Biology:Hindgut fermentation

From HandWiki
Revision as of 07:07, 12 February 2024 by AstroAI (talk | contribs) (change)
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Short description: Digestive process seen in herbivores

Hindgut fermentation is a digestive process seen in monogastric herbivores, animals with a simple, single-chambered stomach. Cellulose is digested with the aid of symbiotic bacteria.[1] The microbial fermentation occurs in the digestive organs that follow the small intestine: the large intestine and cecum. Examples of hindgut fermenters include proboscideans and large odd-toed ungulates such as horses and rhinos, as well as small animals such as rodents, rabbits and koalas.[2] In contrast, foregut fermentation is the form of cellulose digestion seen in ruminants such as cattle which have a four-chambered stomach,[3] as well as in sloths, macropodids, some monkeys, and one bird, the hoatzin.[4]

Cecum

Hindgut fermenters generally have a cecum and large intestine that are much larger and more complex than those of a foregut or midgut fermenter.[1] Research on small cecum fermenters such as flying squirrels, rabbits and lemurs has revealed these mammals to have a GI tract about 10-13 times the length of their body.[5] This is due to the high intake of fiber and other hard to digest compounds that are characteristic to the diet of monogastric herbivores. Unlike in foregut fermenters, the cecum is located after the stomach and small intestine in monogastric animals, which limits the amount of further digestion or absorption that can occur after the food is fermented.[6]

Large intestine

In smaller hindgut fermenters of the order Lagomorpha (rabbits, hares, and pikas), cecotropes formed in the cecum are passed through the large intestine and subsequently reingested to allow another opportunity to absorb nutrients. Cecotropes are surrounded by a layer of mucus which protects them from stomach acid but which does not inhibit nutrient absorption in the small intestine.[6] Coprophagy is also practiced by some rodents, such as the capybara, guinea pig and related species,[7] and by the marsupial common ringtail possum.[8] This process is also beneficial in allowing for restoration of the microflora population, or gut flora. These microbes are found in the digestive organs of living creatures and can act as protective agents that strengthen the immune system. Small indgut fermenters have the ability to expel their microflora, which is useful during the acts of hibernation, estivation and torpor.

Efficiency

While foregut fermentation is generally considered more efficient, and monogastric animals cannot digest cellulose as efficiently as ruminants,[1] hindgut fermentation allows animals to consume small amounts of low-quality forage all day long and thus survive in conditions where ruminants might not be able to obtain nutrition adequate for their needs. Hindgut fermenters are able to extract more nutrition out of small quantities of feed.[9] The large hind-gut fermenters are bulk feeders: they ingest large quantities of low-nutrient food, which they process more rapidly than would be possible for a similarly sized foregut fermenter. The main food in that category is grass, and grassland grazers move over long distances to take advantage of the growth phases of grass in different regions.[10]

Speed

The ability to process food more rapidly than foregut fermenters gives hindgut fermenters an advantage at very large body size, as they are able to accommodate significantly larger food intakes. The largest extant and prehistoric megaherbivores, elephants and indricotheres (a type of rhino), respectively, have been hindgut fermenters.[11] Study of the rates of evolution of larger maximum body mass in different terrestrial mammalian groups has shown that the fastest growth in body mass over time occurred in hindgut fermenters (perissodactyls, rodents and proboscids).[12]

Types

Hindgut fermenters are subdivided into two groups based on the relative size of various digestive organs in relationship to the rest of the system: colonic fermenters tend to be larger species such as horses, and cecal fermenters are smaller animals such as rabbits and rodents.[2] However, in spite of the terminology, colonic fermenters such as horses make extensive use of the cecum to break down cellulose.[13][14] Also, colonic fermenters typically have a proportionally longer large intestine than small intestine, whereas cecal fermenters have a considerably enlarged cecum compared to the rest of the digestive tract.

