Vampirovibrionophyceae is a class of non-Photosynthesis cyanobacteria.
Vampirovibrio chlorellavorus is the only species of the class that has been grown in cell culture.
Treatments
Melainabacteria has been treated as:
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The phylum " Candidatus Melainabacteria" when its DNA was discovered in 2013.
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The class " Candidatus Melainabacteria" under Cyanobacteria in Soo et al. (2014).
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The phylum " Candidatus Melainobacteriota", the 2013 name corrected to match new bacteriological rules.
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The class Vampirovibriophyceae under Cyanobacteria in Strunecký and Mareš 2023, with the corrected spelling Vampirovibrionophyceae.
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The class Vampirovibrionia under Cyanobacteria in 2023.
It was not realized until 2015 that this group actually includes one cultured bacterium.
Treating this group as a phylum would place it at the same taxonomic rank as Cyanobacteriota.
Phylogeny
Classification
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Class Vampirovibrionophyceae Strunecký and Mareš 2023 (ACD20)
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Order " Ca. Caenarcanales" corrig. Soo et al. 2014 "Caenarcaniphilales"
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Family "Caenarcanaceae" Chuvochina et al. 2023
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Genus " Ca. Caenarcanum" Soo et al. 2014
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" Ca. C. bioreactoricola" Soo et al. 2014
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Order Vampirovibrionales Chuvochina et al. 2024
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Family Vampirovibrionaceae Chuvochina et al. 2024
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Genus Vampirovibrio Gromov & Mamkayeva 1972 ex Gromov & Mamkaeva 1980
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V. chlorellavorus Gromov & Mamkayeva 1972 ex Gromov & Mamkaeva 1980
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Order " Ca. Gastranaerophilales" Soo et al. 2014
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Family "Adamsellaceae" Pallen, Rodriguez-R & Alikhan 2022 CAJFVJ01
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Genus " Ca. Adamsella" Glendinning et al. 2020
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Family "RUG14156"
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Genus " Ca. Galligastranaerophilus" Gilroy et al. 2021
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" Ca. G. faecipullorum" Gilroy et al. 2021
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" Ca. G. gallistercoris" Gilroy et al. 2021
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" Ca. G. intestinavium" Gilroy et al. 2021
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" Ca. G. intestinigallinarum" Gilroy et al. 2021
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Family "Gastranaerophilaceae" Gilroy et al. 2021
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Genus " Ca. Avigastranaerophilus" Gilroy et al. 2021
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" Ca. A. faecigallinarum" Gilroy et al. 2021
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Genus " Ca. Gastranaerophilus" Soo et al. 2014
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" Ca. G. phascolarctosicola" Soo et al. 2014
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" Ca. G. termiticola" Utami et al. 2018
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Genus " Ca. Limenecus" Gilroy et al. 2021
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" Ca. L. avicola" Gilroy et al. 2021
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Genus " Ca. Scatenecus" Gilroy et al. 2021
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" Ca. S. faecavius" Gilroy et al. 2021
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Genus " Ca. Scatousia" Gilroy et al. 2021
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" Ca. S. excrementigallinarum" Gilroy et al. 2021
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" Ca. S. excrementipullorum" Gilroy et al. 2021
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Genus " Ca. Spyradomonas" Gilroy et al. 2021
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" Ca. S. excrementavium" Gilroy et al. 2021
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Genus " Ca. Stercorousia" Gilroy et al. 2021
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" Ca. S. faecigallinarum" Gilroy et al. 2021
Ecological niche
Melainabacteria
Nucleic acid can be found in a range of environments, including soil, water, and animal habitats. They can often be found in the gut of humans and in the respiratory tract, oral environments, and skin surface, though rarely. Melainabacteria nucleic acids are often found in natural environments such as groundwater aquifers and lake sediment, soil, and the
aphotic zone of aquatic environments such as lake sediment and aquifers.
Cyanobacteria bloom in freshwater systems as a result of excess nutrients and high temperatures, resulting in a scum on the water surface that resembles spilled paint.
Because melainabacteria is a type of cyanobacteria, it has raised concern because melainabacteria thrive in groundwater systems. The genomes of melainabacteria were found to be bigger when found in aquifer systems and algal cultivation ponds than when in the mammalian gut environment.
Origin
The Great Oxygenation Event (GOE) increased the abundance of oxygen in the atmosphere.
Bacteria that existed before the GOE did not rely on oxygen, such as the billion-year-old cyanobacteria. Melainabacteria do not photosynthesize.
Cyanobacteria produced atmospheric oxygen and supported the development of early plant cells.
Genome
The genomes of melainabacteria organisms isolated from ground water indicate that the organism has the capacity to fix nitrogen. Melainabacteria are predicted to lack linked electron transport chains, but have multiple methods to generate a membrane potential which can then produce ATP via
ATP synthase. They are thought to be able to use
Iron for production that can be consumed by other microorganisms. Melainabacteria from the human gut also are thought to synthesize several
B vitamins and
Vitamin K, which suggests that these bacteria are beneficial to their host because they are consumed along with plant fibers.
Animal habitats
Melainabacteria may play a role in digesting fiber in the human gut,
and their nucleic acids are more commonly found in herbivorous mammals and those with plant-rich diets.
Because plant diets require more fiber break-down, melainabacteria may aid in this digestive function. However, scientists do not know
why these microbes are in the gut and how they got there.
Ongoing studies such as, "The human gut and groundwater harbor non-photosynthetic bacteria belonging to a new candidate phylum sibling to Cyanobacteria," are funded by various organizations such as the National Institutes of Health, the David and Lucile Packard Foundation, The Hartwell Foundation, the Arnold and Mabel Beckman Foundation, the U.S. Department of Energy, the European Molecular Biology Organization and the
Wellcome Trust.
See also
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List of bacteria genera
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List of bacterial orders
External links
