Mucilage Explained

Mucilage is a thick gluey substance produced by nearly all plants and some microorganisms. These microorganisms include protists which use it for their locomotion. The direction of their movement is always opposite to that of the secretion of mucilage.[1] It is a polar glycoprotein and an exopolysaccharide. Mucilage in plants plays a role in the storage of water and food, seed germination, and thickening membranes. Cacti (and other succulents) and flax seeds are especially rich sources of mucilage.[2]

Occurrence

Exopolysaccharides are the most stabilising factor for microaggregates and are widely distributed in soils. Therefore, exopolysaccharide-producing "soil algae" play a vital role in the ecology of the world's soils. The substance covers the outside of, for example, unicellular or filamentous green algae and cyanobacteria. Amongst the green algae especially, the group Volvocales are known to produce exopolysaccharides at a certain point in their life cycle. It occurs in almost all plants, but usually in small amounts. It is frequently associated with substances like tannins and alkaloids.[3]

Mucilage has a unique purpose in some carnivorous plants. The plant genera Drosera (sundews), Pinguicula, and others have leaves studded with mucilage-secreting glands, and use a "flypaper trap" to capture insects.[4]

Human uses

Mucilage is edible. It is used in medicine as it relieves irritation of mucous membranes by forming a protective film. It is known to act as a soluble, or viscous, dietary fiber that thickens the fecal mass, an example being the consumption of fiber supplements containing psyllium seed husks.[5]

Traditionally, marshmallows were made from the extract of the mucilaginous root of the marshmallow plant (Althaea officinalis). The inner bark of the slippery elm (Ulmus rubra), a North American tree species, has long been used as a demulcent and cough medicine, and is still produced commercially for that purpose.[6]

Mucilage mixed with water has been used as a glue, especially for bonding paper items such as labels, postage stamps, and envelope flaps.[7] Differing types and varying strengths of mucilage can also be used for other adhesive applications, including gluing labels to metal cans, wood to china, and leather to pasteboard.[8] During the fermentation of nattō soybeans, extracellular enzymes produced by the bacterium Bacillus natto react with soybean sugars to produce mucilage. The amount and viscosity of the mucilage are important nattō characteristics, contributing to nattō's unique taste and smell.

The mucilage of two kinds of insectivorous plants, sundew (Drosera)[9] and butterwort (Pinguicula),[10] is used for the traditional production of a variant of the yogurt-like Swedish dairy product called filmjölk.[11] [12]

Ecological implications for plants

The presence of mucilage in seeds affects important ecological processes in some plant species, such as tolerance of water stress, competition via allelopathy, or facilitation of germination through attachment to soil particles.[13] [14] [15] Some authors have also suggested a role of seed mucilage in protecting DNA material from irradiation damage.[16] The amount of mucilage produced per seed has been shown to vary across the distribution range of a species, in relation with local environmental conditions of the populations.[17]

A variety of maize grows aerial roots that produce a sweet mucus. The Sierra Mixe is a tall variety that survives in poor soils without fertilizer in Oaxaca, Mexico, and the mucilage has been shown to support nitrogen fixation through bacteria that thrive in its high-sugar, low-oxygen environment.[18]

Plant sources

The following plant and algae species are known to contain far greater concentrations of mucilage than typical:

