Optimising Rumen Function of Bali Cattle Fed Ration Based on Agriculture By-Products with Supplementation of Multivitamins-Minerals.
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Int. J. Pure App. Biosci. 2 (5): 1-245 (2014)
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RMIT University, Melbourne, Australia
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Bangalore University, Bangalore, India
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National University of Sci. &
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Dr. Mahendra Dhillon
PES College, Bangalore, India
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Sr. Lecturer, Deptt. of Botany, M.B. PG
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Career Point University, Kota, Rajasthan,
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Lzebra Girls College
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Madurai Kamaraj University, Madurai
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University of Florida, USA
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Optimising Rumen Function of Bali Cattle Fed Ration Based on Agriculture
By-Products with Supplementation of Multivitamins-Minerals
Mudita, I M., I W. Wirawan, I G. L. O. Cakra and I. B. G. Partama
Faculty of Animal Husbandry, Udayana University, Denpasar, HP. 081338791005
*Corresponding Author E-mail: muditafapet_unud@yahoo.com
ABSTRACT A research has been carried out to optimize the rumen function and the rumen microbial protein synthesis
in Bali Cattle (Steer). Sixteen Bali cattle were used in this experiment with Completely Randomized Block Designed four treatments and four blocks. The first treatment was ration based on agriculture by
products without supplementation (R0), while the other three treatments were supplemented with 0.075%
(R1), 0.150% (R2) and 0.225% (R3) multivitamins-minerals. The variables of rumen microbial protein
synthesis including urinary exretion of allantoin, purin derivatives absorbsion, rumen microbial protein synthesis and efficiency of rumen microbial protein synthesis, Feed and nutrients degradation on the
rumen, pH, concentration of NH3-N, VFA and amount of protozoa in the rumen fluid were measured in
the experiment. The result showed that rumen microbial protein synthesis and amount of microbial
purines absorbed in suplementation of 0.150% (R2) and 0.225% (R3) multivitamins-minerals were
significant difference (P<0,05) compared with without supplementation (R0) (222.83 and 222.24
gram/day Vs 197.83 gram/day) and (49.45 and 49.35 Vs 44.76 mmol/day), but they were not significantly different with without supplementation on rumen microbial protein synthesis (213.57 gram/day) and on amount of microbial purines absorbed (48.67 mmol/day). Degradable organic matter and Sulfur absorbed in the rumen, amount protozoa, and ruminal pH, concentration of NH3-N, totally VFA and
propionate acids of rumen fluid significantly (P<0,05) increased as well. Increasing supplementation
until 0.15% (R2) multivitamins-minerals were decreased concentration of acetate acid, butirate acid and
methane gas production compare with without supplementation, but increasing until 0.225%
supplementation of multivitamins-minerals (R3) increased concentration of butirate acid and methane gas
production. Moreover, regression analyzed showed that suplementation of multi vitamins-minerals of 0.188% coused maximum rumen microbial protein synthesis of 223,39 gram/day. It was concluded that rumen microbial protein synthesis of Bali cattle given ration based on ammoniated rice straw could be increased as maximum 12.92.%. The level optimal multivitamins-minerals supplementation used in this experiment was 0,188%.
Key words: Agriculture by-products, Bali cattle, Multivitamins-minerals, Microbial Protein Synthesis, Rumen Function.
INTRODUCTION
Optimise the rumen function on degrading fibrous feed such as non-conventional feedstuffs is one of Bali cattle productivity improvement strategy. The products of rumen function such as degraded nutrients in the rumen, metabolic rumen product (VFA, and NH3-N) and microbial biomass are essential nutrients to
meet the nutrient demands of the anaerobic microbes and body tissues of ruminant animals. Microbial protein synthesis in the rumen supllies 40 to 80% of the amino acids absorbed by ruminants13 and the amino acid composition of microbial protein is similar to that of protein in the main animal product such as milk, lamb or beef27.
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ISSN: 2320 – 7051 Int. J. Pure App. Biosci.2 (5): 36-45 (2014)
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Microbial protein synthesized in the reticulo-rumen constitutes almost the only source for protein digestion in the small intestine on the animals given feeds with such low quality fibrous diets like as agricultural by product19. That ways better strategies minded national program to support feed security especially ruminants feed focused on optimise use agriculture waste and agro-industry by products as feed12.
The maximum potential of rumen microbes to produce microbial protein and degraded nutrients in the rumen can be explored only by the provision of high quality diet27, so increasing rumen function in cattle fed ration based on agriculture by product like as rice straw should be focused on strategies for through many problems especially deficiency nutrient and low degistibility at that feed materials. Applied urea ammoniation technologies verified can increased digestible rice straw6,22, in spite of inadequacy micro-nutrients such as minerals Ca, P, Mg, Cu, Zn, Mn, Co, Fe, S, and vitamins A, D3 and E can not increased7.
Multivitamin-minerals supplementation of cattle given ration base on waste is one of the best strategy a farmer can make. That statements founded on vitamins and minerals are important factor to affected the effectivity rumen fermentation and efficiency of microbial protein syntheis14.
