Mixotricha paradoxa
Mixotricha paradoxa | |
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Scientific classification | |
Domain: | Eukaryota |
(unranked): | |
Phylum: | |
Class: | |
Order: | Trichomonadida |
Family: | |
Genus: | Mixotricha
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Species: | M. paradoxa
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Binomial name | |
Mixotricha paradoxa Sutherland, 1933
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Mixotricha paradoxa is a species of
It is composed of five different organisms: three
Mixotricha mitochondria degenerated in hydrogenosomes and mitosomes and lost the ability to produce energy aerobically by oxidative phosphorylation.[1][2] The mitochondria-derived nuclear genes were however conserved.[2]
Discovery
The name was given by the Australian biologist J.L. Sutherland, who first described Mixotricha in 1933.
Behavior
Mixotricha is a species of
Mixotricha is a large protozoan .5 millimetres (0.020 in) long and contains hundreds of thousands of bacteria.[5] It is an endosymbiont and digests cellulose for the termite.[5]
Anatomy
Species of the order
The basal bodies are also bacteria, not spirochaetes but oval, pill-shaped bacteria. There is a one-to-one relationship between a bracket, a spirochaete, and a basal bacterium. Each bracket has one spirochaete running through it and one pill bacterium at its base as the basal body.[5] It has not been shown definitely, but the basal bodies could also be making cellulases that digest wood.[5]
Endosymbionts for biochemical processes
At least one endosymbiont lives inside the protist to help digest cellulose and lignin, a major component of the wood the termites eat. The cellulose gets converted to glucose then to acetate, and the lignin is digested directly to acetate.[2] The acetate probably crosses the termite gut membrane to be digested later.[2]
Mixotricha forms a mutualistic relationship with bacteria living inside the termite. There are a total of four species of bacterial symbionts. It has spherical bacteria inside the cell, which function as mitochondria, which Mixotricha lacks. Mixotricha mitochondria degenerated and lost the ability to produce energy aerobically by oxidative phosphorylation.[1][2] Mitochondrial relics include hydrogenosomes which produce hydrogen and small structures called mitosomes.[2]
Ectosymbionts for movement
Three surface colonising bacteria are anchored on the surface.[10]
The flagella and cilia are actually two different single celled organisms. The ciliate belongs to an archaic group that used to be called archezoa but this term is no longer in fashion.[11] It has four weak flagella, which serve as a rudder.[12][11]
While Mixotricha has four anterior flagella, it does not use them for locomotion, but more for steering.
The wavelength of the cilia is about .1 millimetres (0.0039 in) and suggests that the spirochaetes are somehow in touch with each other.[5]
Mixotricha also has rod-shaped bacteria arranged in an ordered pattern on the surface of the cell.[13]
Each spirochaete has its own little emplacement, called a 'bracket'.[14] Spirochetes move continuously forwards or backwards but when they are attached they move in one direction.[2]
Sperm tails might have their origin in spirochaetes.[2] The evidence that cilia (undulipodia) are symbiotic bacteria is found unpersuasive.[5]
Genome
Mixotricha have five genomes, as they form very close symbiotic relationships with four types of bacteria.[15] It is a good example organism for symbiogenesis and nestedness.[2]
There are two spirochete and one-rod bacteria on its surface, one endosymbiotic bacteria inside to digest cellulose and the host nucleus.[2]
References
- ^ ISBN 978-3-319-28147-6.
- ^ ISBN 9780940262409.
- ^ Jean L. Sutherland: Protozoa from Australian Termites. Quarterly Journal of Microscopical Science, Band s2-76, S. 145-173. (Abstract)
- ^ ISBN 978-0544859937.
- PMID 17764914.
- S2CID 21431174.
- PMID 25352694.
- ISBN 9783540282105.
- ^ "Movement symbiosis2". www.microbiological-garden.net. Retrieved 27 May 2019.
- ^ ISBN 9783540281801.
- ^ "Movement symbiosis". www.microbiological-garden.net. Retrieved 27 May 2019.
- ISBN 9783642216800.
- PMID 17675420.
- ^ Margulis, Lynn; Sagan, Dorion (June 2001). "The Beast with Five Genomes". Natural History. Archived from the original on 15 November 2006. Retrieved 3 May 2007.