Euglenids or euglenoids are one of the best-known groups of eukaryotic flagellates: single-celled organisms with flagella, or whip-like tails. They are classified in the phylum Euglenophyta, class Euglenida or Euglenoidea. Euglenids are commonly found in fresh water, especially when it is rich in organic materials, but they have a few marine and endosymbiotic members. Many euglenids feed by phagocytosis, or strictly by diffusion. A monophyletic subgroup known as Euglenophyceae have chloroplasts and produce their own food through photosynthesis.[3][4][5] This group contains the carbohydrate paramylon.

Euglenid
Temporal range: Middle Ordovician–Present[1][2]
Euglena viridis, by Ehrenberg
Scientific classification Edit this classification
Domain: Eukaryota
Clade: Discoba
Superphylum: Discicristata
Phylum: Euglenozoa
Class: Euglenida
Butschli 1884, emend. Simpson 1997
Major groups
Synonyms
  • Euglenoidina Bütschli, 1884, Blochmann, 1886
  • Euglenoidea Lankester, 1885
  • Euglenoida Cavalier-Smith, 1993

Euglenids split from other Euglenozoa (a larger group of flagellates) more than a billion years ago. The plastids (membranous organelles) in all extant photosynthetic species result from secondary endosymbiosis between a euglenid and a green alga.[6]

Structure

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Euglenoids are distinguished mainly by the presence of a type of cell covering called a pellicle. Within its taxon, the pellicle is one of the euglenoids' most diverse morphological features.[7] The pellicle is composed of proteinaceous strips underneath the cell membrane, supported by dorsal and ventral microtubules. This varies from rigid to flexible, and gives the cell its shape, often giving it distinctive striations. In many euglenids, the strips can slide past one another, causing an inching motion called metaboly. Otherwise, they move using their flagella.

 
Euglenid Body Plan
  1. Dorsal flagellum
  2. Axoneme
  3. Paraflagellar rod
  4. Mastigonemes, "hairs" attached to flagellum
  5. Flagellar pocket vestibulum
  6. Feeding apparatus
  7. Paraxial swelling
  8. Eyespot, photoreceptor used to sense light direction and intensity
  9. Contractile vacuole, regulates the quantity of water inside a cell
  10. Ventral flagellum
  11. Ventral root
  12. Golgi apparatus; modifies proteins and sends them out of the cell
  13. Endoplasmic reticulum, the transport network for molecules going to specific parts of the cell
  14. Phagosome
  15. Lysosome, holds enzymes
  16. Nucleus
  17. Nucleolus
  18. Plastid membranes (3, secondary)
  19. Thylakoids, site of the light-dependent reactions of photosynthesis
  20. Pyrenoid, center of carbon fixation
  21. Paramylon granules
  22. Pellicular strip
  23. Muciferous body
  24. Mitochondrion, creates ATP (energy) for the cell (discoid cristae)

Classification

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Examples of euglenid diversity.
1—2. Ascoglena sp. (Euglenales);
3–4. Cryptoglena sp. (idem);
5–9, 14–15, 24–25, 27–29. Trachelomonas spp. (id.);
10. Eutreptia sp. (Eutreptiales);
11, 20. Astasia spp. (Euglenales);
12. Distigma sp. (Eutreptiales);
13. Menoid[i]um sp. (Rhabdomonadales);
16–18. Colacium sp. (Euglenales);
19, 26. Petalomonas spp. (Sphenomonadales);
21. Sphenomonas sp. (id.);
22–23. Euglenopsis sp. (Euglenales);
30. Peranema sp. (Heteronematales)

The first attempt at classifying euglenids was done by Ehrenberg in 1830, when he described the genus Euglena and placed it in the Polygastrica of family Astasiae, containing other creatures of variable body shape and lacking pseudopods or lorica. Later, various biologists described additional characteristics for Euglena and established different classification systems for euglenids based on nutrition modes, the presence and number of flagella, and the degree of metaboly. The 1942 revision by A. Hollande distinguished three groups, Peranemoidées (flexible phagotrophs), Petalomonadinées (rigid phagotrophs) and Euglenidinées (phototrophs), and was widely accepted as the best reflection of the natural relationships between euglenids, adopted by many other authors.[8] Gordon F. Leedale expanded on Hollande's system, establishing six orders (Eutreptiales, Euglenales, Rhabdomonadales, Sphenomonadales, Heteronematales and Euglenamorphales) and taking into account new data on their physiology and ultrastructure. This scheme endured until 1986, with the sequencing of the SSU rRNA gene from Euglena gracilis.[8]

Euglenids are currently regarded as a highly diverse clade within Euglenozoa, in the eukaryotic supergroup Discoba.[9] They are traditionally organized into three categories based on modes of nutrition: the phototrophs (Euglenophyceae), the osmotrophs (mainly the 'primary osmotrophs' known as Aphagea), and the phagotrophs, from which the first two groups have evolved.[10] The phagotrophs, although paraphyletic, have historically been classified under the name of Heteronematina.[9]