Minerals and vitamins supplement to enhance fermentative digestion and microbial growth efficiency in the rumen of cattle on poor quality feed. The macro-minerals (Ca, P and Mg), micro-minerals (Cu, Co, Zn, Mn, Fe and S) and multi-vitamin (especially Vitamin A and E) most important to rumen fermentation activity, feeds degradation, and microbial protein synthesis17. The levels of sulfur and ammonia in rumen fluid which maximize digestibility of fibrous carbohydrates appear to be 1–2 mg S/l and 50–80 mg ammonia N/l respectively, whereas maximum microbial growth efficiency seems to require 4–10 mg S/l and 150–200 mg ammonia N/l respectively17. Even though, Bal and Ozturk3 showed optimise rumen microbial protein synthesis needed 1.6 – 1.9 g Sulfur/kg organic matter digested with N/S ratio 18.5:1. Limited intake of sulfur may restrict rumen activity and microbial protein synthesis when large amounts of non-protein nitrogen are fed to ruminant animals, such as urea or effect given urea ammoniated feeds14. In spite of, given fed with very high sulfur can decreased fed consumsion, respiration stress even death21. Phosphorus is another mineral required for the synthesis of ATP and protein by rumen microbes. Microbial protein synthesis can be limited by an insufficient supply of P for microbial growth. Parakkasi21 describe the mineral zinc (Zn) as components and activator of any enzyme such as deyidrogenase,
peptydase and fosfatase with functions at nucleat acid metabolisms, carbohydrate metabolisms and
protein synthesis. Rumen microbes needed 130-220 mg Zn/kg for optimise microbes growth and yields. Other minerals such as Ca, Mn, Fe, Co and Cu also important for microbial protein synthesis, synthesis of ATP and vitamins B, microbes activities, nutrient degradable14,21. Supply of vitamins A and E important on given ration based on urea ammoniated rice straw because that materials deficience6. Vitamins A and E function for microbes growth especially microbial protein synthesis and energy supply for microbes activities21. Supply of vitamins B-complex also important couse low of supply mineral precursor finding that vitamin such as minerals S or Co on feed material.
This experiment was conducted to determine the best level of multivitamins-minerals supplementation in the fermentation process on ration based on agriculture by-product that could increase of rumen function to degrade nutrients, produce high quality of rumen metabolic product, and increase supply of nutrients for host animal. The research results are expected to give early illustration of science and technology development especially in optimizing the utilization of local resources based on agriculture by-product feedstuffs to support feed security of ruminant production.
MATERIALS AND METHODS Location, Animals, Diet and Experimental Design
A research has been carried out at farm of “Nandi Abian” farmers group association, Abianbase of Gianyar Regency used sixteen Bali cattle mean body weight 244.19 + 33.78 kg. They were kept in feedlot pens (individual concrete pens) on site for duration of the study. This experiment was run for 12 weeks at the farm and continously laboratory experimental for data analysis at Animal Nutrition Laboratory, Faculty of Animal Husbandry and Analytic Laboratory, Udayana University.
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( Mudita, I M. et al Int. J. Pure App. Biosci.2 (5): 36-45 (2014) ISSN: 2320 – 7051
This experiment used a Completely Randomized Block Designed with four treatments and four blocks base on body weight of cattle. The treatment were as follows:
R0 = Basal Ration without suplemented multivitamins-minerals
R1 = R0 were suplemented with 0.075% multivitamins-minerals
R2 = R0 were suplemented with 0.150% multivitamins-minerals
R3 = R0 were suplemented with 0.225% multivitamins-minerals
Basal ration composed by urea ammoniated rice straw and agroindustry by product. Ration and water provided ad libitum. Materials Feedstuffs and Nutrient composition can see at Table 1 and 2.
Table 1. Material Composition of Ration Experimental Feedstuffs Composition Composition Ration (%)
R0 R1 R2 R3
Urea Ammoniated Rice Straw 25.000 25.000 25.000 25.000
Pollard 34.000 33.966 33.932 33.898
Coconut Meal 25.000 24.975 24.950 24.925 Sugarcane 6.000 5.994 5.988 5.982 Coconut Oil 5.000 4.995 4.990 4.985 Limestone (CaCO3) 2.000 1.998 1.996 1.994
Urea 1.000 0.999 0.998 0.997
Salt 2.000 1.998 1.996 1.994
Pignox 0.000 0.075 0.150 0.225
T o t a l 100.000 100.000 100.000 100.000
Table 2. Nutrient Compositions of Ration Experimental
Nutrient1 Ration
R0 R1 R2 R3
Dry Matter (%) 89.420 89.420 89.420 89.420 Organic Matter (%) 83.728 83.663 83.598 83.533 Crude Protein (%) 14.596 14.584 14.572 14.559 Crude Fibre (%) 12.216 12.211 12.207 12.202 Gross Energy (Mkal) 3.888 3.885 3.882 3.878 Ca (%)2 1.348 1.347 1.346 1.345
P (%)2 0.450 0.449 0.449 0.449
S (%)2 0.300 0.303 0.305 0.308
Zn (%)2 0.015 0.016 0.018 0.019 N/S ratio 7.785 7.709 7.634 7.561
Reference: 1) Analysis by Animal Nutrition Laboratory, Faculty of Animal Husbandry, Udayana University, and 2) Analysis by Analitic Laboratory, Udayana University
Data Collection, Sampling Procedure and Analysis
Parameters observed on this research are the variable of rumen microbial protein synthesis (MPS), including urinary exretion of allantoin, purin derivatives absorbsion, rumen microbial protein synthesis and efficiency of rumen microbial protein synthesis (EMPS), feed and nutrients (DM, OM, CF, CP, Ca, P, S and
Zn) degradation/absorbsion on the rumen, pH, concentration of NH3-N, Totally VFA, Partial VFA (Acetate
Acids, Propioniate Acids and Butirate Acids) and amount of protozoa in the rumen fluid
Feed were randomly collected and fecal samples were taken from total collection of individual cattle during the last 7 day of the study. They were analyzed for chemical composition such as DM, ash, CP and CF contents with proxymate analyzed2, and concentrations of minerals Ca (with EDTA method), S (Iodometry method), P and Zn (with Atomic absorption Spectrophotometre/AAS).
