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RUDP and RDP.pptx rumin degradable protein
1. Digestion & Utilization of RDP,RUP and NPN substances in
ruminants
Submitted by: Sarmad Jamshaid
Reg.# F23BNUTR3M01002
M.Phil. Animal Nutrition 2nd semester
Course: RUM NUTR 32204
Submitted to: Prof. Dr. Nasir Ali Tauqeer
2. Introduction
Protein is important for ruminants.
Growth and development
Reproduction
Milk production
Rumen microbial health
Enzyme functions
Ruminant protein digestion differs from mono-gastric animals, with the
rumen being a specialized foregut where microbial fermentation is pivotal
for protein breakdown and utilization.
4. Fractions of dietary protein
• Rumen degradable Protein (RDP)
• Rumen undegradable protein (UDN)
• Rumen Degradable Protein (RDP) is the fraction of Crude Protein (CP)
consumed which is broken down by rumen microbes.
• And remaining protein which reaches the small intestine without
degradation called as Rumen undegradable protein (UDN).
5.
6. Digestion of Rumen degradable Protein (RDP)
• Rumen degradable Protein (RDP) hydrolysed to peptides and amino
acids by rumen microorganisms,
• But some amino acids are degraded further, to organic acids,
ammonia and carbon dioxide.
• The main proteolytic organisms are Prevotella ruminicola,
Peptostreptococci species and the protozoa.
1- Hydrolysis of peptide bonds to produce peptides and amino acids.
2- Deamination and degradation of amino acids.
7. • The ammonia produced due those processes , together with some
small peptides and free amino acids, is utilised by the rumen
organisms to synthesise microbial proteins.
• Some of the microbial protein is broken down in the rumen and its
nitrogen is recycled (i.e. taken up by microorganisms).
• The NRC (2001) suggests that maximum milk and milk protein
yields occur when RDP is 9.5-10.5% of diet dry matter.
8. • An important feature of the formation of microbial protein is that bacteria are
capable of synthesizing indispensable (lysine, Methionine, threonine and
tryptophan) as well as dispensable amino acids (glutamine and serine).
• The ammonia in rumen liquor is the key intermediate in microbial
degradation and synthesis of protein.
• Estimates of the optimum concentration of ammonia in rumen liquor vary widely,
from 85 mg/L to over 300 mg/L ( Gumilar et al. 2018)
9. Limitations of RDP
• Ammonia : Excessive intake of RDP can lead to ammonia toxicity and
nitrogen loss through urinary excretion.
• Supplementation frequency: According to Bohnert et al. (2002) DM
digestibility decrease with increase in RDP from daily to every 6 days.
• Fiber digestibility: There is negative correlation between NDF, ADF and
RDP. High content in diet will decrease RDP and increase RUP.
10. Factors Affecting Ruminal Protein Degradation
Chemical Nature of the proteins
•Solubility – More soluble proteins degraded faster some soluble proteins not
extensively degraded
Egg ovalbumin, serum proteins
• 3-dimensional structure – Affects solubility & availability
• Chemical bonding
Disulfide bonds – Reduces degradation
11. • Physical barriers
• Cell walls of plants
• Cross linking of peptide chains – Reduces degradation
E.g. Aldehydes, Tannins
• Feed intake
• Rate of passage – Time proteins remain in the rumen
• Feed processing
• Rate of passage (conditioning time 18-20 sec)
• Heat damage – Complexes with carbohydrates
12. Rumen undegradable protein (RUP) digestion
• Rumen undegradable protein (UDN) is also called bypass protein or
escaped protein or rumen undegradable protein (RUP).
• It is the portion of intake protein that escapes rumen degradation and is
digested directly in the small intestine.
• About 80 to 85 % of the microbial bacterial protein or true protein that
flows out of the rumen is digested in the small intestine and it is expressed
as a percentage of crude protein (CP).
13.
14. Protein digestion in the small intestine
• The nitrogen entering the duodenum is a combination of microbial protein,
undegraded protein and endogenous protein.
