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Euglena is a genus of single-celled, flagellate . It is the best-known and most widely studied member of the class Euglenoidea, a diverse group containing some 54 genera and at least 200 species. Species of Euglena are found in fresh water and salt water. They are often abundant in quiet inland waters where they may bloom in numbers sufficient to color the surface of ponds and ditches green ( Euglena viridis) or red ( E. sanguinea).
The species Euglena gracilis has been used extensively in the laboratory as a model organism.
Most species of Euglena have photosynthesizing within the body of the cell, which enable them to feed by autotrophy, like plants. However, they can also take nourishment , like animals. Since Euglena have features of both animals and plants, early taxonomists, working within the Linnaean two-kingdom system of biological classification, found them difficult to classify. (2025). 9781603581363, Chelsea Green. ISBN 9781603581363 It was the question of where to put such "unclassifiable" creatures that prompted Ernst Haeckel to add a third living kingdom (a fourth kingdom in toto) to the Animale, Vegetabile (and Lapideum meaning Mineral) of Carl Linnaeus: the Kingdom Protista. (2025). 9780534492762, Brooks/Cole Thompson Learning. ISBN 9780534492762
In 1786, O.F. Müller gave a more complete description of the organism, which he named Cercaria viridis, noting its distinctive color and changeable body shape. Müller also provided a series of illustrations, accurately depicting the undulating, contractile movements (metaboly) of the cell body. In 1830, C. G. Ehrenberg renamed Müller's Cercaria Euglena viridis, and placed it, in keeping with the short-lived system of classification he invented, among the Polygastrica in the family Astasiaea: multi-stomached creatures with no alimentary canal, variable body shape but no pseudopods or lorica. Ehrenberg, C. Organisation, Systematik und geographisches Verhältnifs der Infusionsthierchen. Vol. II. Berlin, 1830. pp 58-9 By making use of the newly invented achromatic microscope, Ehrenberg was able to see Euglena's eyespot, which he correctly identified as a "rudimentary eye" (although he reasoned, wrongly, that this meant the creature also had a nervous system). This feature was incorporated into Ehrenberg's name for the new genus, constructed from the Greek roots "eu-" (well, good) and glēnē (eyeball, socket of joint).
Ehrenberg did not notice Euglenas flagella, however. The first to publish a record of this feature was Félix Dujardin, who added "filament flagelliforme" to the descriptive criteria of the genus in 1841. Subsequently, the class Flagellata (Cohn, 1853) was created for creatures, like Euglena, possessing one or more flagella. While "Flagellata" has fallen from use as a taxon, the notion of using flagella as a phylogenetic criterion remains vigorous.
As early as 1935, it was recognized that this was an artificial grouping, however convenient. In 1948, Pringsheim affirmed that the distinction between green and colorless flagellates had little taxonomic justification, although he acknowledged its practical appeal. He proposed something of a compromise, placing colorless, saprotrophic euglenoids in the genus Astasia, while allowing some colorless euglenoids to share a genus with their photosynthesizing cousins, provided they had structural features that proved common ancestry. Among the green euglenoids themselves, Pringsheim recognized the close kinship of some species of Phacus and Lepocinclis with some species of Euglena.
By the 1950s, when A. Hollande published a major revision of the phylum, organisms were classified by shared structural features, such as the number and type of flagella. In the 1970s, it was hypothesized that photosynthetic euglenoids derived their chloroplasts by engulfing an algal cell and took its photosynthetic machinery. This secondary endosymbiosis hypothesis was later confirmed through molecular evidence, and it appears that the photosynthetic euglenoids are grouped into one clade. (2025). 9780123858764, Elsevier Inc.. ISBN 9780123858764 However, genetic analysis of the non-photosynthesizing euglenoid Astasia longa confirmed that this organism retains sequences of DNA inherited from an ancestor that must have had functioning chloroplasts; therefore, some once-photosynthetic lineages must have later lost the chloroplasts. Recognizing the non-monophyletic nature of the genus Euglena, Marin et al. (2003) have revised it to include certain members traditionally placed in Astasia and Khawkinea.
Throughout its taxonomic history, Euglena served as a "holding bag" for species that did not morphologically fit into other groups. This made Euglena a heterogeneous assemblage, and made correct species identification very difficult. Some researchers proposed intra-generic groups within Euglena; for example Pringsheim (1956) named five groups (Rigidae, Lentiferae, Catilliferae, Radiatae, Serpentes) based on cell shape and chloroplast morphology, while Zakryś (1986) named three subgenera (Euglena, Calliglena and Discoglena) based on chloroplast and paramylon morphology. However, molecular phylogenetics once again showed that these groups did not always correspond to evolutionary lineages. To revise this, taxonomists have transferred species out of Euglena and into other genera, including Lepocinclis, Phacus, and the newly proposed genera Discoplastis, Euglenaria, and Euglenaformis.
Euglena chloroplasts contain , used in the synthesis of paramylon, a form of starch energy storage enabling Euglena to survive periods of light deprivation. The presence of pyrenoids is used as an identifying feature of the genus, separating it from other euglenoids, such as Lepocinclis and Phacus. Pyrenoids may be surrounded by a single paramylon cap (these pyrenoids are called haplopyrenoids), a bilateral paramylon cap (these are called diplopyrenoids), or a cluster of small paramylon grains (called a paramylon center), or may be "naked" and lack associated paramylon bodies.