At the end total collection period, rumen fluid samples were collected at 4 hours post feeding. Approximately 200 ml of rumen fluid was taken from the middle part of the rumen by using a hand vacum pump.
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) Mudita, I M. et al Int. J. Pure App. Biosci.2 (5): 36-45 (2014) ISSN: 2320 – 7051
Rumen fluid was immediated measure for pH using portable pH meter (HANNA instrument HI 9025). Concentration of NH3-N rumen fluid calculated with using fenolhypocloryte method, Totally Volatile Fatty Acid calculated from concentration of Acetate Acids + Propionate Acids + Butirate Acids. Partial VFA (Acetate, Propionate and butirate) analyses using a high performance liquid chromatography HPLC. The total direct count of protozoa on rumen fluid were counting with using MFS solution at counting chamber/hemocytometer18.
Urine samples were analyzed for allantoin in urine was determined by HPLC as described by Partama22. The amount of microbial purines absorbed (X mmol/day) corresponding to the purine derivates ecreted (Y mmol/day) was calculated based on the relationship derivated by Bowen4.
Y = 0,85 X + 0,190 W0,75
Where: Y is the excretion of purine derivates (mmol/day); X is the microbial purines absorbed (mmol/day), 0.190 W0.75 is contribution of endogenous purine each kg metabolic body weight from Bos indicus
The supply of microbial protein in gram per day was estimated as follows: 70X
Microbial Protein (gram/day) = x 6.25 0.116 x 0.83 x 1000
With X being the absorption of purine derivates in mmol/day, digestibility of microbial purine is 0.83, the N content of purines is 70 mg N/mmol and the ratio of purine-N : total N in mixed rumen microbes is 11.6:100, the convertion factor N to Protein is 6.25
The EMPS which denote the microbial protein supplied to the animal per unit of DOMR was calculated
using the following formula:
MP (g/day)
EMPS (g/1000 DOMR) = x 1000
DOMR (g)
Where : DOMR = DOMI x 0.65 (ARC, 1990 cited by Khampa and Wanapat)16, DOMR = digestible organic matter apparently fermented in the rumen, DOMI = digestible organic matter intake, EMPS = efficiency microbial
protein synthesis
Statistical Analysis
Data Collecting were analyzed by Analysis Variance/ANOVA and continued with Honestly Significant Difference test (HSD-test) if necessary26. Contras polinomial analysis were using for optimum supplemented multivitamins-minerals.
RESULTS AND DISCUSSION Effect on Degradable Nutrients on Rumen
The degradable nutrients and absorbed micro-nutrients (minerals) on rumen are presented in Table 3. Degradable organic matter, Sulfur absorbed and N:S ratio on rumen were affected (P<0.05) by multivitamins-mineral supplementation, while degradable DM, CP, CF, energy and absorbed Ca, P and Zn on rumen were similar in all treatments. Degradable organic matter and S absorbed on rumen were significantly higher (P<0.05) in Bali cattle fed R3 (2078.10 g/d and 8.66 g/d) than in R0 (1846.32 g/d and 6.88
g/d) while N: S ratio on rumen was significantly lower (P<0.05) in Bali cattle fed R3 (6.81) than in R0, R1 or
R2 (7.78; 7.83; 8.26).
Similar degradable nutrients on rumen (except organic matter and S absorbed) were affected by quality of ration given. In general, rate of digestion nutrien on rumen is the major factor controlling the energy available for growth of rumen microbes8. Furthermore, nutrient composition of all ration were similar (Table 2).
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Mudita, I M. et al Int. J. Pure App. Biosci.2 (5): 36-45 (2014) ISSN: 2320 – 7051
Table 3. Influence of Multivitamins-Minerals Supplementation on Nutrient Degradable and Absorbed on Rumen in Bali Cattle
Item Treatment
1
SEM3
R0 R1 R2 R3
- Degradable DM (g/d) 2170.02a2 2325.66a 2417.05a 2422.55a 67.18 - Degradable OM (g/d) 1846.32a 1989.86ab 2070.04ab 2078.10b 52.96 - Degradable CP (g/d) 334.60a 370.70a 379.28a 367.62a 11.73 - Degradable CF (g/d) 219.75a 212.89a 242.05a 219.15a 13.28 - Degradable Energy (Mkal/d) 8.34a 8.85a 9.08a 9.32a 0.27 - Ca Absorbed on Rumen (g/d) 24.64a 25.46a 26.38a 26.63a 2.04 - P Absorbed on Rumen (g/d) 6.34a 5.15a 5.74a 4.61a 0.77 - S Absorbed on Rumen (g/d) 6.88a 7.57ab 7.35ab 8.66b 0.31 - Zn Absorbed on Rumen (g/d) 0.08a 0.13a 0.20a 0.07a 0.04 - N:S ratio on rumen 7.78b 7.83b 8.26b 6.81a 0.13 Note: 1) R0 = Ration without multivitamins-minerals supplementation, R1 = Ration with 0.075% multivitamins-minerals
supplementation, R2 = Ration with 0.150% multivitamins-minerals supplementation, and R3 = Ration with
0.225% multivitamins-minerals supplementation, 2) The same letter in same row is not significantly difference (P>0.05), 3) SEM = Standard Error of the Treatment Means
Significantly degradable organic matter and S absorbed on rumen by supplementation of 0.225% multivitamins-mineral show increasing efectivity of rumen microbes esspecially rumen bacteria where showed by high microbial protein yield were similar with R2 but higher (P<0.05) than R0 (Table 5) and
with lower (quantitative) amount protozoa than R2 (5.80x105 Vs 6.20x105 cells/ml) (Table 4). The low
populated protozoa will increasing populated of bacteria and than increasing rumen degradable nutrients24.