• Nitrogen entering the small intestine from the stomach can range from 30-
100% microbial protein and 0-70% undegraded protein.
• Digestion of protein in the abomasum and the small intestine in ruminants is
similar to that in monogastric animals.
• The digestion of protein in the abomasum is carried out mainly by pepsin in a
very acidic environment (pH 2).
15. Absorption of amino acids and peptides
• The most active site of amino acid and peptide absorption is the mid
to lower ileum.
• There is a preferential absorption of essential over non-essential
amino acids from digesta flowing through the small intestine.
• For example, absorption of lysine and methionine is higher than
the absorption of glutamine and glycine.
16. Determination of RUP by flowrate digesta method
In situ Nylon bag technique (whole cotton seed meal and palm meal)
In vitro un degradable protein measurement (Kjeldahl method)
17. Sources of Bypass Protein
Naturally Protected Proteins (Fish meal, blood meal and feather meal)
Heat Treatment (Maillard reactions)
Chemical Treatment (Formaldehyde, lignosulfate)
Esophageal Groove (For young one, liquid protein)
Post Rumen Infusion (Fistula)
Encapsulation of Proteins (Vitamins, minerals and probiotics)
Amino Acids Analogs (Methionine hydroxyl)
Lowering Ruminal Protease Activity
Decreasing Retention Time in Rumen
18. Formaldehyde Treatment
• Formaldehyde treatment of high quality proteins results in the formation
of cross links with amino group.
• It makes protein less susceptible to microbial attack (CzerKawski, 1986)
• These are highly stable in the near pH of rumen but are readily
hydrolyzed in acidic pH of lower digestive tract.
20. Importance of Bypass Protein
• Required for medium and high lactating and growing animals mainly
in early lactation.
• Provision of first limiting amino acids
• Increase in Milk production by 10-15 %.
• Good increase in live weight gain of meat purpose animals. Exposes
essential and limiting amino acids directly to Intestine. Reduces Milk
Production cost.
21. Why Limit High RUP Proteins in Lactating Cows
• Animal byproducts tend to reduce feed intake palatability decreased feed
intake reduces microbial protein synthesis
• Plant byproducts may have poor amino acid balance, corn proteins
deficient in lysine.
• Quality of RUP proteins can be variable
• Protein requirements may have been met
• First limiting amino acid might not be increased
• Overestimation of degradation of other supplemental proteins.
22. Comparison of Degradable and Un-degradable Protein
Feature Degradable Protein Undegradable Protein
Degradation site Rumen Small intestine
Degradation
products
Ammonia and amino acids Amino acids
Utilization Microbial protein synthesis Direct amino acid supply
Benefits High-quality protein source Essential amino acids
Limitations Ammonia toxicity, nitrogen
loss
Reduced microbial protein synthesis
23. Non-Protein Nitrogenous Substances (NPN)
• NPN are nitrogen-containing compounds that are not protein.
• NPN sources
• Urea
• Ammonia (NH3)
• Nitrates (NO3)
• young grass
• silage
• immature root crop
24. • Microbial protein synthesis
• Reduce the need for protein supplementation, especially when dietary
protein sources are expensive or limited
• supporting milk production
Limitations
• Rumen microbes have limited capacity to utilize NPN, and excessive
intake can lead to ammonia toxicity and environmental pollution.
Benefits of NPN
25. Optimizing Protein utilization
To optimize protein utilization in ruminants, it is crucial to:
• Balance dietary protein sources to provide both degradable and un-
degradable protein
• Maintain a healthy rumen environment for efficient microbial
protein synthesis
• Consider animal factors and adjust protein intake accordingly
• Utilize proper feed processing and supplementation strategies
26. Conclusion
• Proper understanding of degradable and un-degradable protein
and NPN is essential for efficient animal nutrition.
• Feeding strategies should be tailored to the specific needs of
the animal and production system.
• Balancing protein sources, quality, and feed processing can
optimize protein utilization and animal performance.