Echinamoeba thermarum is an extremely thermophilic amoeba species discovered in various hot springs worldwide. It is notable for its ability to thrive at high temperatures, with an optimal growth temperature of 50°C (122°F).
Echinamoeba thermarum | |
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Scientific classification | |
Domain: | Eukaryota |
Phylum: | Amoebozoa |
Class: | Tubulinea |
Order: | Echinamoebida |
Family: | Echinamoebidae |
Genus: | Echinamoeba |
Species: | E. thermarum
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Binomial name | |
Echinamoeba thermarum Baumgartner et al. 2003
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Taxonomy
editE. thermarum is classified within the genus Echinamoeba based on morphology and SSU rRNA comparisons.[1] Its species name, "thermarum," refers to its highly thermophilic lifestyle and hydrothermal habitat.
The phylogenetic analysis places Echinamoebida as a clade of thermophilic amoebae within Lobosa (Amoebozoa).[2]
Habitat and distribution
editE. thermarum was isolated from hot springs in multiple locations,[1] including:
- Agnano Terme, Italy
- Yellowstone National Park, USA
- Kamchatka, Russia
- Arenal Volcano, Costa Rica
Additional locations have been identified by other researchers:
- Black Canyon geothermal springs of the Colorado River, USA[3]
- Geothermal springs of Taupō Volcanic Zone, New Zealand[2]
- Karymsky Volcano and Valley of Geysers, Russia[2]
The species has adapted to live in hydrothermal environments with temperatures ranging from 33°C (91.4°F) to 57°C (134.6°F).[1]
Morphology and characteristics
editE. thermarum morphological features are as follows:[1]
- Flat cells with irregular triangular or elongated shapes
- Fine spine-like sub pseudopodia
- Average size: 22 μm long and 11 μm wide
- Single nucleus with a central nucleolus
The amoeba can be cultured monoxenically on a thermophilic alpha-proteobacterium.
Evolution and adaptation
editE. thermarum as an example of adaptation to extreme environments[2] suggests that the evolution of thermophily in amoebae has occurred across multiple distantly related lineages, indicating that the amoeboid form may be particularly well-suited for high-temperature environments.
E. thermarum and other thermophilic amoebae can provide insights into: adaptations enabling survival in hot conditions. The relationship between morphological form and thermophilic lifestyle. Functional contributions of thermophilic amoebae to extreme environment ecology.
Life Cycle Stages
editThe life cycle of Echinamoeba thermarum includes the following stages:
- Trophozoite Stage: This is the active feeding stage where the amoeba consumes nutrients from its environment, often utilizing bacteria as a food source. Trophozoites can thrive at temperatures ranging from 33°C to 57°C, with an optimal growth temperature of around 50°C.
- Encystation: Under unfavorable conditions (e.g., nutrient depletion or extreme environmental changes), Echinamoeba thermarum can undergo encystation. This process allows the amoeba to form a protective cyst that can withstand harsh conditions until favorable conditions return.
- Cyst Stage: Cysts are dormant forms that provide protection against adverse environmental factors. They can remain viable for extended periods and germinate back into trophozoites when conditions improve.
Reproductive Strategies
editEchinamoeba thermarum primarily reproduces asexually through binary fission during the trophozoite stage. This method allows for rapid population increases in suitable environments. The specific mechanisms of reproduction during encystation and subsequent germination are less understood but are crucial for survival in extreme habitats
Ecological significance
editE. thermarum identified as a potential host for Legionella pneumophila, a pathogenic bacterium known to cause Legionnaires' disease.[4] This relationship highlights the importance of understanding the ecology of thermophilic amoebae in both natural and engineered water systems.
References
edit- ^ a b c d Baumgartner, Manuela; Yapi, Ahoua; Gröbner-Ferreira, Regina; Stetter, Karl O. (2003-08-01). "Cultivation and properties of Echinamoeba thermarum n. sp., an extremely thermophilic amoeba thriving in hot springs". Extremophiles. 7 (4): 267–274. doi:10.1007/s00792-003-0319-6. ISSN 1431-0651. PMID 12910386.
- ^ a b c d Rappaport, Hannah B.; Oliverio, Angela M. (2023-08-16). "Extreme environments offer an unprecedented opportunity to understand microbial eukaryotic ecology, evolution, and genome biology". Nature Communications. 14 (1): 4959. Bibcode:2023NatCo..14.4959R. doi:10.1038/s41467-023-40657-4. ISSN 2041-1723. PMC 10432404. PMID 37587119.
- ^ Moreno, Ivan J.; Brahamsha, Bianca; Donia, Mohamed S.; Palenik, Brian (2023-02-09). "Diverse Microbial Hot Spring Mat Communities at Black Canyon of the Colorado River". Microbial Ecology. 86 (3): 1534–1551. Bibcode:2023MicEc..86.1534M. doi:10.1007/s00248-023-02186-x. ISSN 0095-3628. PMC 10497668. PMID 36757423.
- ^ Delafont, Vincent; Bouchon, Didier; Héchard, Yann; Moulin, Laurent (September 2016). "Environmental factors shaping cultured free-living amoebae and their associated bacterial community within drinking water network". Water Research. 100: 382–392. doi:10.1016/j.watres.2016.05.044. ISSN 0043-1354. PMID 27219048.
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