In addition, euglenids can be divided into inflexible or rigid euglenids, and flexible or metabolic euglenids which are capable of 'metaboly' or 'euglenid motion'. Only those with more than 18 protein strips in their pellicle gain this flexibility. Phylogenetic studies show that various clades of rigid phagotrophic euglenids compose the base of the euglenid tree, namely Petalomonadida and the paraphyletic 'Ploeotiida'. In contrast, all flexible euglenids belong to a monophyletic group known as Spirocuta, which includes Euglenophyceae, Aphagea and various phagotrophs (Peranemidae, Anisonemidae and Neometanemidae). The current classification of class Euglenida, as a result of these studies, is as follows:[10][11][12][13][14]

Nutrition

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The classification of euglenids is still variable, as groups are being revised to conform with their molecular phylogeny. Classifications have fallen in line with the traditional groups based on differences in nutrition and number of flagella; these provide a starting point for considering euglenid diversity. Different characteristics of the euglenids' pellicles can provide insight into their modes of movement and nutrition.[18]

As with other Euglenozoa, the primitive mode of nutrition is phagocytosis. Prey such as bacteria and smaller flagellates is ingested through a cytostome, supported by microtubules. These are often packed together to form two or more rods, which function in ingestion, and in Entosiphon form an extendable siphon. Most phagotrophic euglenids have two flagella, one leading and one trailing. The latter is used for gliding along the substrate. In some, such as Peranema, the leading flagellum is rigid and beats only at its tip.

Osmotrophic euglenoids

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Osmotrophic euglenids are euglenids which have undergone osmotrophy.

Due to a lack of characteristics that are useful for taxonomical purposes, the origin of osmotrophic euglenids is unclear, though certain morphological characteristics reveal a small fraction of osmotrophic euglenids are derived from phototrophic and phagotrophic ancestors.[19]

A prolonged absence of light or exposure to harmful chemicals may cause atrophy and absorption of the chloroplasts without otherwise harming the organism. A number of species exists where a chloroplast's absence was formerly marked with separate genera such as Astasia (colourless Euglena) and Hyalophacus (colourless Phacus). Due to the lack of a developed cytostome, these forms feed exclusively by osmotrophic absorption.

Reproduction

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Although euglenids share several common characteristics with animals, which is why they were originally classified as so, no evidence has been found of euglenids ever using sexual reproduction. This is one of the reasons they could no longer be classified as animals.[dubiousdiscuss]

For euglenids to reproduce, asexual reproduction takes place in the form of binary fission, and the cells replicate and divide during mitosis and cytokinesis. This process occurs in a very distinct order. First, the basal bodies and flagella replicate, then the cytostome and microtubules (the feeding apparatus), and finally the nucleus and remaining cytoskeleton. Once this occurs, the organism begins to cleave at the basal bodies, and this cleavage line moves towards the center of the organism until two separate euglenids are evident.[20] Because of the way that this reproduction takes place and the axis of separation, it is called longitudinal cell division or longitudinal binary fission.[21]

Evolution

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The earliest fossil of euglenids is attributed to Moyeria, which is interpreted as possessing a pellicle composed of proteinaceous strips, the defining characteristic of euglenids. It is found in Middle Ordovician and Silurian rocks, making it the oldest fossil evidence of euglenids.[1][2]