Chloroplast morphology in Euglena is diverse, and can be broadly divided into four groups. The first group consists of E. archaeoplastidiata, which has a single, parietal chloroplast with two diplopyrenoids. The second group (e.g. Euglena viridis) has axial, stellate chloroplasts with paramylon center. The third group has parietal, lobed chloroplasts, each with a naked, haplo- or diplopyrenoid; this group is very diverse and identification may be difficult. The fourth group (e.g. E. sanguinea) has plate-like, parietal chloroplasts each with a single diplopyrenoid. The chloroplast centers are located deep within the cell, and the chloroplasts are deeply dissected into long bands, which follow the spiral contours of the cell.
Euglena have two flagella rooted in basal body located in a small reservoir at the front of the cell. Typically, one flagellum is very short, and does not protrude from the cell, while the other is long enough to be seen with light microscopy. In some species, such as Euglena mutabilis, both flagella are "non-emergent"—entirely confined to the interior of the cell's reservoir—and consequently cannot be seen in the light microscope.
Like other euglenoids, Euglena possess a red eyespot, an organelle composed of carotenoid pigment granules. The red spot itself is not thought to be photosensitive. Rather, it filters the sunlight that falls on a light-detecting structure at the base of the flagellum (a swelling, known as the paraflagellar body), allowing only certain wavelengths of light to reach it. As the cell rotates with respect to the light source, the eyespot partially blocks the source, permitting the Euglena to find the light and move toward it (a process known as phototaxis).
Euglena lacks a cell wall. Instead, it has a pellicle made up of a protein layer supported by a substructure of , arranged in strips spiraling around the cell. The action of these pellicle strips sliding over one another, known as metaboly, gives Euglena its exceptional flexibility and contractility. The mechanism of this euglenoid movement is not understood, but its molecular basis may be similar to that of amoeboid movement. Some species have mucocysts, which are membrane-bound bodies containing mucilaginous threads. Mucocysts are located underneath the pellicle in parallel rows following the arrangement of pellicle strips. Their presence or absence and shape (spherical or spindle-shaped) are an important diagnostic for species-level identification, but are mostly only visible after staining with a dye such as neutral red.
In low moisture conditions, or when food is scarce, Euglena forms a protective wall around itself and lies dormant as a resting cyst until environmental conditions improve.
Reports of isogamy are rare, and have not been substantiated.
The taste of powdered Euglena is described as dried sardine flakes, and contains minerals, vitamins and docosahexaenoic acid, an omega-3 acid. The powder is used as ingredient in other foods. Kemin Industries sells a euglena nutraceutical supplement ingredient featuring dried Euglena gracilis with high levels of Beta-glucan.
The lipid content of Euglena (mainly wax esters) is seen as a promising feedstock for production of biodiesel and jet fuel. Under the aegis of Itochu, a start-up company called Euglena Co., Ltd. has completed a refinery plant in Yokohama in 2018, with a production capacity of 125 kiloliters of bio jet fuel and biodiesel per year.Video explanation lacks technical details but suggests degree of government commitment to solving problems of large-scale cultivation and infrastructure. CEO of Euglena Co. wears euglena-green necktie.
Form and function
When feeding as a heterotroph, Euglena takes in nutrients by osmotrophy, and can survive without light on a diet of organic matter, such as beef extract, peptone, acetate, ethanol or . When there is sufficient sunlight for it to feed by phototrophy, it uses chloroplasts containing the pigments chlorophyll a and chlorophyll b to produce sugars by photosynthesis. Euglena's chloroplasts are surrounded by three membranes, while those of plants and the green algae (among which earlier taxonomists often placed Euglena) have only two membranes. This fact has been taken as morphological evidence that Euglena's chloroplasts evolved from a eukaryotic green alga. Thus, the similarities between Euglena and plants would have arisen not because of kinship but because of a secondary endosymbiosis. Molecular phylogenetic analysis has lent support to this hypothesis, and it is now generally accepted.
(2025). 9780123858764, Elsevier Inc.. ISBN 9780123858764
(2025). 9780870138799, Michigan State University Press. ISBN 9780870138799 In species that possess a long, emergent flagellum, it may be used to help the organism swim. The surface of the flagellum is coated with about 30,000 extremely fine filaments called .
Reproduction
Euglena reproduce asexually through binary fission, a form of cell division. Reproduction begins with the mitosis of the cell nucleus, followed by the division of the cell itself. Euglena divide longitudinally, beginning at the front end of the cell, with the duplication of flagellar processes, gullet and stigma. Presently, a cleavage forms in the anterior, and a V-shaped bifurcation gradually moves toward the posterior, until the two halves are entirely separated.
Uses
Euglena has been used extensively as a model organism. It is capable of both heterotrophic and photosynthetic growth, meaning it can be grown in both light and dark conditions and it is thus relatively easy to cultivate. Euglena was one of the first photosynthetic organisms to have its chloroplast genome sequenced, and the chloroplast of Euglena has been extensively studied in the fields of biochemistry, cell biology and molecular biology. (2025). 9783319549088 ISBN 9783319549088 In 2015, Ellis O'Neill and Professor Rob Field have sequenced the transcriptome of Euglena gracilis, which provides information about all of the genes that the organism is actively using. They found that Euglena gracilis has a whole host of new, unclassified genes which can make new forms of and natural products. The potential in your pond published on August 14, 2015 by the "John Innes Centre" In addition, Euglena is commonly used in classrooms to demonstrate important biological processes, such as photosynthesis, or population growth.
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