll trends" Nature, 472: E5–E6. doi:10.1038/nature09952
  15. ^ A. McQuatters-Gollop et al. Is there a decline in marine phytoplankton? Nature 472, 10.1038/nature09950
  16. ^ Boyce, D.G. et al. Boyce et al. reply Nature 472, 10.1038/nature09952
  17. ^ a b c d McVey, James P., Nai-Hsien Chao, and Cheng-Sheng Lee. CRC Handbook of Mariculture Vol. 1 : Crustacean Aquaculture. New York: C R C P LLC, 1993.

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