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Digestion in Ruminants. Ruminants. 2.8 billion domesticated ruminants ungulates Pregastric fermentation 4 compartment stomach reticulum rumen omasum abomasum. Reticulum. Honeycomb lining Formation of food bolus Regurgitation initiated here Collects hardware (nails, wire). Rumen.
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Ruminants • 2.8 billion domesticated ruminants • ungulates • Pregastric fermentation • 4 compartment stomach • reticulum • rumen • omasum • abomasum
Reticulum • Honeycomb lining • Formation of food bolus • Regurgitation initiated here • Collects hardware (nails, wire)
Rumen • Digestion and fermentation vat • Contains anaerobic microbes • Papillae lining • Absorption of VFA
Omasum • Laminae/manyply lining • muscular folds • Reduces particle size • Absorption of water • Absorption of VFA
Abomasum • True gastric stomach • Proteolytic enzymes • Gastric digestion • Decreased pH from 6 to 2.5 • Denatures proteins • Kills bacteria and pathogens • Dissolves minerals (e.g., Ca3(PO4)2)
Rumen Fermentation • World’s largest commercial fermentation • 100 billion liters in domestic animals • 1010 to 1012 cells/mL • 200 liters (50 gallons) in cows
Ruminants • Continuous culture fermenters • input and output • Lignocellulosic substrates used • 8 x 1015 mouths to feed
Rumen Environment • pH 6.0 – 7.0 • Highly reduced • 10 – 15% dry matter • 39°C • 260 – 280 mOsm
Rumen Microbes • Bacteria • >200 species with many subspecies • 25 species at concentrations >107/mL • 1010 to 1012 cells/mL • 99.5% obligate anaerobes
Rumen Microbes • Protozoa • Large (20-200 microns) unicellular organisms • Prey on bacteria • Numbers affected by diet
Rumen Microbes • Fungi • Known only for about 20 years • Numbers usually low • Digest recalcitrant fiber
Symbiotic Relationship • Microbes provide to the ruminant • Digestion of cellulose and hemicellulose • Provision of high quality protein • Provision of B vitamins • Detoxification of toxic compounds
Microbes to Ruminants • Digestion of cellulose and hemicellulose • Cellulases are all of microbial origin • Without microbes, ruminants would not be able to use forage crops such as pasture, hay or silage
Microbes to Ruminants • Provision of high quality protein • 50-80% of absorbed N is from microbes • Improved microbial efficiency will provide more microbial protein • Can get over 3 kg of microbial protein per day • High biological value protein source • Amino acid pattern is very similar to that required by the ruminant animal
Microbes to Ruminants • Provision of B vitamins • Meets the ruminant’s requirements under most conditions • Niacin may be beneficial in early lactation dairy cows
Microbes to Ruminants • Detoxification of toxic compounds • Example • Mimosine in Leucaena causes problems • poor growth, reproduction and hair loss • Hawaiian ruminants, but not those from Australia, have microbes that degrade mimosine so Leucaena could be fed • Transferred rumen fluid to Australia • Inoculated rumen • Fed Leucaena
Symbiotic Relationship • Ruminants provide to microbes • Housing • Garbage removal • Nutrients • Neutral environment
Ruminants to Microbes • Housing • Reliable heat • 39 ± 2°C • Guaranteed for 18 to 96 hours depending on diet and type of animal • Straw-fed water buffalo – longest rumen residence time • Small selective browsers (mouse deer or duiker) – shortest time
Ruminants to Microbes • Garbage removal • Absorption of VFA • Energy to ruminant • Eructation • CO2 and CH4 • Passage of indigestible residue and microbes to lower GI tract
Ruminants to Microbes • Nutrients • Animal eats • Saliva provides urea (N source for bacteria)
Ruminants to Microbes • Neutral environment • pH 6.5 to 7.0 • Saliva contains bicarbonate and phosphate buffers • Cows produce up to 46 gallons of saliva daily • Added during eating and rumination • Cow ruminates 10-12 hours/day
Ruminants to Microbes • Neutral environment • If pH 5.7 rather than 6.5 • 50% less microbial synthesis • Rate of carbohydrate use is decreased • More lactate and less acetate is produced • Further downward pH spiral • In concentrate selectors (like deer), parotid salivary glands are 0.3% of body weight
Rumination • 10 – 12 hours/day • Reduces particle size • only small particles leave reticulorumen • Increases surface area for microbial fermentation • Breaks down impervious plant coatings
Bacterial Digestion of Protein • Microbes utilize N, amino acids and peptides for their protein synthesis • Microbes convert dietary proteins into their own proteins • some amino acid conversion occurs so dietary amino acids does not equal amino acids leaving the rumen
Bacterial Digestion of Lipid • Microbial lipases act on triglycerides • Biohydrogenation • Addition of H across double bond to saturate unsaturated fatty acids
Lipolysis + 3H20 + Lipases Esterified Plant Lipid Free Fatty Acids
Biohydrogenation Sheep fed alfalfa hay
Biohydrogenation • Reduction of double bonds • Result: fatty acids that are more saturated with hydrogen Unsaturated Saturated
Biohydrogenation 18:2 converted (%) Time (h) • (adapted from Harfoot et al., 1973)
Biohydrogenation of Linoleic Acid Linoleic acid cis-9, trans-11 CLA trans-11 18:1 18:0 isomerase reductase reductase
Factors that Reduce Microbial Growth • Rapid, dramatic ration changes • Takes 3-4 weeks for microbes to stabilize • Feed restricted amounts of diet • Feed lots of unsaturated fat • Bacteria do not use fat for energy • Inhibit fiber digestion and microbial growth • Different types of fat have different effects
Factors that Reduce Microbial Growth • Feed lots of non-structural carbohydrate to lower rumen pH (rumen acidosis) • Slug feeding • Feed barley or wheat • To prevent acidosis, must balance lactate users and producers
Factors that Maximize Microbial Growth • Maximum dry matter intake • Balanced carbohydrate and protein fractions • Bacteria need both energy and N for amino acid synthesis • Gradual ration changes • Maintain rumen pH • Keep feed available at all times
Why Worry about Rumen Microbes? • Microbes make ruminants less efficient • Aerobic fermentation • Anaerobic fermentation Glucose + O2 ATP + CO2 + H2O Glucose acetic acid + propionic acid + butyric acid + CO2 + H2O + CH4 + Heat