Effect on Amount Protozoa and Rumen Fermentation
Table 4 present amount protozoa and rumen fermentation characteristic. As for amount protozoa, supplementation of 0.150% multivitamins-minerals (R2) increasing amount populations and 60% higher
(P<0.05) than R0 but not significantly than R1 dan R3. Ruminal pH values were found in a range of 6.94 –
7.34 which were significantly different among treatment. The supplementation of R3 resulted in highest
pH, while the supplementation at R0, R1 and R2 were similar among treatment. The supplementation at R1
and R2 also similarly with at R3. Ruminat pH rumen fluid in this study there are in the normally range pH
like as reported by Owen and Goetsch20 (except at R3) are 5.5-7.2 and supplementation of
multivitamins-mineran can as buffer for to prevent reduce pH as effect from increase bacteria population. Furthermore, normally ruminal animals depend on cellulolytic bacteriato digest cellulose, but these bacteria cannot resist the low ruminal pH and an increase in pH gradient leads to anion toxicity25. In addition, most ruminal bacteria prefer pH near neutrality for growth although some species (e.g., Streptococcus bovis
and Prevotella ruminicola) can growth in pH 5 to 6 ranges.
The concentration of ruminal ammonia-N (NH3-N) were significantly higher (P<0.05) in the R3 than in
R0, but not significantly compared with R1 and R2. The supplementation of 0.075% (R1) and 0.150% (R2)
multivitamins-minerals also result high concentration NH3-N but not significantly (P>0.05) compare with
R0 (Table 4). The higher NH3-N concentration associated with high supplementation of
multivitamins-minerals may have been due to increasing effectivity used N component from feeds by rumen microbes. Zinc on multivitamins-minerals have been increasing microbes enzyme activities so that degrable protein process to peptide, olygopeptide, amino acids and ending to ammonia can produce with well1. Furthermore, higher NH3-N concentration associated with high organic matter degradable on rumen may
have been due to the continuous supply of new substrates from soluble fractions especially N-component5.
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Mudita, I M. et al Int. J. Pure App. Biosci.2 (5): 36-45 (2014) ISSN: 2320 – 7051
Table 4. Influence of Multivitamins-Minerals Supplementation on amount protozoa and Rumen Fermentation Characteristic in Bali Cattle
Item Treatment
1
SEM3
R0 R1 R2 R3
Amount Protozoa (x 105 cells/ml) 3.88a2 5.20ab 6.20b 5.80ab 0.51 Ruminal pH 6.94a 6.95a 7.23ab 7.34b 0.09 NH3-N (mM) 5.33a 7.13ab 7.89ab 8.98b 0.66 Total VFA (mM) 114.80a 117.09ab 120.08b 117.24ab 0.89 Partial VFA
Acetate Acid (mM) 73.10b 72.90ab 72.24a 73.05ab 0.19 Propionate Acid (mM) 22.00a 26.70abc 29.40c 22.60ab 1.33 Butirate Acid (mM) 19.69a 17.49a 18.44a 21.58a 1.14 Concentration of Methane (mM) 40.90ab 38.52ab 37.99a 41.67b 0.83 Note:1) R0 = Ration without multivitamins-minerals supplementation, R1 = Ration with 0.075% multivitamins-minerals
supplementation, R2 = Ration with 0.150% multivitamins-minerals supplementation, and R3 = Ration with 0.225% multivitamins-minerals supplementation, 2) The same letter in same row is not significantly difference (P>0.05), 3) SEM = Standard Error of the Treatment Means.
Total and partial VFA concentration were significantly (P<0.05) by supplementation of multivitamins-minerals. Concentration of totally VFA and propionate acids in Bali cattle fed R2 were significantly higher
(P<0.05) than those fed without supplementation of multivitamins-minerals (R0). The higher VFA
concentration associated with high organic matter degradable on rumen (Table 3), protozoa populated (Table 4) and estimation bacteria populated (shown by high microbial protein synthesis, at Table 5). The increasing rumen microbes populated (bacteria and protozoa) as effect the supplementation of multivitamins-minerals have been increasing carbohydrate fermentation to produce VFA. Furthermore, the higher propionate acids concentration on R2 as effect of high organic matter content with low crude
fiber content on ration given (Table 2). The higher total VFA and propionate acids concentration in this study suggested by Hermawan10 were reported supplementation 0.05% ammonium sulfate and 0.03%
pignox have been increasing totally VFA and propionate acids proportion on rumen.
The methane gas concentration on rumen fluid were significantly (P<0.05) by supplementation of multivitamins-minerals on ration based on urea ammoniated rice straw. Concentration of methane gas production in Bali cattle fed R3 were significantly highest than the others treatment, while given fed R2 result
lowest methane gas production (Table 4). This case may be happened as given fed R3 in Bali cattle to result
minerals concentration on rumen highest so that negative responds for growth and rumen microbes activities. Furthermore, given fed R3 may be also to result run of secondary fermentation process so more reduction H
2
molecule which used by Methanobacterium ruminantium and Methanobacterium mobilis to produce methane11,. Moreover, the lower methane gas concentration on rumen fluid at R1 and R2 are surprising, while
show the optimizing bio process on rumen and reduced acidosis risk in Bali cattle. Furthermore, low methane production is surprising because reduced global warming risk and can positive for animal, farmer and environment9.
Effect on Microbial Protein Supply
As shown in Table 5, the allantoin excretion in urine and efficiency microbial protein synthesis (EMPS) in
the rumen were not significantly (P>0.05) in all treatment with range 51.23 – 55.76 mmol/d and 107.17 – 107.74 g/1000g DOMR, while the allantoin absorbed and microbial protein synthesis have been increased by suplementation of 0.150% - 0.225% multivitamins-minerals on ration.
