Cafeteria roenbergensis

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Cafeteria roenbergensis
Cafeteria roenbergensis FENCHEL and D J PATTERSON schematic drawing.svg
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Clade: Diaphoretickes
Clade: SAR
Clade: Stramenopiles
Phylum: Bigyra
Class: Bicosoecophyceae
Order: Bicosoecales
Family: Cafeteriaceae
Genus: Cafeteria
Fenchel & Patterson, 1988
Species:
C. roenbergensis
Binomial name
Cafeteria roenbergensis
Fenchel & Patterson, 1988 [1]
Two living cells of C. roenbergensis. Light micrograph. The cells are about 6 mm long. The anterior flagellum beats with an undulating pattern, the posterior (recurrent or smooth) flagellum usually holds the cell to the substrate. Cafeteria roenbergensis atcc50561 Protsville.jpg
Two living cells of C. roenbergensis. Light micrograph. The cells are about 6 μm long. The anterior flagellum beats with an undulating pattern, the posterior (recurrent or smooth) flagellum usually holds the cell to the substrate.

Cafeteria roenbergensis is a small bacterivorous marine flagellate. It was discovered by Danish marine ecologist Tom Fenchel and named by him and taxonomist David J. Patterson in 1988. It is in one of three genera of bicosoecids, and the first discovered of two known Cafeteria species. Bicosoecids belong to a broad group, the stramenopiles, also known as heterokonts (Heterokonta) that includes photosynthetic groups such as diatoms, brown, and golden algae, and non-photosynthetic groups such as opalinids, actinophryid "heliozoans", and oomycetes. The species is found primarily in coastal waters where there are high concentrations of bacteria on which it grazes. Its voracious appetite plays a significant role in regulating bacteria populations.

Physiology

Cafeteria roenbergensis is a slightly flattened, kidney-shaped bicosoecid. Its cell typically measures between 3 and 10 μm and it has a volume of around 20 μm3. [2] It is colorless and has two unequally sized flagella. The smooth flagellum, angled posteriorly, is shorter, and attaches to substrates in non-motile cells, but trails behind in motile cells. The hairy flagellum points forward in an arc in sessile cells. Cafeteria is a eukaryotic organism, so it contains the typical organelles such as mitochondria and nuclei. [2]

Cafeteria roenbergensis reproduces asexually via binary fission [ citation needed ], first replicating the flagella and internal organelles before the cell divides. No sexual activity is known for this species. Cells can replicate in under 10 hours.

Behavior

Cafeteria roenbergensis is a suspension feeder, meaning that it feeds by filtering suspended bacteria, its primary food source, and other particulate matter from the water. [3] Its two flagella facilitate feeding, locomotion and attachment to substrates. The anterior flagellum is responsible for locomotion and feeding. It propels the cell in a swift spiral movement. During feeding, it beats at about 40 times per second to create a current of water that moves about 100 micrometers/second. This current brings bacteria to its mouthparts. The food is ingested below the base of the flagella, which is referred to as the ventral side. In nonmotile C. roenbergensis cells, (cells that prefer to anchor themselves to a substrate) the posterior flagellum helps attach the organism to a substrate while it is feeding. [4] The flagella are anchored by 'rootlets' ribbons and subcellular ropes. They act as a skeleton and also support the mouth region.

Ecology

Bacterivorous nanoflagellates, the general group to which C. roenbergensis belongs, make up a significant portion of the oceans' protozoan communities, as well as those in freshwater, soils and other habitats. They are reported to be the primary consumer of bacteria in many habitats, controlling bacterial populations as they "graze". [5]

Habitat

Cafeteria roenbergensis has been found in all oceans examined, but is especially common in coastal waters. [6] These protists occur in a type of biosphere known as "microbial assemblages". This means that they are present at such low abundances, that they are not easily detected, and can only be retrieved and isolated using specialized isolation techniques such as flow cytometry. [7] Ishigaki and Sleigh (2001) found that C. roenbergensis ceased to reproduce when the concentration of bacteria that they were grazing on became less than 2.0×107 cells ml−1. [8] Other flagellates were able to multiply at much lower bacterial concentrations, indicating that bacterial concentration is a limiting factor for Cafeteria. Flagellates have varying abilities to gather bacteria to their mouths with their flagella, and this study suggests that the abilities of Cafeteria species may be inferior to other flagellates, since Cafeteria are usually specific to niches with high concentrations of bacteria. [3]

