Ruminant

Rough illustration of a ruminant digestive system

Ruminants are mammals that are able to acquire nutrients from plant-based food by fermenting it in a specialized stomach prior to digestion, principally through microbial actions. The process typically requires the fermented ingesta (known as cud) to be regurgitated and chewed again. The process of rechewing the cud to further break down plant matter and stimulate digestion is called rumination.[1][2] The word "ruminant" comes from the Latin ruminare, which means "to chew over again".

The roughly 150 species of ruminants include both domestic and wild species. Ruminating mammals include cattle, goats, sheep, giraffes, yaks, deer, antelope, and some macropods.[3]

Taxonomically, the suborder Ruminantia (also known as ruminants) is a lineage of herbivorous artiodactyls that includes the most advanced and widespread of the world's ungulates.[4] The term 'ruminant' is not synonymous with Ruminantia. Suborder Ruminantia includes many ruminant species, but does not include tylopods and marsupials.[3]

Explanation

Different forms of the stomach in mammals. A, dog; B, Mus decumanus; C, Mus musculus; D, weasel; E, scheme of the ruminant stomach, the arrow with the dotted line showing the course taken by the food; F, human stomach. a, minor curvature; b, major curvature; c, cardiac end G, camel; H, Echidna aculeata. Cma, major curvature; Cmi, minor curvature. I, Bradypus tridactylus Du, duodenum; MB, coecal diverticulum; **, outgrowths of duodenum; †, reticulum; ††, rumen. A (in E and G), abomasum; Ca, cardiac division; O, psalterium; Oe, oesophagus; P, pylorus; R (to the right in E and to the left in G), rumen; R (to the left in E and to the right in G), reticulum; Sc, cardiac division; Sp, pyloric division; WZ, water-cells. (from Wiedersheim's Comparative Anatomy)
Food digestion in the simple stomach of nonruminant animals versus ruminants[5]

The primary difference between a ruminant and nonruminant is that ruminants have a four-compartment stomach. The four parts are the rumen, reticulum, omasum, and abomasum. In the first two chambers, the rumen and the reticulum, the food is mixed with saliva and separates into layers of solid and liquid material. Solids clump together to form the cud or bolus.

The cud is then regurgitated and chewed to completely mix it with saliva and to break down the particle size. Fiber, especially cellulose and hemicellulose, is primarily broken down in these chambers by microbes (mostly bacteria, as well as some protozoa, fungi and yeast) into the three volatile fatty acids (VFAs): acetic acid, propionic acid, and butyric acid. Protein and nonstructural carbohydrate (pectin, sugars, and starches) are also fermented.

Though the rumen and reticulum have different names, they represent the same functional space as digesta can move back and forth between them. Together, these chambers are called the reticulorumen. The degraded digesta, which is now in the lower liquid part of the reticulorumen, then passes into the next chamber, the omasum, where water and many of the inorganic mineral elements are absorbed into the blood stream.

After this, the digesta is moved to the true stomach, the abomasum. The abomasum is the direct equivalent of the monogastric stomach, and digesta is digested here in much the same way. Digesta is finally moved into the small intestine, where the digestion and absorption of nutrients occurs. Microbes produced in the reticulorumen are also digested in the small intestine. Fermentation continues in the large intestine in the same way as in the reticulorumen.

Only small amounts of glucose are absorbed from dietary carbohydrates. Most dietary carbohydrates are fermented into VFAs in the rumen. The glucose needed as energy for the brain and for lactose and milk fat in milk production, as well as other uses, comes from nonsugar sources, such as the VFA propionate, glycerol, lactate, and protein. The VFA propionate is used for around 70% of the glucose and glycogen produced and protein for another 20% (50% under starvation conditions).[6][7]

Classification and taxonomy

Hofmann and Stewart divided ruminants into three major categories based on their feed type and feeding habits: concentrate selectors, intermediate types, and grass/roughage eaters, with the assumption that feeding habits in ruminants cause morphological differences in their digestive systems, including salivary glands, rumen size, and rumen papillae.[8][9]

Also, some mammals are pseudoruminants, which have a three-compartment stomach instead of four like ruminants. The Hippopotamidae (comprising hippopotami) are well-known examples. Pseudoruminants, like traditional ruminants, are foregut fermentors and most ruminate or chew cud. However, their anatomy and method of digestion differs significantly from that of a four-chambered ruminant.[3]

Monogastric herbivores, such as rhinoceroses, horses, and rabbits, are not ruminants, as they have a simple single-chambered stomach. These hindgut fermenters digest cellulose in an enlarged cecum through the reingestion of the cecotrope.