Insects

In addition to mammals, several insects are also hindgut fermenters, the best studied of which are the termites, which are characterised by an enlarged "paunch" of the hindgut that also houses the bulk of the gut microbiota.[15] Digestion of wood particles in lower termites is accomplished inside the phagosomes of gut flagellates, but in the flagellate-free higher termites, this appears to be accomplished by fibre-associated bacteria.[16]

See also

References

  1. 1.0 1.1 1.2 Animal Structure & Function . Sci.waikato.ac.nz. Retrieved on 2011-11-27.
  2. 2.0 2.1 Grant, Kerrin Adaptations in Herbivore Nutrition, July 30, 2010. Lafebervet.com. Retrieved on 2017-10-16.
  3. Hindgut versus Foregut Fermenters. Vcebiology.edublogs.org (2011-04-30). Retrieved on 2011-11-27.
  4. Grajal, A.; Strahl, S. D.; Parra, R.; Dominguez, M. G.; Neher, A. (1989). "Foregut fermentation in the Hoatzin, a Neotropical leaf-eating bird". Science 245 (4923): 1236–1238. doi:10.1126/science.245.4923.1236. PMID 17747887. Bibcode1989Sci...245.1236G. .
  5. Lu, Hsiao-Pei; Yu-bin Wang; Shiao-Wei Huang; Chung-Yen Lin; Martin Wu; Chih-hao Hsieh; Hon-Tsen Yu (10 September 2012). "Metagenomic analysis reveals a functional signature for biomass degradation by cecal microbiota in the leaf-eating flying squirrel (Petaurista alborufus lena)". BMC Genomics. 1 13 (1): 466. doi:10.1186/1471-2164-13-466. PMID 22963241. 
  6. 6.0 6.1 James (14 May 2010). "Comparative Digestion". VetSci. http://vetsci.co.uk/2010/05/14/comparative-digestion/. 
  7. Hirakawa, Hirofumi (2001). "Coprophagy in Leporids and Other Mammalian Herbivores". Mammal Review 31 (1): 61–80. doi:10.1046/j.1365-2907.2001.00079.x. 
  8. Chilcott, M. J.; Hume, I. D. (1985). "Coprophagy and selective retention of fluid digesta: their role in the nutrition of the common ringtail possum, Pseudocheirus peregrinus.". Australian Journal of Zoology 33 (1): 1–15. doi:10.1071/ZO9850001. 
  9. Budiansky, Stephen (1997). The Nature of Horses. Free Press. ISBN 0-684-82768-9. https://archive.org/details/natureofhorsesex00budi. 
  10. van der Made, Jan; Grube, René (2010). "The rhinoceroses from Neumark-Nord and their nutrition". in Meller, Harald (in de, en). Elefantenreich – Eine Fossilwelt in Europa. Halle/Saale. pp. 382–394; see p. 387. http://www.rhinoresourcecenter.com/ref_files/1295058899.pdf. 
  11. Clauss, M.; Frey, R.; Kiefer, B.; Lechner-Doll, M.; Loehlein, W.; Polster, C.; Roessner, G. E.; Streich, W. J. (2003-04-24). "The maximum attainable body size of herbivorous mammals: morphophysiological constraints on foregut, and adaptations of hindgut fermenters". Oecologia 136 (1): 14–27. doi:10.1007/s00442-003-1254-z. PMID 12712314. Bibcode2003Oecol.136...14C. https://www.zora.uzh.ch/id/eprint/2393/2/Oecologia_body_size_2003V.pdf. 
  12. Evans, A. R. (2012-01-30). "The maximum rate of mammal evolution". PNAS 109 (11): 4187–4190. doi:10.1073/pnas.1120774109. PMID 22308461. Bibcode2012PNAS..109.4187E. 
  13. Williams, Carey A. (April 2004), "The Basics of Equine Nutrition", FS 038, The Equine Science Center, Rutgers University, http://www.esc.rutgers.edu/publications/factsheets_nutrition/FS038.htm, retrieved 2017-04-02 
  14. Moore, B. E.; Dehority, B. A. (1993). "Effects of diet and hindgut defaunation on diet digestibility and microbial concentrations in the cecum and colon of the horse.". Journal of Animal Science 71 (12): 3350–3358. doi:10.2527/1993.71123350x. PMID 8294287. 
  15. Brune, A.; Dietrich, C. (2015). "The Gut Microbiota of Termites: Digesting the Diversity in the Light of Ecology and Evolution". Annual Review of Microbiology 69: 145–166. doi:10.1146/annurev-micro-092412-155715. PMID 26195303. 
  16. Mikaelyan, A.; Strassert, J.; Tokuda, G.; Brune, A. (2014). "The fibre-associated cellulolytic bacterial community in the hindgut of wood-feeding higher termites (Nasutitermes spp.)". Environmental Microbiology 16 (9): 2711–2722. doi:10.1111/1462-2920.12425.