Virus

A giant virus, Cafeteria roenbergensis virus (CroV) infects and causes the lysis of C. roenbergensis. [9] The impact of CroV on natural populations of C. roenbergensis remains unknown; however, the virus has been found to be very host specific, and does not infect other closely related organisms. [3] C. roenbergensis is also infected by a second virus, the Mavirus virophage, which is only able to replicate in the presence of CroV. [10] This virus interferes with the replication of CroV, which leads to the survival of C. roenbergensis cells. Mavirus is able to integrate into the genome of cells of C. roenbergensis, and thereby confer immunity to the population [11]

Taxonomy

Cafeteria is categorized in a group called the "Heterotrophic group". It has one other known species in its genus, Cafeteria minuta, which was found living in tropical marine sediments by Larsen and Patterson in 1990. [5]

Name

Marine biologist Tom Fenchel, one of the two species authorities who first described C. roenbergensis, is credited with having joked about the chromalveolate's name: "We found a new species of ciliate during a marine field course in Rønbjerg and named it Cafeteria roenbergensis because of its voracious and indiscriminate appetite after many dinner discussions in the local cafeteria." [12]

Mitochondrial genome

Cafeteria roenbergensis has a highly compact mitochondrial genome that includes less than 3.4% introns. Some sources hold that its mitochondrial genome contains no introns at all. [13] The mitochondrial translation code in C. roenbergensis is not standard in comparison to its closest known relatives, Phytophthora infestans and Ochromonas danica. Instead of acting as a stop codon, in Cafeteria, UGA codes for tryptophan. [14]

Culture

Because they are easy to grow in culture, Cafeteria roenbergensis has been subject to a diversity of more detailed studies, such as genomic and ecological studies that have revealed that this species has the most functionally compact DNA amongst eukaryotes. [6] While in culture, Cafeteria are fed Vibrio bacteria. In a test conducted by Park and Simpson in 2010, it was found that Cafeteria cells grow best in salinities of 3 ppm to 100 ppm, but cannot survive at concentrations any higher. [15]

Related Research Articles

<span class="mw-page-title-main">Flagellate</span> Group of protists with at least one whip-like appendage

A flagellate is a cell or organism with one or more whip-like appendages called flagella. The word flagellate also describes a particular construction characteristic of many prokaryotes and eukaryotes and their means of motion. The term presently does not imply any specific relationship or classification of the organisms that possess flagella. However, the term "flagellate" is included in other terms which are more formally characterized.

<span class="mw-page-title-main">Stramenopile</span> Clade of eukaryotes

The Stramenopiles, also called Heterokonts, are a clade of organisms distinguished by the presence of stiff tripartite external hairs. In most species, the hairs are attached to flagella, in some they are attached to other areas of the cellular surface, and in some they have been secondarily lost. Stramenopiles represent one of the three major clades in the SAR supergroup, along with Alveolata and Rhizaria.

<span class="mw-page-title-main">Flagellum</span> Cellular appendage functioning as locomotive or sensory organelle

A flagellum is a hairlike appendage that protrudes from certain plant and animal sperm cells, from fungal spores (zoospores), and from a wide range of microorganisms to provide motility. Many protists with flagella are known as flagellates.

<span class="mw-page-title-main">Choanoflagellate</span> Group of eukaryotes considered the closest living relatives of animals

The choanoflagellates are a group of free-living unicellular and colonial flagellate eukaryotes considered to be the closest living relatives of the animals. Choanoflagellates are collared flagellates, having a funnel shaped collar of interconnected microvilli at the base of a flagellum. Choanoflagellates are capable of both asexual and sexual reproduction. They have a distinctive cell morphology characterized by an ovoid or spherical cell body 3–10 µm in diameter with a single apical flagellum surrounded by a collar of 30–40 microvilli. Movement of the flagellum creates water currents that can propel free-swimming choanoflagellates through the water column and trap bacteria and detritus against the collar of microvilli, where these foodstuffs are engulfed. This feeding provides a critical link within the global carbon cycle, linking trophic levels. In addition to their critical ecological roles, choanoflagellates are of particular interest to evolutionary biologists studying the origins of multicellularity in animals. As the closest living relatives of animals, choanoflagellates serve as a useful model for reconstructions of the last unicellular ancestor of animals.