Abundance, distribution, and domestication

Wild ruminants number at least 75 million and are native to all continents except Antarctica. Nearly 90% of all species are found in Eurasia and Africa. Species inhabit a wide range of climates (from tropic to arctic) and habitats (from open plains to forests).[10]

The population of domestic ruminants is greater than 3.5 billion, with cattle, sheep, and goats accounting for about 95% of the total population. Goats were domesticated in the Near East circa 8000 BC. Most other species were domesticated by 2500 BC., either in the Near East or southern Asia.[10]

Ruminant physiology

Ruminating animals have various physiological features that enable them to survive in nature. One feature of ruminants is their continuously growing teeth. During grazing, the silica content in forage causes abrasion of the teeth. This abrasion is compensated for by continuous tooth growth throughout the ruminant's life, as opposed to humans or other nonruminants, whose teeth stop growing after a particular age. Most ruminants do not have upper incisors; instead, they have a thick dental pad to thoroughly chew plant-based food.[11]

Rumen microbiology

Vertebrates lack the ability to hydrolyse the beta [1-4] glycosidic bond of plant cellulose due to the lack of the enzyme cellulase. Thus, ruminants must completely depend on the microbial flora, present in the rumen or hindgut, to digest cellulose. Digestion of food in the rumen is primarily carried out by the rumen microflora, which contains dense populations of several species of bacteria, protozoa, sometimes yeasts and other fungi - 1 ml of rumen is estimated to contain 10-50 billion bacteria and 1 million protozoa, as well as several yeasts and fungi.[12]

Since the environment inside a rumen is anaerobic, most of these microbial species are obligate or facultative anaerobes that can decompose complex plant material, such as cellulose, hemicellulose, starch, and proteins. The hydrolysis of cellulose results in sugars, which are further fermented to acetate, lactate, propionate, butyrate, carbon dioxide, and methane.

As bacteria conduct fermentation in the rumen, they consume about 10% of the carbon, 60% of the phosphorus, and 80% of the nitrogen that the ruminant ingests.[13] To reclaim these nutrients, the ruminant then digests the bacteria in the abomasum. The enzyme lysozyme has adapted to facilitate digestion of bacteria in the ruminant abomasum.[14] Pancreatic ribonuclease also degrades bacterial RNA in the ruminant small intestine as a source of nitrogen.[15]

During grazing, ruminants produce large amounts of saliva - estimates range from 100 to 150 litres of saliva per day for a cow.[16] The role of saliva is to provide ample fluid for rumen fermentation and to act as a buffering agent.[17] Rumen fermentation produces large amounts of organic acids, thus maintaining the appropriate pH of rumen fluids is a critical factor in rumen fermentation. After digesta pass through the rumen, the omasum absorbs excess fluid so that digestive enzymes and acid in the abomasum are not diluted.[18]

Tannin toxicity in ruminant animals

Tannins are phenolic compounds that are commonly found in plants. Found in the leaf, bud, seed, root, and stem tissues, tannins are widely distributed in many different species of plants. Tannins are separated into two classes: hydrolysable tannins and condensed tannins. Depending on their concentration and nature, either class can have adverse or beneficial effects. Tannins can be beneficial, having been shown to increase milk production, wool growth, ovulation rate, and lambing percentage, as well as reducing bloat risk and reducing internal parasite burdens.[19]

Tannins can be toxic to ruminants, in that they precipitate proteins, making them unavailable for digestion, and they inhibit the absorption of nutrients by reducing the populations of proteolytic rumen bacteria.[19][20] Very high levels of tannin intake can produce toxicity that can even cause death.[21] Animals that normally consume tannin-rich plants can develop defensive mechanisms against tannins, such as the strategic deployment of lipids and extracellular polysaccharides that have a high affinity to binding to tannins.[19]

Religious importance

The Law of Moses in the Bible only allowed the eating of mammals that had cloven hooves (i.e. members of the order Artiodactyla) and "that chew the cud",[22] a stipulation preserved to this day in Jewish dietary laws.

Other uses

The verb 'to ruminate' has been extended metaphorically to mean to ponder thoughtfully or to meditate on some topic. Similarly, ideas may be 'chewed on' or 'digested'. 'Chew the (one's) cud' is to reflect or meditate. In psychology, "rumination" refers to a pattern of thinking, and is unrelated to digestive physiology.

Ruminants and climate change

Methane is produced by the bacteria described above within the rumen, and this methane is released to the atmosphere. The rumen is the major site of methane production in ruminants.[23] Methane is a strong greenhouse gas with a global warming potential of 86 compared to CO2 over a 20-year period.[24][25][26]

In 2010, enteric fermentation accounted for 43% of the total greenhouse gas emissions from all agricultural activity in the world.[27] The meat from ruminants has a higher carbon equivalent footprint than other meats or vegetarian sources of protein based on a global meta-analysis of lifecycle assessment studies.[28] Methane production by animals, principally ruminants, is estimated 15-20% global production of methane.[29][30]