The higher allantoin absorbed and microbial protein supply in Bali cattle fed R2 and R3 may be due to
synchronization of available fermentable energy and degradable nitrogen in rumen and also supply and availability trace mineral and vitamins as effect of supplementation multivitamin-minerals. Karsli and Russell14 reported in addition to N and carbohydrate supply, microbial yield is affected by concentration of trace minerals and vitamin. In addition, dietary sulfur concentration has been found to effect microbial growth.
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Mudita, I M. et al Int. J. Pure App. Biosci.2 (5): 36-45 (2014) ISSN: 2320 – 7051
The amount of sulfur required by rumen microbes for synthesis of methionine and cysteine range from 0.11 to 0.20% of the total diet, depending on the status of the cattle. Limited intake of sulfur may restrict microbial protein synthesis when large amounts of NPN are fed to ruminal animals, such as urea or urea were fixation in product urea ammoniated rice straw.
Table 5. Influence of Multivitamins-Minerals Supplementation on Microbial Protein Supply in Bali Cattle Items
Treatments1
SEM3
R0 R1 R2 R3
Allantoin excretion (mmol/d) 51.23a2 55.13a 55.52a 55.76a 1.34 Allantoin Absorbed (mmol/d) 44.76a 48.67ab 49.45b 49.35b 1.19 Microbial Protein Synthesis (g/d) 197.83a 213.57ab 222.83b 222.24b 5.43 EMPS (g/1000 g DOMR) 107.17a 107.36a 107.74a 107.42a 4.96
Note:1) R0 = Ration without multivitamins-minerals supplementation, R1 = Ration with 0.075% multivitamins-minerals supplementation, R2 = Ration with 0.150% multivitamins-minerals supplementation, and R3 = Ration with 0.225% multivitamins-minerals supplementation, 2) The same letter in same row is not significantly difference (P>0.05), 3) SEM = Standard Error of the Treatment Means.
Similar of the Allantoin excretion and efficiency protein microbial synthesis (EMPS) of Bali cattle fed ratio
based on urea ammoniated rice straw were 51.23 – 55.76 mmol/day and 107.17 – 107.74 g/1000g DOMR shown Bali cattle can be adaptation of environment as well. Moreover, that are may be as effect of increasing populated of protozoa in Bali cattle fed ration with supplementation of multivitamins-mineral especially R2
(Table 4). High populated protozoa on rumen can take advantages and disadvantages. Protozoa on rumen can increase protein degradable, supply ammonia nitrogen (NH3-N) on rumen and reduce acidosis risk, in spite of
high populated of protozoa also can decrease the number of bacteria and fungi in the rumen liquor as effect protozoa is a predator of bacteria. Bacteria are sources of nitrogen/protein of protozoa. So protein microbial synthesis can be decrease of high populated protozoa and efficiency microbial protein synthesis on digestible organic matter apparently fermented in the rumen can be reduced.
Generally, efficiency microbial protein synthesis (EMPS) in the rumen of Bali cattle given ration based on
urea ammoniated rice straw with supplementation of multivitamins-minerals ere enough (107.36-107.42 g PMS/1000g DOMR). This is surprising because Bali cattle were supplemented of multivitamins-minerals on ration based on urea ammoniated rice straw have a much better Allantoin excretion from dairy cattle fed cottonseed meal at 0.5 kg/head/day and urea-treated rice straw was offered ad lib. with supplementation of corn meal and cassava chip as energy sources and with vary levels were result 28.1 – 45.8 mmol/d16, in spite of lower than Allantoin excretion of crossbreed (Brahman Vs Local) given urea treated rice straw with supplemented 1-3% per metabolic body weight (BW0.75) concentrate which result 130.7 – 244.6 mmol/d28. The EMPS of Bali cattle given ration based on urea ammoniated rice straw with supplementation of
multivitamins-minerals was 107.17 – 107.74 g MP/1000g DOMR equal with 69.51 – 69.97 g MP/1000g DOM or 17.27 – 17.78 g N/kg DOMR were there in range values EMPS fattening cattle reported Karsli and
Russell14,15 were 70–237g MPS/1000g DOMR. This is surprising because ration based on urea ammoniated rice straw have a much better EMPS from crossbreed cattle (Brahman Vs Local) were given fed various of
(14)
Mudita, I M. et al Int. J. Pure App. Biosci.2 (5): 36-45 (2014) ISSN: 2320 – 7051
Picture 1.
Relation supplementation of multivitamins-minerals on the ration based on urea ammoniated rice straw with rumen microbial protein synthesis
Generally, relation supplementation of multivitamins-minerals with rumen microbial protein synthesis in Bali cattle given ration based on urea ammoniated rice straw following regression formula: Y = 197.67 + 273.29 X – 725.78 X2, where R2 = 0.4697 (Picture 1), where Y = rumen microbial synthesis (g/d), and X = supplementation of multivitamins-minerals on ration. Based on that regression analyses known that suplementation of multi vitamins-minerals of 0.188% coused maximum rumen microbial protein synthesis of 223.39 gram/day or maximum increased 12.92%.
CONCLUSION
Supplementation of multivitamins-minerals on ration based on ammoniated rice straw can increasing maximum microbial protein supply as 223.39 g PMS/day (increase 12.92.%) with optimum supplementation are 0.188%.
Acknowledgement
The authors wish to thank to Faculty of Animal Husbandry Udayana University for support in this experiment. Thanks are also due to the Farmers Group Association “Nandi Abian” who help in feeding and looking after the animals during the period of experimentation.The Laboratory Staffs of the Faculty of Animal Husbandry for the assistance in analysing the sample of experimentation is also acknowledge.
