Autotroph Explained

See also: Primary production.

An autotroph is an organism that can convert abiotic sources of energy into energy stored in organic compounds, which can be used by other organisms. Autotrophs produce complex organic compounds (such as carbohydrates, fats, and proteins) using carbon from simple substances such as carbon dioxide,[1] generally using energy from light or inorganic chemical reactions.[2] Autotrophs do not need a living source of carbon or energy and are the producers in a food chain, such as plants on land or algae in water. Autotrophs can reduce carbon dioxide to make organic compounds for biosynthesis and as stored chemical fuel. Most autotrophs use water as the reducing agent, but some can use other hydrogen compounds such as hydrogen sulfide.

The primary producers can convert the energy in the light (phototroph and photoautotroph) or the energy in inorganic chemical compounds (chemotrophs or chemolithotrophs) to build organic molecules, which is usually accumulated in the form of biomass and will be used as carbon and energy source by other organisms (e.g. heterotrophs and mixotrophs). The photoautotrophs are the main primary producers, converting the energy of the light into chemical energy through photosynthesis, ultimately building organic molecules from carbon dioxide, an inorganic carbon source.[3] Examples of chemolithotrophs are some archaea and bacteria (unicellular organisms) that produce biomass from the oxidation of inorganic chemical compounds, these organisms are called chemoautotrophs, and are frequently found in hydrothermal vents in the deep ocean. Primary producers are at the lowest trophic level, and are the reasons why Earth sustains life to this day.[4]

Most chemoautotrophs are lithotrophs, using inorganic electron donors such as hydrogen sulfide, hydrogen gas, elemental sulfur, ammonium and ferrous oxide as reducing agents and hydrogen sources for biosynthesis and chemical energy release. Autotrophs use a portion of the ATP produced during photosynthesis or the oxidation of chemical compounds to reduce NADP+ to NADPH to form organic compounds.[5]

History

The term autotroph was coined by the German botanist Albert Bernhard Frank in 1892.[6] [7] It stems from the ancient Greek word, meaning "nourishment" or "food". The first autotrophic organisms likely evolved early in the Archean but proliferated across Earth's Great Oxidation Event with an increase to the rate of oxygenic photosynthesis by cyanobacteria.[8] Photoautotrophs evolved from heterotrophic bacteria by developing photosynthesis. The earliest photosynthetic bacteria used hydrogen sulphide. Due to the scarcity of hydrogen sulphide, some photosynthetic bacteria evolved to use water in photosynthesis, leading to cyanobacteria.[9]

Variants

Some organisms rely on organic compounds as a source of carbon, but are able to use light or inorganic compounds as a source of energy. Such organisms are mixotrophs. An organism that obtains carbon from organic compounds but obtains energy from light is called a photoheterotroph, while an organism that obtains carbon from organic compounds and energy from the oxidation of inorganic compounds is termed a chemolithoheterotroph.

Evidence suggests that some fungi may also obtain energy from ionizing radiation: Such radiotrophic fungi were found growing inside a reactor of the Chernobyl nuclear power plant.[10]

Examples

There are many different types of autotrophs in Earth's ecosystems. Lichens located in tundra climates are an exceptional example of a primary producer that, by mutualistic symbiosis, combines photosynthesis by algae (or additionally nitrogen fixation by cyanobacteria) with the protection of a decomposer fungus. Also, plant-like primary producers (trees, algae) use the sun as a form of energy and put it into the air for other organisms. There are of course H2O primary producers, including a form of bacteria, and phytoplankton. As there are many examples of primary producers, two dominant types are coral and one of the many types of brown algae, kelp.

Photosynthesis

Gross primary production occurs by photosynthesis. This is also the main way that primary producers take energy and produce/release it somewhere else. Plants, coral, bacteria, and algae do this. During photosynthesis, primary producers take energy from the sun and convert it into energy, sugar, and oxygen. Primary producers also need the energy to convert this same energy elsewhere, so they get it from nutrients. One type of nutrient is nitrogen.

Ecology

See also: Primary production. Without primary producers, organisms that are capable of producing energy on their own, the biological systems of Earth would be unable to sustain themselves.[3] Plants, along with other primary producers, produce the energy that other living beings consume, and the oxygen that they breathe.[3] It is thought that the first organisms on Earth were primary producers located on the ocean floor.[3]

Autotrophs are fundamental to the food chains of all ecosystems in the world. They take energy from the environment in the form of sunlight or inorganic chemicals and use it to create fuel molecules such as carbohydrates. This mechanism is called primary production. Other organisms, called heterotrophs, take in autotrophs as food to carry out functions necessary for their life. Thus, heterotrophs – all animals, almost all fungi, as well as most bacteria and protozoa – depend on autotrophs, or primary producers, for the raw materials and fuel they need. Heterotrophs obtain energy by breaking down carbohydrates or oxidizing organic molecules (carbohydrates, fats, and proteins) obtained in food. Carnivorous organisms rely on autotrophs indirectly, as the nutrients obtained from their heterotrophic prey come from autotrophs they have consumed.