<i>Stephanopogon</i> Genus of flagellate marine protozoan

Stephanopogon is a genus of flagellated marine protist that superficially resembles a ciliate.

<i>Bodo saltans</i> Species of kinetoplastid flagellated phagotrophic protozoa

Bodo saltans is a free-living nonparasitic species of kinetoplastid flagellated phagotrophic protozoa that feed on bacteria. Bodo saltans cells have been reported in freshwater and marine environments.

<span class="mw-page-title-main">Telonemia</span> Phylum of single-celled organisms

Telonemia is a phylum of microscopic eukaryotes commonly known as telonemids. They are unicellular free-living flagellates with a unique combination of cell structures, including a highly complex cytoskeleton unseen in other eukaryotes.

<i>Cafeteria</i> (bicosoecid) Genus of single-celled organisms

Cafeteria is a genus of marine bicosoecid described in 1988 by Tom Fenchel and D. J. Patterson. It was created after the discovery of a new species, Cafeteria roenbergensis, a tiny (5–10 μm) eukaryotic organism that is eaten by protozoa and small invertebrates. The name is meant to indicate the importance of the genus in the food web.

Carpediemonas is genus of Metamonada, and belongs to the group Excavata. This organism is a unicellular flagellated eukaryote that was first discovered in substrate samples from the Great Barrier Reef. Carpediemonas can be found in anaerobic intertidal sediment, where it feeds on bacteria. A feature of this species is the presence of a feeding groove, a characteristic of the excavates. Like most other metamonads, Carpediemonas does not rely on an aerobic mitochondrion to produce energy. Instead, it contains hydrogenosomes that are used to produce ATP. This organism has two flagella: a posterior one used for feeding on the substrate, and an anterior one that moves in a slower sweeping motion. Carpediemonas is assigned to the fornicates, where similar Carpediemonas-like organisms are used in researching the evolution within excavates. Although Carpediemonas is a member of the metamonads, it is unusual in the sense that it is free-living and has three basal bodies.

<span class="mw-page-title-main">Jakobid</span>

Jakobids are an order of free-living, heterotrophic, flagellar eukaryotes in the supergroup Excavata. They are small, and can be found in aerobic and anaerobic environments. The order Jakobida, believed to be monophyletic, consists of only twenty species at present, and was classified as a group in 1993. There is ongoing research into the mitochondrial genomes of jakobids, which are unusually large and bacteria-like, evidence that jakobids may be important to the evolutionary history of eukaryotes.

<span class="mw-page-title-main">Bigyra</span> Phylum of single-celled organisms

Bigyra is a phylum of microscopic eukaryotes that are found at the base of the Stramenopiles clade. It includes three well-known heterotrophic groups Bicosoecida, Opalinata and Labyrinthulomycetes, as well as several small clades initially discovered through environmental DNA samples: Nanomonadea, Placididea, Opalomonadea and Eogyrea. The classification of Bigyra has changed several times since its origin, and its monophyly remains unresolved.

<i>Jakoba</i> Genus of Eukaryotic Organisms

Jakoba is a genus in the taxon Excavata, and currently has a single described species, Jakoba libera described by Patterson in 1990, and named in honour of Dutch botanist Jakoba Ruinen.

<i>Katabia</i> Genus of heterotrophic protists

Katabia is a genus of soil-dwelling heterotrophic flagellate cercozoans containing the single species Katabia gromovi, and the only member of family Katabiidae.

<i>Cafeteria roenbergensis virus</i> Species of virus

Cafeteria roenbergensis virus (CroV) is a giant virus that infects the marine bicosoecid flagellate Cafeteria roenbergensis, a member of the microzooplankton community.