REFERENCES
1. Arora, S.P., Pencernaan Mikroba pada Ruminansia. Gadjah Mada University Press, Yogyakarta (1995)
2. Association of Official Analytical Chemist (A.O.A.C.), Official Method of Analysis. 13th Ed., Washington, DC. (1980)
3. Bal, M.A dan D. Ozturk., Effects of Sulfur Containing Supplements on Ruminal Fermentation and Microbial Protein Synthesis. Research Journal of Animal and Veterinary Sciences 1(1): 33-36. INSInet Publications. http://www.insinet.net/rjavs/2006/33-36.pdf (accessed: Novembre 30, 2007). (2006)
(15)
Mudita, I M. et al Int. J. Pure App. Biosci.2 (5): 36-45 (2014) ISSN: 2320 – 7051
4. Bowen, M.K., Efficiency of microbial crude protein production in cattle grazing tropical pasture. PhD Thesis. University of Queensland. (2003)
5. Chen, C. Y. and J. T. Hsu., The Effects of Starch and Protein Degradation Rates, Hay Sources, and Feeding Frequency on Rumen Microbial Fermentation in a Continuous Culture System. Proc. Natl.
Sci. Counc. ROC (B).22:4, page 159-165 (1998)
6. Chenost, M. And Kayouli, C., Roughage Utilization In Warm Climate. ISBN 92-5-103981. Food and Agriculture Organization of The United Nations Rome, Italy. http://www.Fao.org/docrep/003/w4988e/W4988E01.htm (accessed: November 30, 2007). (1997)
7. Drake, D.J., G. Nader dan L. Farero., Feeding Rice Straw to Cattle. ANR Publication 8079. Division of Agriculture and Natural Resources. University of California. ISBN 978-1-60107-255-9. http://anrcatalog.ucdavis.edu (accessed: January 15, 2008) (2002)
8. Fellner, V., Rumen Microbes and Nutrient Management. Animal Science Departmental Report. North Carolina State University. http://mark.asci.ncsu.edu/SwineReports/2004-2005/DairyCattle/Nutrition/Fellner1.htm. (accessed: December 20, 2007]. (2004)
9. Hegarty, R., Green House Gas Emission From The Australian Livestock Sector. What Do We Know, What Can We Do. Australian Green House Office, Canberra ACT. ISBN: 1 876536 69 1. (accessed: Decembre 24, 2007) (2001)
10.Hermawan, D., Pengaruh Suplementasi Mineral dalam Ransum yang Mengandung Jerami Padi Amoniasi Urea Terhadap Konsentrasi VFA Parsial, Gas Metan dan konversi Ransum Pada Sapi Bali Penggemukan. Skripsi. Fakultas Peternakan. Universitas Udayana, Denpasar (2006)
11.Hungate, R.E., The Rumen and its Microbes. Academic Press, inc., New York (1966)
12.Ilham, N., Analisis Sosial Ekonomi dan Strategi Pencapaian Swasembada Daging 2010. Materi presentasi Pada Koordinasi Teknis Direktorat Budidaya Ternak Ruminansia. Tanggal 27 April 2006, Bogor. http://pse.litbang.deptan.go.id/ind/pdffiles/ART4-2b.pdf (accessed: February 25, 2007] (2006)
13.Karsli, M.A., Ruminal Mikrobial Protein Synthesis in Sheep Fed Forages of Varying Nutritive Values. Beef Research Report. Iowa State University (1999)
14.Karsli, M.A. and Russell, J.R., Effect of Some Dietary Factors on Ruminal Microbial Protein Synthesis. Turk. J. Vet. Anim. Sci. 25: 681-686. http://journals.tubitak.gov.tr/veterinery/issues/vet-01.25.5/vet-25-5-7-0002-14.pdf. (accessed: Decembre 28, 2007] (2001)
15.Karsli, M.A. and Russell, J.R., Effect of Source and Concentration of Nitrogen dan Carbohydrate on Ruminal Microbial Protein Synthesis. Turk. J. Vet. Anim. Sci. 26: 201-207. http://journals.tubitak.gov.tr/veterinary/issues/vet-02-26-2/vet-26-2-1-0002-21.pdf [(accessed: Decembre 28, 2007] (2002)
16.Khampa, S. Dan M., Wanapat. Influences of Energy Sources and Levels Supplementation on Ruminal Fermentation and Microbial Protein Synthesis in Dairy Steers. Pakistan Journal of Nutrition 5(4): 294-300. ISSN 1680-5194. http://www.pjbs.org/pjnonline/fin469.pdf accessed: January 15, 2008) (2006)
17.Leng, R. A., Tree Foliage In Ruminant Nutrition. Food and Agriculture Organization of The United Nations Rome, Italy. http://www.Fao.org/docrep/003/w7448e/W7448E00.htm (accessed: Septembre 14, 2007) (1997)
18.Ogimoto, K. dan S. Imai., Atlas of Rumen Microbiology. Japan Scientific Societies Press, Tokyo (1981)
19.Oosting, S.J., T.C. Viets, .C.W. Lammers-Wienhoven, and J. Van Bruchem., Ammonia Treatment of wheat Straw. 2. Efficiency of Microbial Protein Synthesis, Rumen Micrtobial Protein Pool Size and Turnover, and Small Intestinal Protein Digestion in heep. Netherland Journal of Agricultural Science 41: 135 – 151 (1993)
20.Owens, F.N. dan A.L. Goetsch., Ruminal Fermentation. In D.C. Church Ed. The Ruminant Animal Digestive Physiology and Nutrition. A. Reston Book. Prentice Hall, Eglewood Cliffs, New Jersey (1988)
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* Mudita, I M. et al Int. J. Pure App. Biosci.2 (5): 36-45 (2014) ISSN: 2320 – 7051
21.Parakkasi, A., Ilmu Nutrisi dan Makanan Ternak Ruminan. Penerbit Universitas Indonesia, Jakarta (1999)
22.Partama, IBG., Optimalisasi pemanfaatan jerami padi sebagai pakan dasar sapi Bali penggemukan melalui perlakuan amoniasi dan biofermentasi dengan mikroba. Prosiding Seminar Nasional Optimalisasi Teknologi Kreatif dan Peran Stakeholder dalam Percepatan Adopsi Inovasi Teknologi Pertanian. Pusat Analisis Sosial Ekonomi dan Kebijakan Pertanian Bekerjasama dengan BPTP Bali. Denpasar-Bali, 28 September 2005 (2005)
