Euglena gracilis is a freshwater species of single-celled alga in the genus Euglena. It has secondary chloroplasts, and is a mixotroph able to feed by photosynthesis or phagocytosis. It has a highly flexible cell surface, allowing it to change shape from a thin cell up to 100 μm long to a sphere of approximately 20 μm. Each cell has two flagella, only one of which emerges from the flagellar pocket (reservoir) in the anterior of the cell, and can move by swimming, or by so-called "euglenoid" movement across surfaces. E. gracilis has been used extensively in the laboratory as a model organism, particularly for studying cell biology and biochemistry.[1]

Euglena gracilis
Scientific classification Edit this classification
Domain: Eukaryota
Phylum: Euglenozoa
Class: Euglenida
Clade: Euglenophyceae
Order: Euglenales
Family: Euglenaceae
Genus: Euglena
Species:
E. gracilis
Binomial name
Euglena gracilis
Klebs, 1883

Other areas of their use include studies of photosynthesis, photoreception, and the relationship of molecular structure to the biological function of subcellular particles, among others.[2] Euglena gracilis is the most studied member of the Euglenaceae.

E. gracilis was discovered as an effective bioindicator for phenol pollution in freshwater ecosystems and drainage.[3] Their brief generating duration and particular biological reactions make it optimal for measuring phenol concentrations in the natural environment.[3] The reported morphological abnormalities and unusual cell division reveal important information about the biological impacts of phenol on marine organisms. Using E. gracilis as a bioindicator can determine the level of phenol exposure in marine ecosystems and adopt appropriate mitigation actions to protect water quality and biodiversity.

Taxonomy

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Euglena gracilis

A morphological and molecular study of the Euglenozoa put E. gracilis in close kinship with the species Khawkinea quartana, with Peranema trichophorum basal to both,[4] although a later molecular analysis showed that E. gracilis was more closely related to Astasia longa than to certain other species recognized as Euglena.

The transcriptome of E. gracilis was sequenced, showing that E. gracilis has many unclassified genes which can make complex carbohydrates and natural products.[5][6]

Morphology

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The morphology is characterized by a spindle-shaped cell with a length ranging from 40 to 150 micrometers. The cell contains a pellicle which is a flexible outer covering made up of proteinaceous strips called pellicular strips. This pellicle provides shape and structure to the cell. The movement of the E. gracilis is primarily achieved by its flagellum that emerges from a flagellar pocket. It has forward and backwards movement, as well as changes in its direction. Additionally, E. gracilis contains a light-sensitive eyespot, or stigma, which enables it to exhibit phototaxis by moving towards light sources for photosynthesis. The cell also possesses a contractile vacuole responsible for osmoregulation, helping maintain proper water balance within the cell. [7]

Energy storage

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Paramylon is a unique storage polysaccharide found in Euglena gracilis, serving as a reserve carbohydrate for energy storage. Structurally, paramylon is a linear β-1,3-glucan, distinct from the storage polysaccharide starch of plants and some species of alga.[8]

The origin of the middle plastid membrane

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The plastids contain three membranes. These membranes are an evolutionary vestige of the secondary endosymbiotic event that occurred between a phagotrophic eukaryovorous euglenid and a Pyramimonas-related green alga.[9] The plastids of Euglena are unusual since most secondary plastids are surrounded by four envelopes. The two inner ones are derived from the inner and outer chloroplast envelopes of the primary plastid of the alga that was taken up during the symbiotic event. The two outermost are derived from the plasma membrane of the alga (third) and the phagosome of the host (fourth).[9]

Biofuels

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Microalgae are considered a possible source for biodiesel production due to their high lipid content. Its lipids may be suitable for biodiesel production due to their saturation, such as fatty acyl-CoA reductase and wax synthase. These ratios vary on environmental and cultivation conditions.[8]

As food

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In industry, Euglena gracilis is genetically engineered to produce a flour used to manufacture various protein-rich, non-animal foods.[10]

References

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  1. ^ Russell, A. G.; Watanabe, Y; Charette, JM; Gray, MW (2005). "Unusual features of fibrillarin cDNA and gene structure in Euglena gracilis: Evolutionary conservation of core proteins and structural predictions for methylation-guide box C/D snoRNPs throughout the domain Eucarya". Nucleic Acids Research. 33 (9): 2781–91. doi:10.1093/nar/gki574. PMC 1126904. PMID 15894796.
  2. ^ Wacker, Warren E. C. (1962-09-29). "Euglena: An Experimental Organism for Biochemical and Biophysical Studies". JAMA: The Journal of the American Medical Association. 181 (13): 1150. doi:10.1001/jama.1962.03050390052015. ISSN 0098-7484.
  3. ^ a b Lukáčová, Alexandra; Lihanová, Diana; Beck, Terézia; Alberty, Roman; Vešelényiová, Dominika; Krajčovič, Juraj; Vesteg, Matej (2023-08-12). "The Influence of Phenol on the Growth, Morphology and Cell Division of Euglena gracilis". Life. 13 (8). MDPI AG: 1734. doi:10.3390/life13081734. ISSN 2075-1729. PMC 10455851. PMID 37629591.
  4. ^ Montegut-Felkner, Ann E.; Triemer, Richard E. (1997). "Phylogenetic Relationships of Selected Euglenoid Genera Based on Morphological and Molecular Data". Journal of Phycology. 33 (3): 512–9. Bibcode:1997JPcgy..33..512M. doi:10.1111/j.0022-3646.1997.00512.x. S2CID 83579360.
  5. ^ "The potential in your pond". ScienceDaily. August 14, 2015. Retrieved December 14, 2023.
  6. ^ O'Neill, Ellis C.; Trick, Martin; Hill, Lionel; Rejzek, Martin; Dusi, Renata G.; Hamilton, Christopher J.; Zimba, Paul V.; Henrissat, Bernard; Field, Robert A. (2015). "The transcriptome of Euglena gracilis reveals unexpected metabolic capabilities for carbohydrate and natural product biochemistry". Molecular BioSystems. 11 (10): 2808–21. doi:10.1039/C5MB00319A. PMID 26289754.
  7. ^ Barsanti, Laura; Gualtieri, Paolo (2020-01-01), Konur, Ozcan (ed.), "Chapter 4 - Anatomy of Euglena gracilis", Handbook of Algal Science, Technology and Medicine, Academic Press, pp. 61–70, ISBN 978-0-12-818305-2, retrieved 2023-12-15
  8. ^ a b Gissibl, Alexander; Sun, Angela; Care, Andrew; Nevalainen, Helena; Sunna, Anwar (2019). "Bioproducts From Euglena gracilis: Synthesis and Applications". Frontiers in Bioengineering and Biotechnology. 7: 108. doi:10.3389/fbioe.2019.00108. ISSN 2296-4185. PMC 6530250. PMID 31157220.
  9. ^ a b Minorsky, Peter (2020-12-10). "On the Inside: The Origins of Euglena gracilis's Middle Plastid Envelope Membrane". Plantae. Retrieved 2023-12-15.
  10. ^ Harada R, Nomura T, Yamada K, Mochida K, Suzuki K (2020). "Genetic Engineering Strategies for Euglena gracilis and Its Industrial Contribution to Sustainable Development Goals: A Review". Frontiers in Bioengineering and Biotechnology. 8: 790. doi:10.3389/fbioe.2020.00790. PMC 7371780. PMID 32760709.
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