Most ecosystems are supported by the autotrophic primary production of plants and cyanobacteria that capture photons initially released by the sun. Plants can only use a fraction (approximately 1%) of this energy for photosynthesis.[11] The process of photosynthesis splits a water molecule (H2O), releasing oxygen (O2) into the atmosphere, and reducing carbon dioxide (CO2) to release the hydrogen atoms that fuel the metabolic process of primary production. Plants convert and store the energy of the photon into the chemical bonds of simple sugars during photosynthesis. These plant sugars are polymerized for storage as long-chain carbohydrates, including other sugars, starch, and cellulose; glucose is also used to make fats and proteins. When autotrophs are eaten by heterotrophs, i.e., consumers such as animals, the carbohydrates, fats, and proteins contained in them become energy sources for the heterotrophs.[12] Proteins can be made using nitrates, sulfates, and phosphates in the soil.[13] [14]

Primary production in tropical streams and rivers

Aquatic algae are a significant contributor to food webs in tropical rivers and streams. This is displayed by net primary production, a fundamental ecological process that reflects the amount of carbon that is synthesized within an ecosystem. This carbon ultimately becomes available to consumers. Net primary production displays that the rates of in-stream primary production in tropical regions are at least an order of magnitude greater than in similar temperate systems.[15]

Origin of autotrophs

Researchers believe that the first cellular lifeforms were not heterotrophs as they would rely upon autotrophs since organic substrates that were delivered from space was either too heterogeneous to support microbial growth or too reduced to be fermented. Instead, they consider that the first cells were autotrophs.[16] These autotrophs might have been thermophilic and anaerobic chemolithoautotrophs that lived at deep sea alkaline hydrothermal vents. Catalytic Fe(Ni)S minerals at these environments are shown to catalyze biomolecules like RNA.[17] This view is supported by phylogenetic evidence as the physiology and habitat of the last universal common ancestor (LUCA) was inferred to have also been a thermophilic anaerobe with a Wood-Ljungdahl pathway, its biochemistry was replete with FeS clusters and radical reaction mechanisms, and was dependent upon Fe, H2, and CO2.[18] The high concentration of K+ present within the cytosol of most life forms suggest that early cellular life had Na+/H+ antiporters or possibly symporters.[19] Autotrophs possibly evolved into heterotrophs when they were at low H2 partial pressures where the first form of heterotrophy were likely amino acid and clostridial type purine fermentations[20] and photosynthesis emerged in the presence of long-wavelength geothermal light emitted by hydrothermal vents. The first photochemically active pigments are inferred to be Zn-tetrapyrroles.[21]