<span class="mw-page-title-main">Mavirus</span> Genus of viruses

Mavirus is a genus of double stranded DNA virus that can infect the marine phagotrophic flagellate Cafeteria roenbergensis, but only in the presence of the giant CroV virus. The genus contains only one species, Cafeteriavirus-dependent mavirus. Mavirus can integrate into the genome of cells of C. roenbergensis, and thereby confer immunity to the population

<i>Neobodo</i> Genus of protists

Neobodo are diverse protists belonging to the eukaryotic supergroup Excavata. They are Kinetoplastids in the subclass Bodonidae. They are small, free-living, heterotrophic flagellates with two flagella of unequal length used to create a propulsive current for feeding. As members of Kinetoplastids, they have an evident kinetoplast There was much confusion and debate within the class Kinetoplastid and subclass Bodonidae regarding the classification of the organism, but finally the new genera Neobodo was proposed by Keith Vickerman. Although they are one of the most common flagellates found in freshwater, they are also able to tolerate saltwater Their ability to alternate between both marine and freshwater environments in many parts of the world give them a “cosmopolitan” character. Due to their relatively microscopic size ranging between 4–12 microns, they are further distinguished as heterotrophic nanoflagellates. This small size ratio limits them as bacterivores that swim around feeding on bacteria attached to surfaces or in aggregates.

<span class="mw-page-title-main">Marine viruses</span> Viruses found in marine environments

Marine viruses are defined by their habitat as viruses that are found in marine environments, that is, in the saltwater of seas or oceans or the brackish water of coastal estuaries. Viruses are small infectious agents that can only replicate inside the living cells of a host organism, because they need the replication machinery of the host to do so. They can infect all types of life forms, from animals and plants to microorganisms, including bacteria and archaea.

Stygiella /ˌstɪ.d͡ʒiˈɛ.lə/ is a genus of free-living marine flagellates belonging to the family Stygiellidae in the jakobids (excavata).

<span class="mw-page-title-main">Marine prokaryotes</span> Marine bacteria and marine archaea

Marine prokaryotes are marine bacteria and marine archaea. They are defined by their habitat as prokaryotes that live in marine environments, that is, in the saltwater of seas or oceans or the brackish water of coastal estuaries. All cellular life forms can be divided into prokaryotes and eukaryotes. Eukaryotes are organisms whose cells have a nucleus enclosed within membranes, whereas prokaryotes are the organisms that do not have a nucleus enclosed within a membrane. The three-domain system of classifying life adds another division: the prokaryotes are divided into two domains of life, the microscopic bacteria and the microscopic archaea, while everything else, the eukaryotes, become the third domain.

<i>Cafileria</i> Genus of marine protists

Cafileria is a genus of marine microscopic protists. It is monotypic, comprising the single species Cafileria marina, described in 2019 from Norway. It is part of a clade of heterotrophic flagellates that consume bacteria, known as Bicosoecida, a basal lineage of Stramenopiles. Due to its small size it is described as a nanoflagellate. It is the only organism where direct connections between mitochondria and the cell nucleus have been observed. Another peculiarity of C. marina is the change in shape of the Golgi apparatus during the cell cycle.

References

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  2. 1 2 Otto, K.; D. Weichart & S. Kjelleberg (1997). "Plasmid transfer between marine Vibrio strains during predation by the heterotrophic microflagellate Cafeteria reonbergensis". Applied and Environmental Microbiology . 63 (2): 749–752. Bibcode:1997ApEnM..63..749O. doi: 10.1128/AEM.63.2.749-752.1997 . PMC   1389530 . PMID   16535524.
  3. 1 2 3 Massana, Ramon; Javier Del Campo; Christian Dinter; Ruben Sommaruga (2007). "Crash of a population of the marine heterotrophic flagellate Cafeteria roenbergensis by viral infection". Environmental Microbiology . 9 (11): 2660–2669. doi:10.1111/j.1462-2920.2007.01378.x. PMID   17922751. S2CID   30191542.
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  8. Thomas Ishigaki; M. A. Sleigh (2001). "Grazing characteristics and growth efficiencies at two different temperatures for three nanoflagellates fed with Vibrio bacteria at three different concentrations". Microbial Ecology . 41 (3): 264–271. doi:10.1007/s002480000060. JSTOR   4251819. PMID   11391464. S2CID   29625660.
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