See also

References

  1. "Rumination: The process of foregut fermentation".
  2. "Ruminant Digestive System" (PDF).
  3. 1 2 3 Fowler, M.E. (2010). "Medicine and Surgery of Camelids", Ames, Iowa: Wiley-Blackwell. Chapter 1 General Biology and Evolution addresses the fact that camelids (including camels and llamas) are not ruminants, pseudo-ruminants, or modified ruminants.
  4. "Suborder Ruminatia, the Ultimate Ungulate".
  5. Russell,J. B. 2002. Rumen Microbiology and its role In Ruminant Nutrition.
  6. William O. Reece (2005). Functional Anatomy and Physiology of Domestic Animals, pages 357-358 ISBN 978-0-7817-4333-4
  7. Colorado State University, Hypertexts for Biomedical Science: Nutrient Absorption and Utilization in Ruminants
  8. Ditchkoff, S. S. (2000). "A decade since "diversification of ruminants": has our knowledge improved?" (PDF). Oecologia 125: 82–84. doi:10.1007/PL00008894.
  9. Reinhold R Hofmann, 1989."Evolutionary steps of ecophysiological and diversification of ruminants: a comparative view of their digestive system". Oecologia, 78:443-457
  10. 1 2 Hackmann. T. J., and Spain, J. N. 2010."Ruminant ecology and evolution: Perspectives useful to livestock research and production". Journal of Dairy Science, 93:1320-1334
  11. "Dental Anatomy of Ruminants".
  12. "Fermentation Microbiology and Ecology".
  13. name="Callewaert">Callewaert, L.; Michiels, C. W. (2010). "Lysozymes in the animal kingdom". Journal of Biosciences 35 (1): 127–160. doi:10.1007/S12038-010-0015-5.
  14. Irwin, D. M.; Prager, E. M.; Wilson, A. C. (1992). "Evolutionary genetics of ruminant lysozymes". Animal Genetics 23 (3): 193–202. doi:10.1111/j.1365-2052.1992.tb00131.x.
  15. Jermann, T. M.; Opitz, J. G.; Stackhouse, J.; Benner, S. A. (1995). "Reconstructing the evolutionary history of the artiodactyl ribonuclease superfamily". Nature 374 (6517): 57–59. doi:10.1038/374057a0. PMID 7532788.
  16. "Some physical and chemical properties of Bovine saliva which may affect rumen digestion and synthesis". Journal of Dairy Science 32 (2): 123–132. 1949. doi:10.3168/jds.s0022-0302(49)92019-6.
  17. "Rumen Physiology and Rumination".
  18. Clauss, M.; Rossner, G. E. (2014). "Old world ruminant morphophysiology, life history, and fossil record: exploring key innovations of a diversification sequence". Annales Zoologici Fennici 51 (1-2): 80–94. doi:10.5735/086.051.0210.
  19. 1 2 3 B.R Min, et al (2003) The effect of condensed tannins on the nutrition and health of ruminants fed fresh temperate forages: a review Animal Feed Science and Technology 106(1):3-19
  20. Bate-Smith and Swain (1962). "Flavonoid compounds". In Florkin M., Mason H.S. Comparative biochemistry III. New York: Academic Press. pp. 75–809.
  21. "Cornell University Department of Animal Science".
  22. Leviticus 11:3
  23. Asanuma. N., M. Iwamoto, T. Hino. 1999."Effect of the addition of fumarate on methane production by ruminal microorganisms in vitro." J. Dairy Sci.82:780–787
  24. IPCC Fifth Assessment Report, Table 8.7, Chap. 8, p. 8–58 (PDF; 8,0 MB)
  25. Shindell, D. T.; Faluvegi, G.; Koch, D. M.; Schmidt, G. A.; Unger, N.; Bauer, S. E. (2009). "Improved Attribution of Climate Forcing to Emissions". Science 326 (5953): 716–8. Bibcode:2009Sci...326..716S. doi:10.1126/science.1174760. PMID 19900930.
  26. Shindell, D. T.; Faluvegi, G.; Koch, D. M.; Schmidt, G. A.; Unger, N.; Bauer, S. E. (2009). "Improved Attribution of Climate Forcing to Emissions". Science 326 (5953): 716–8. doi:10.1126/science.1174760. PMID 19900930.
  27. Food and Agriculture Organization of the United Nations (2013) "FAO STATISTICAL YEARBOOK 2013 World Food and Agriculture". See data in Table 49.
  28. Ripple, William J.; Pete Smith; Helmut Haberl; Stephen A. Montzka; Clive McAlpine & Douglas H. Boucher. 2014. "Ruminants, climate change and climate policy". Nature Climate Change. Volume 4 No. 1. P 2-5.
  29. Cicerone, R. J., and R. S. Oremland. 1988 "Biogeochemical Aspects of Atmospheric Methane"
  30. Yavitt, J. B. 1992. Methane, biogeochemical cycle. Pages 197–207 in Encyclopedia of Earth System Science, Vol. 3. Acad.Press, London, England.

External links

Wikisource has the text of the 1905 New International Encyclopedia article Ruminant.
This article is issued from Wikipedia - version of the Wednesday, March 09, 2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.