23.Partama, IBG., Diversifikasi Pakan Sapi Bali. Seminar Sehari: Prospek Pengembangan Agrbisnis Sapi Bali di Bali. Prgogram Pascasarjana Ilmu Ternak, Universitas Udayana, Denpasar. Denpasar-Bali, 15 Agustus 2006 (2006)
24.Polan, C. E., Update: Dietary Protein and Microbial Protein Contribution. Symposium. American Institute of Nutrition (1987)
25.Russell, J. B. And D. B. Wilson., Why are Ruminal Cellulolytic Bacteria Unable to Digest Cellulose at Low pH. Journal of Dairy Science. 79(8): page 1503-1509 (1996)
26.Sastrosupadi, A., Rancangan Percobaan Praktis Bidang pertanian. Edisi Revisi. Penerbit Kanisius, Yogyakarta (2000)
27.Verbic, J., Factor Affecting Microbial Protein Synthesis in The Rumen with Emphasis on Diets Containing Forages. www.gumpenstein.at/publikationen/tzt2002/verbic.pdf (accessed: January 25, 2007] (2002)
28.Wanapat, M. Dan S. Khampa., Effect of Level Suplementation of Concentrate Containing High Level of Cassava Chip on Rumen Ecology, Mcrobial N Supply and Digestibility of Nutrients in Beef Cattle. Asian-Aust, J. Anim.Sci.20(1): 75-81 (2007)
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The amount of sulfur required by rumen microbes for synthesis of methionine and cysteine range from 0.11 to 0.20% of the total diet, depending on the status of the cattle. Limited intake of sulfur may restrict microbial protein synthesis when large amounts of NPN are fed to ruminal animals, such as urea or urea were fixation in product urea ammoniated rice straw.
Table 5. Influence of Multivitamins-Minerals Supplementation on Microbial Protein Supply in Bali Cattle Items
Treatments1
SEM3
R0 R1 R2 R3
Allantoin excretion (mmol/d) 51.23a2 55.13a 55.52a 55.76a 1.34
Allantoin Absorbed (mmol/d) 44.76a 48.67ab 49.45b 49.35b 1.19
Microbial Protein Synthesis (g/d) 197.83a 213.57ab 222.83b 222.24b 5.43
EMPS (g/1000 g DOMR) 107.17a 107.36a 107.74a 107.42a 4.96
Note:1) R0 = Ration without multivitamins-minerals supplementation, R1 = Ration with 0.075% multivitamins-minerals supplementation, R2 = Ration with 0.150% multivitamins-minerals supplementation, and R3 = Ration with 0.225% multivitamins-minerals supplementation, 2) The same letter in same row is not significantly difference (P>0.05), 3) SEM = Standard Error of the Treatment Means.
Similar of the Allantoin excretion and efficiency protein microbial synthesis (EMPS) of Bali cattle fed ratio based on urea ammoniated rice straw were 51.23 – 55.76 mmol/day and 107.17 – 107.74 g/1000g DOMR shown Bali cattle can be adaptation of environment as well. Moreover, that are may be as effect of increasing populated of protozoa in Bali cattle fed ration with supplementation of multivitamins-mineral especially R2 (Table 4). High populated protozoa on rumen can take advantages and disadvantages. Protozoa on rumen can increase protein degradable, supply ammonia nitrogen (NH3-N) on rumen and reduce acidosis risk, in spite of high populated of protozoa also can decrease the number of bacteria and fungi in the rumen liquor as effect protozoa is a predator of bacteria. Bacteria are sources of nitrogen/protein of protozoa. So protein microbial synthesis can be decrease of high populated protozoa and efficiency microbial protein synthesis on digestible organic matter apparently fermented in the rumen can be reduced.
Generally, efficiency microbial protein synthesis (EMPS) in the rumen of Bali cattle given ration based on urea ammoniated rice straw with supplementation of multivitamins-minerals ere enough (107.36-107.42 g PMS/1000g DOMR). This is surprising because Bali cattle were supplemented of multivitamins-minerals on ration based on urea ammoniated rice straw have a much better Allantoin excretion from dairy cattle fed cottonseed meal at 0.5 kg/head/day and urea-treated rice straw was offered ad lib. with supplementation of corn meal and cassava chip as energy sources and with vary levels were result 28.1 – 45.8 mmol/d16, in spite of lower than Allantoin excretion of crossbreed (Brahman Vs Local) given urea treated rice straw with supplemented 1-3% per metabolic body weight (BW0.75) concentrate which result 130.7 – 244.6 mmol/d28. The EMPS of Bali cattle given ration based on urea ammoniated rice straw with supplementation of multivitamins-minerals was 107.17 – 107.74 g MP/1000g DOMR equal with 69.51 – 69.97 g MP/1000g DOM or 17.27 – 17.78 g N/kg DOMR were there in range values EMPS fattening cattle reported Karsli and Russell14,15 were 70–237g MPS/1000g DOMR. This is surprising because ration based on urea ammoniated rice straw have a much better EMPS from crossbreed cattle (Brahman Vs Local) were given fed various of energy source and level supplementation which calculate 4.3 – 10.7 g N/kg DOMR16
(2)
Mudita, I M. et al Int. J. Pure App. Biosci.2 (5): 36-45 (2014) ISSN: 2320 – 7051 Picture 1.