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References

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  1. ^ a b Gray, Jane; Boucot, A. J. (1989). "Is Moyeria a euglenoid?". Lethaia. 22 (4): 447–456. doi:10.1111/j.1502-3931.1989.tb01449.x.
  2. ^ a b Strother, Paul K.; Taylor, Wilson A.; van de Schootbrugge, Bas; Leander, Brian S.; Wellman, Charles H. (2020). "Pellicle ultrastructure demonstrates that Moyeria is a fossil euglenid". Palynology. 44 (3): 461–471. doi:10.1080/01916122.2019.1625457.
  3. ^ Karnkowska, Anna; Bennett, Matthew S.; Triemer, Richard E. (2018). "Dynamic evolution of inverted repeats in Euglenophyta plastid genomes". Scientific Reports. 8 (1): 16071. Bibcode:2018NatSR...816071K. doi:10.1038/s41598-018-34457-w. PMC 6207741. PMID 30375469.
  4. ^ Yoshihisa Hirakawa (2017). Secondary Endosymbioses. Academic Press. p. 323. ISBN 9780128026809.
  5. ^ "Algaebase :: Subclass: Euglenophycidae". Archived from the original on 2020-07-13. Retrieved 2019-10-27.
  6. ^ Zakryś, B; Milanowski, R; Karnkowska, A (2017). "Evolutionary Origin of Euglena". Euglena: Biochemistry, Cell and Molecular Biology. Advances in Experimental Medicine and Biology. Vol. 979. pp. 3–17. doi:10.1007/978-3-319-54910-1_1. ISBN 978-3-319-54908-8. PMID 28429314.
  7. ^ Leander, Brian S.; Farmer, Mark A. (2001-03-01). "Comparative Morphology of the Euglenid Pellicle. II. Diversity of Strip Substructure". Journal of Eukaryotic Microbiology. 48 (2): 202–217. doi:10.1111/j.1550-7408.2001.tb00304.x. ISSN 1550-7408. PMID 12095109. S2CID 2109559.
  8. ^ a b Carlos E. de M. Bicudo; Mariângela Menezes (16 March 2016). "Phylogeny and Classification of Euglenophyceae: A Brief Review". Frontiers in Ecology and Evolution. 4. doi:10.3389/FEVO.2016.00017. ISSN 2296-701X. Wikidata Q57898656.
  9. ^ a b Sina M. Adl; David Bass; Christopher E. Lane; et al. (1 January 2019). "Revisions to the Classification, Nomenclature, and Diversity of Eukaryotes". Journal of Eukaryotic Microbiology. 66 (1): 4–119. doi:10.1111/JEU.12691. ISSN 1066-5234. PMC 6492006. PMID 30257078. Wikidata Q57086550.
  10. ^ a b Gordon Lax; Alastair G. B. Simpson (16 August 2020). "The Molecular Diversity of Phagotrophic Euglenids Examined Using Single-cell Methods". Protist. 171 (5): 125757. doi:10.1016/J.PROTIS.2020.125757. ISSN 1434-4610. PMID 33126020. Wikidata Q101127864.
  11. ^ a b G. Lax; M. Kolisko; Y. Eglit; et al. (June 2021). "Multigene phylogenetics of euglenids based on single-cell transcriptomics of diverse phagotrophs". Molecular Phylogenetics and Evolution. 159: 107088. doi:10.1016/J.YMPEV.2021.107088. ISSN 1055-7903. Wikidata Q110667805.
  12. ^ Alexei Y. Kostygov; Anna Karnkowska; Jan Votýpka; Daria Tashyreva; Kacper Maciszewski; Vyacheslav Yurchenko; Julius Lukeš (10 March 2021). "Euglenozoa: taxonomy, diversity and ecology, symbioses and viruses". Open Biology. 11: 200407. doi:10.1098/RSOB.200407. ISSN 2046-2441. PMC 8061765. PMID 33715388. Wikidata Q125548575.
  13. ^ Gordon Lax; Anna Cho; Patrick J. Keeling (30 March 2023). "Phylogenomics of novel ploeotid taxa contribute to the backbone of the euglenid tree". Journal of Eukaryotic Microbiology. 70 (4). doi:10.1111/JEU.12973. ISSN 1066-5234. Wikidata Q123348233.
  14. ^ Lax G, Keeling PJ (2023). "Molecular phylogenetics of sessile Dolium sedentarium, a petalomonad euglenid". The Journal of Eukaryotic Microbiology. 70 (e12991): e12991. doi:10.1111/jeu.12991. PMID 37424051.
  15. ^ Gordon Lax; Won Je Lee; Yana Eglit; Alastair Geoffrey Brinley Simpson (23 March 2019). "Ploeotids Represent Much of the Phylogenetic Diversity of Euglenids". Protist. 170 (2): 233–257. doi:10.1016/J.PROTIS.2019.03.001. ISSN 1434-4610. PMID 31102975. Wikidata Q92132357.
  16. ^ Thomas Cavalier-Smith; Ema E Chao; Keith Vickerman (28 August 2016). "New phagotrophic euglenoid species (new genus Decastava; Scytomonas saepesedens; Entosiphon oblongum), Hsp90 introns, and putative euglenoid Hsp90 pre-mRNA insertional editing". European Journal of Protistology. 56: 147–170. doi:10.1016/J.EJOP.2016.08.002. ISSN 0932-4739. PMID 27718409. Wikidata Q31135651.
  17. ^ Thomas Cavalier-Smith (15 September 2016). "Higher classification and phylogeny of Euglenozoa". European Journal of Protistology. 56: 250–276. doi:10.1016/J.EJOP.2016.09.003. ISSN 0932-4739. PMID 27889663. Wikidata Q39151632.
  18. ^ Leander, Brian Scott (May 2001). "Evolutionary morphology of the euglenid pellicle". University of Georgia Theses and Dissertations.
  19. ^ Busse, Ingo; Preisfeld, Angelika (14 April 2018). "Systematics of primary osmotrophic euglenids: a molecular approach to the phylogeny of Distigma and Astasia (Euglenozoa)". International Journal of Systematic and Evolutionary Microbiology. 53 (2): 617–624. doi:10.1099/ijs.0.02295-0. PMID 12710635.
  20. ^ "Euglenida". tolweb.org. Retrieved 2017-03-30.
  21. ^ "Reproduction". Euglena. Retrieved 2017-03-31.

Bibliography

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