See also

External links

Notes and References

  1. Morris, J. et al. (2019). "Biology: How Life Works", 3rd edition, W. H. Freeman.
  2. News: Chang . Kenneth . Visions of Life on Mars in Earth's Depths . 12 September 2016 . . 12 September 2016 . 12 September 2016 . https://web.archive.org/web/20160912225220/http://www.nytimes.com/2016/09/13/science/south-african-mine-life-on-mars.html . live .
  3. Web site: What Are Primary Producers?. Sciencing. en. 2018-02-08. 14 October 2019. https://web.archive.org/web/20191014195302/https://sciencing.com/primary-producers-8138961.html. live.
  4. Post. David M. 2002. Using Stable Isotopes to Estimate Trophic Position: Models, Methods, and Assumptions. Ecology. 83. 3. 703–718. 10.1890/0012-9658(2002)083[0703:USITET]2.0.CO;2.
  5. Book: Mauseth, James D. . Botany: an introduction to plant biology . 2014 . Jones & Bartlett Learning . 978-1-4496-6580-7 . 5th . Burlington, MA . 2014 . 266-267 . en . registration.
  6. Book: Frank, Albert Bernard. Lehrbuch der Botanik. 1892–93. W. Engelmann. Leipzig. de. 14 January 2018. 7 March 2023. https://web.archive.org/web/20230307124024/https://www.biodiversitylibrary.org/bibliography/29599#/summary. live.
  7. Web site: What Are Autotrophs? . 11 March 2019 .
  8. Crockford . Peter W. . Bar On . Yinon M. . Ward . Luce M. . Milo . Ron . Halevy . Itay . November 2023 . The geologic history of primary productivity . Current Biology . 33 . 21 . 4741–4750.e5 . 10.1016/j.cub.2023.09.040 . 37827153 . 2023CBio...33E4741C . 263839383 . 0960-9822 . 5 December 2023 . 15 March 2024 . https://web.archive.org/web/20240315091640/https://www.cell.com/current-biology/abstract/S0960-9822(23)01286-1?_returnURL=https%3A%2F%2Flinkinghub.elsevier.com%2Fretrieve%2Fpii%2FS0960982223012861%3Fshowall%3Dtrue . live .
  9. Web site: The Evolution of Autotrophs. Townsend. Rich. 13 October 2019. University of Wisconsin-Madison Department of Astronomy. 3 May 2019. 8 July 2022. https://web.archive.org/web/20220708065825/http://www.astro.wisc.edu/~townsend/static.php?ref=diploma-4#toc-The_Evolution_of_Autotrophs. live.
  10. Web site: Chernobyl fungus feeds on radiation . Melville . Kate . 23 May 2007 . 18 February 2009 . https://web.archive.org/web/20090204184150/http://scienceagogo.com/news/20070422222547data_trunc_sys.shtml . 4 February 2009 . live.
  11. Book: Schurr, Sam H. . Energy, Economic Growth, and the Environment . 19 January 2011 . 9781617260209 . New York . 868970980.
  12. Book: Beckett, Brian S. . Illustrated Human and Social Biology . 1981 . Oxford University Press . 38 . 978-0-19-914065-7 . 16 August 2020 . 15 March 2024 . https://web.archive.org/web/20240315091624/https://books.google.com/books?id=-mYIPXC0gEgC&pg=PA38#v=onepage&q&f=false . live .
  13. Book: Odum, Eugene P. (Eugene Pleasants), 1913-2002.. Fundamentals of ecology. 2005. Thomson Brooks/Cole. Barrett, Gary W.. 0-534-42066-4. 5th. Belmont, CA. 598. 56476957.
  14. Book: Smith, Gilbert M. . A Textbook of General Botany . 2007 . Read Books . 148 . 978-1-4067-7315-6 . 16 August 2020 . 15 March 2024 . https://web.archive.org/web/20240315091638/https://books.google.com/books?id=jmQUgBUaB_wC&pg=PA148 . live .
  15. Book: 10.1016/B978-012088449-0.50004-2 . Primary Production in Tropical Streams and Rivers . Tropical Stream Ecology . 23–42 . 2008 . Davies . Peter M. . Bunn . Stuart E. . Hamilton . Stephen K. . 9780120884490 .
  16. Weiss . Madeline C. . Preiner . Martina . Xavier . Joana C. . Zimorski . Verena . Martin . William F. . 2018-08-16 . The last universal common ancestor between ancient Earth chemistry and the onset of genetics . PLOS Genetics . 14 . 8 . e1007518 . 10.1371/journal.pgen.1007518 . 1553-7390 . 6095482 . 30114187 . free .
  17. Martin . William . Russell . Michael J . 2007-10-29 . On the origin of biochemistry at an alkaline hydrothermal vent . Philosophical Transactions of the Royal Society B: Biological Sciences . 362 . 1486 . 1887–1926 . 10.1098/rstb.2006.1881 . 0962-8436 . 2442388 . 17255002.
  18. Stetter . Karl O . 2006-10-29 . Hyperthermophiles in the history of life . Philosophical Transactions of the Royal Society B: Biological Sciences . 361 . 1474 . 1837–1843 . 10.1098/rstb.2006.1907 . 0962-8436 . 1664684 . 17008222.
  19. Sousa . Filipa L. . Thiergart . Thorsten . Landan . Giddy . Nelson-Sathi . Shijulal . Pereira . Inês A. C. . Allen . John F. . Lane . Nick . Martin . William F. . 2013-07-19 . Early bioenergetic evolution . Philosophical Transactions of the Royal Society B: Biological Sciences . en . 368 . 1622 . 20130088 . 10.1098/rstb.2013.0088 . 0962-8436 . 3685469 . 23754820.
  20. Schönheit . Peter . Buckel . Wolfgang . Martin . William F. . 2016-01-01 . On the Origin of Heterotrophy . Trends in Microbiology . en . 24 . 1 . 12–25 . 10.1016/j.tim.2015.10.003 . 26578093 . 0966-842X . 4 December 2022 . 15 March 2024 . https://web.archive.org/web/20240315091633/https://www.researchgate.net/publication/284132666_On_the_Origin_of_Heterotrophy . live .
  21. Martin . William F . Bryant . Donald A . Beatty . J Thomas . 2017-11-21 . A physiological perspective on the origin and evolution of photosynthesis . FEMS Microbiology Reviews . 42 . 2 . 205–231 . 10.1093/femsre/fux056 . 0168-6445 . 5972617 . 29177446.