Relation supplementation of multivitamins-minerals on the ration based on urea ammoniated rice straw with rumen microbial protein synthesis
Generally, relation supplementation of multivitamins-minerals with rumen microbial protein synthesis in Bali cattle given ration based on urea ammoniated rice straw following regression formula: Y = 197.67 + 273.29 X – 725.78 X2, where R2 = 0.4697 (Picture 1), where Y = rumen microbial synthesis (g/d), and X = supplementation of multivitamins-minerals on ration. Based on that regression analyses known that suplementation of multi vitamins-minerals of 0.188% coused maximum rumen microbial protein synthesis of 223.39 gram/day or maximum increased 12.92%.
CONCLUSION
Supplementation of multivitamins-minerals on ration based on ammoniated rice straw can increasing maximum microbial protein supply as 223.39 g PMS/day (increase 12.92.%) with optimum supplementation are 0.188%.
Acknowledgement
The authors wish to thank to Faculty of Animal Husbandry Udayana University for support in this experiment. Thanks are also due to the Farmers Group Association “Nandi Abian” who help in feeding and looking after the animals during the period of experimentation.The Laboratory Staffs of the Faculty of Animal Husbandry for the assistance in analysing the sample of experimentation is also acknowledge.
REFERENCES
1. Arora, S.P., Pencernaan Mikroba pada Ruminansia. Gadjah Mada University Press, Yogyakarta (1995)
2. Association of Official Analytical Chemist (A.O.A.C.), Official Method of Analysis. 13th Ed., Washington, DC. (1980)
3. Bal, M.A dan D. Ozturk., Effects of Sulfur Containing Supplements on Ruminal Fermentation and Microbial Protein Synthesis. Research Journal of Animal and Veterinary Sciences 1(1): 33-36. INSInet Publications. http://www.insinet.net/rjavs/2006/33-36.pdf (accessed: Novembre 30, 2007). (2006)
(3)
4. Bowen, M.K., Efficiency of microbial crude protein production in cattle grazing tropical pasture. PhD Thesis. University of Queensland. (2003)
5. Chen, C. Y. and J. T. Hsu., The Effects of Starch and Protein Degradation Rates, Hay Sources, and Feeding Frequency on Rumen Microbial Fermentation in a Continuous Culture System. Proc. Natl. Sci. Counc. ROC (B).22:4, page 159-165 (1998)
6. Chenost, M. And Kayouli, C., Roughage Utilization In Warm Climate. ISBN 92-5-103981. Food and Agriculture Organization of The United Nations Rome, Italy. http://www.Fao.org/docrep/003/w4988e/W4988E01.htm (accessed: November 30, 2007). (1997) 7. Drake, D.J., G. Nader dan L. Farero., Feeding Rice Straw to Cattle. ANR Publication 8079. Division
of Agriculture and Natural Resources. University of California. ISBN 978-1-60107-255-9. http://anrcatalog.ucdavis.edu (accessed: January 15, 2008) (2002)
8. Fellner, V., Rumen Microbes and Nutrient Management. Animal Science Departmental Report. North Carolina State University. http://mark.asci.ncsu.edu/SwineReports/2004-2005/DairyCattle/Nutrition/Fellner1.htm. (accessed: December 20, 2007]. (2004)
9. Hegarty, R., Green House Gas Emission From The Australian Livestock Sector. What Do We Know, What Can We Do. Australian Green House Office, Canberra ACT. ISBN: 1 876536 69 1. (accessed: Decembre 24, 2007) (2001)
10.Hermawan, D., Pengaruh Suplementasi Mineral dalam Ransum yang Mengandung Jerami Padi Amoniasi Urea Terhadap Konsentrasi VFA Parsial, Gas Metan dan konversi Ransum Pada Sapi Bali Penggemukan. Skripsi. Fakultas Peternakan. Universitas Udayana, Denpasar (2006)
11.Hungate, R.E., The Rumen and its Microbes. Academic Press, inc., New York (1966)
12.Ilham, N., Analisis Sosial Ekonomi dan Strategi Pencapaian Swasembada Daging 2010. Materi presentasi Pada Koordinasi Teknis Direktorat Budidaya Ternak Ruminansia. Tanggal 27 April 2006, Bogor. http://pse.litbang.deptan.go.id/ind/pdffiles/ART4-2b.pdf (accessed: February 25, 2007] (2006) 13.Karsli, M.A., Ruminal Mikrobial Protein Synthesis in Sheep Fed Forages of Varying Nutritive
Values. Beef Research Report. Iowa State University (1999)
14.Karsli, M.A. and Russell, J.R., Effect of Some Dietary Factors on Ruminal Microbial Protein Synthesis. Turk. J. Vet. Anim. Sci. 25: 681-686. http://journals.tubitak.gov.tr/veterinery/issues/vet-01.25.5/vet-25-5-7-0002-14.pdf. (accessed: Decembre 28, 2007] (2001)
15.Karsli, M.A. and Russell, J.R., Effect of Source and Concentration of Nitrogen dan Carbohydrate on Ruminal Microbial Protein Synthesis. Turk. J. Vet. Anim. Sci. 26: 201-207. http://journals.tubitak.gov.tr/veterinary/issues/vet-02-26-2/vet-26-2-1-0002-21.pdf [(accessed: Decembre 28, 2007] (2002)
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