Extremotroph: Difference between revisions

Extremotrophs: Organisms Beyond the Ordinary

An extremotroph is an intriguing type of organism that has evolved to thrive on sources of energy and matter that are considered inhospitable or even toxic to the majority of life forms on Earth. Derived from the Latin term extremus

, meaning "extreme", and the Greek word troph

( τροφ

), translating to "food", extremotrophs exhibit a vast array of metabolic and physiological adaptations, allowing them to occupy some of the planet's most challenging environments.

Classification and Ecology

The classification of extremotrophs is largely based on the nature of the matter they utilize for sustenance:

• Chemotrophs: Organisms that obtain energy from chemical reactions, often in the absence of sunlight.
• Lithotrophs: Those which derive energy from inorganic compounds.
• Heterotrophs: Organisms that derive energy from organic compounds.

While the concept of extremotrophy may seem alien to many, it is crucial to note that these definitions are anthropocentric, stemming from human perspectives on what constitutes "normal" or "extreme" conditions for life. As such, the boundary between extremophily and extremotrophy is not always clear-cut. Many extremophiles, for instance, those living deep within the Earth's crust, might be described as extremotrophs due to the unique matter they consume.<ref>Horikoshi, Koki (2010) Extremophiles Handbook, pg. 5</ref>

Adaptations of Extremotrophs

To survive and reproduce in their distinctive environments, extremotrophs have developed a suite of specialized adaptations:

• Enzyme Stability: Enzymes that remain functional at extreme temperatures, pH levels, or salinities.
• Protective Protein Structures: Proteins that maintain their structure and function under harsh conditions.
• Unique Membrane Lipids: Cell membranes composed of specialized lipids that maintain integrity under extreme conditions.

Ecological Significance

Extremotrophs play a vital role in ecosystem functioning, particularly in environments where few other organisms can survive:

• Biogeochemical Cycling: Extremotrophs can contribute to the cycling of essential nutrients in extreme environments.
• Primary Production: In the absence of photosynthetic organisms, certain extremotrophs serve as primary producers by fixing carbon using inorganic sources of energy.

Examples

• Pestalotiopsis microspora: plastic eater<ref>Activist Post: Jungle fungus eats plastic, beats cancer</ref>
• Halomonas titanicae: metal eater<ref>New Bacteria Found on Titanic; Eats Metal</ref>
• Geotrichum candidum: compact disk eater<ref>Fungus eats CD : Nature News</ref>
• Aspergillus fumigatus: printed circuit board eater<ref>Kirksey, Kirk (2005) Computer Factoids: Tales from the High-Tech Underbelly, pg. 74</ref>
• Deinococcus radiodurans: radioactive waste eater
• ?: space debris eaters<ref>Mutant space microbes attack ISS: 'Munch' metal, may crack glass — RT</ref>

Industrial uses

Extremotrophs are used as bioremediation and biodegradation agents.

See also

• Extremophile
• Thermophile
• Acidophile

References

<references />

External links

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