External links

Notes and References

  1. News: Modes of Locomotion in Protists: 5 Modes. 2016-09-06. Biology Discussion. 2017-10-26. en-US. live. https://web.archive.org/web/20171224225039/http://www.biologydiscussion.com/protists/modes-of-locomotion-in-protists-5-modes/52116. 2017-12-24.
  2. Web site: Mucilage cell, cactus. www.sbs.utexas.edu. 2017-10-26. live. https://web.archive.org/web/20170615085638/http://www.sbs.utexas.edu/mauseth/weblab/webchap9secretory/9.1-2.htm. 2017-06-15.
  3. Book: Paul . Eldon A. . 2006 . Soil Microbiology, Ecology and Biochemistry . Academic Press . 3rd . 33 . 9780080475141 . live . https://web.archive.org/web/20171224225039/https://books.google.com/books?id=gk1KRzYtxfYC&printsec=frontcover . 2017-12-24 .
  4. Web site: Carnivorous Plant Trapping Mechanisms. International Carnivorous Plant Society. 29 March 2016. live. https://web.archive.org/web/20160406144219/http://www.carnivorousplants.org/cp/TrappingMechanisms.php. 6 April 2016.
  5. Book: Institute of Medicine . Dietary Reference Intakes: Proposed Definition of Dietary Fiber . 2001 . National Academy Press. Washington, D.C. . 978-0-309-07564-0 . 19 .
  6. Web site: Slippery Elm . University of Maryland Medical Center . live . https://web.archive.org/web/20151117025939/https://umm.edu/health/medical/altmed/herb/slippery-elm . 2015-11-17.
  7. News: Spitzenberger . Ray . 23 August 2007 . Glue, Paste or Mucilage: Know the Difference? . East Bernard Express . East Bernard, TX . 29 March 2016.
  8. Book: Dawidowsky, Ferdinand . Glue, Gelatine, Animal Charcoal, Phosphorus, Cements, Pastes, and Mucilage . 1905 . Henry Carey Baird & Co. . 978-1-113-00611-0 . 1.
  9. Web site: Drosera L. . Plants of the World Online . 2023-03-16 . Royal Botanic Gardens, Kew . English .
  10. 2002 . Filmjölk från Linnés tid . Verumjournalen . 2002 . 10 . sv . PDF . 2007-07-18.
  11. Book: Östman, Elisabeth . Iduns kokbok . https://runeberg.org/idunskok/0165.html . 2007-07-18 . Aktiebolaget Ljus, Isaac Marcus' Boktryckeriaktiebolag . Stockholm . sv . Recept på filmjölk, filbunke och långmjölk . 161 . 1911 . live . https://web.archive.org/web/20081029081321/http://runeberg.org/idunskok/0165.html . 2008-10-29.
  12. Web site: Vad gjorde man med mjölken? . 2007-08-05 . Järnriket Gästrikland, Länsmuseet Gävleborg . sv . https://web.archive.org/web/20070322031437/http://www.jarnriket.com/bergsman/ramdokument/21-051_mjoelken.htm . 2007-03-22.
  13. Harper. J. L.. Benton. R. A.. 1966-01-01. The Behaviour of Seeds in Soil: II. The Germination of Seeds on the Surface of a Water Supplying Substrate. 2257664. Journal of Ecology. 54. 1. 151–166. 10.2307/2257664. 1966JEcol..54..151H .
  14. Hasegawa. K.. Mizutani. J.. Kosemura. S.. Yamamura. S.. 1992-10-01. Isolation and identification of lepidimoide, a new allelopathic substance from mucilage of germinated cress seeds. Plant Physiology. 100. 2. 1059–1061. 0032-0889. 1075667. 16653018. 10.1104/pp.100.2.1059.
  15. Lu. Juanjuan. Tan. Dunyan. Baskin. Jerry M.. Baskin. Carol C.. 2010-06-01. Fruit and seed heteromorphism in the cold desert annual ephemeral Diptychocarpus strictus (Brassicaceae) and possible adaptive significance. Annals of Botany. 105. 6. 999–1014. 10.1093/aob/mcq041. 0305-7364. 2876001. 20348559.
  16. Yang. Xuejun. Zhang. Wenhao. Dong. Ming. Boubriak. Ivan. Huang. Zhenying. 2011-09-02. The Achene Mucilage Hydrated in Desert Dew Assists Seed Cells in Maintaining DNA Integrity: Adaptive Strategy of Desert Plant Artemisia sphaerocephala . PLOS ONE . 6 . 9 . e24346 . 10.1371/journal.pone.0024346 . 1932-6203 . 3166310. 21912689 . 2011PLoSO...624346Y. free.
  17. Villellas . J. . García . M. B. . 2013-09-01 . The role of the tolerance–fecundity trade-off in maintaining intraspecific seed trait variation in a widespread dimorphic herb . Plant Biology . en . 15 . 5 . 899–909 . 10.1111/j.1438-8677.2012.00684.x . 23126286 . 2013PlBio..15..899V . 1438-8677 . 10261/87756 . free .
  18. 0037-7333 . . The Corn of the Future Is Hundreds of Years Old and Makes Its Own Mucus . Jason . Daley . 10 August 2018.