Kasim Agwaan, H. (2023). Some physiological effect of Different Protein Sources in Ruminants Ration: A Comparative Review. Journal of Applied Veterinary Sciences, 8(2), 55-61. doi: 10.21608/javs.2023.182063.1203
Hanan Waleed Kasim Agwaan. "Some physiological effect of Different Protein Sources in Ruminants Ration: A Comparative Review". Journal of Applied Veterinary Sciences, 8, 2, 2023, 55-61. doi: 10.21608/javs.2023.182063.1203
Kasim Agwaan, H. (2023). 'Some physiological effect of Different Protein Sources in Ruminants Ration: A Comparative Review', Journal of Applied Veterinary Sciences, 8(2), pp. 55-61. doi: 10.21608/javs.2023.182063.1203
Kasim Agwaan, H. Some physiological effect of Different Protein Sources in Ruminants Ration: A Comparative Review. Journal of Applied Veterinary Sciences, 2023; 8(2): 55-61. doi: 10.21608/javs.2023.182063.1203
Some physiological effect of Different Protein Sources in Ruminants Ration: A Comparative Review
Dept. of Animal Production، College of Agriculture and Forestry, University of Mosul, Iraq
Receive Date: 20 December 2022,
Revise Date: 29 January 2023,
Accept Date: 23 February 2023
Abstract
The ruminants' productive capacity was enhanced by the addition of protein sources high in non-hydrolyzed protein to the Rumen because of its palatability, availability in large quantities, balanced amino acid composition, and rapid decomposition in the Rumen; the various commonly used soybean meal is one of the protein sources in ruminant feed and the most widely used in nutrition. However, its high cost led to the search for alternatives to it at a lower cost; one of these additives is corn gluten meal, which is a by-product of the manufacturing because corn gluten gain has a protein content of 60–65% crude protein, it eliminates the need to supplement traditional feed with protein sources, lowering the cost of feed. Urea is one of the most essential nitrogenous additives that are used to improve the nutritional value and benefit from coarse feed, and because it has a value almost equal to the concentrates for ruminants, as urea decomposes in the Rumen at high speed to ammonia, which is used to produce amino acids and microbial protein by microbiology, and those substances are utilized protein substances by the animal.
ABDEL HAMEED, A.A., SALIH, A.M., and AMASAB, E.O., 2013. Effect of Feeding Untreated or Urea Treated Groundnut Hull Supplement with Different Protein Sources on Blood Parameters of Sudan Desert Lambs. Journal of Animal and Feed, 3(1):40-46.
AL FARES AZIZ KHADER,2012. Partial Replacement of Barely by Soya Bean Meal or Urea and Addition of Saccharomyces cerevisiae to Male Arabi Lambs and Their Effects on Rumen Microbial Performance and Growth. Ph.D. thesis, College of Agriculture, University of Basrah.
ALKASS, J.E., HERMIZ, H.N., and BAPER, M.I., 2021. “Some Aspects of Reproductive Efficiency in Awassi Ewes: A review”, Iraqi Journal of Agricultural Sciences, 52(1), pp. 20–27.
ALSAEDI, M.S.M. 2016. Effect of Using Different Rates of Straw Treated with Whey and Urea on the Performance of Male Arabi Lambs. M.Sc. thesis. College of Agriculture, University of Basrah.
AL-SHERWANY, D.A.O., AL-DABBAGH, A.S.S., and AL-MARZANI E. A.H., 2016. Effect of Different Food Levels on Some Characteristics of Growth and Blood Values for Karadi Lambs. Tikrit Journal for Agricultural Sciences, 16(3): 121-127.
AL-TALIB, A.A., ALMAHDAWI, M.K., ABDEL KADER, M.R., and YOUNIS, O.S., 2010. Influence of the protein level in the diet on some blood and biochemical characteristics and sensory evaluation of Awassi sheep. Al-kofa Journal for Agricultural Sciences, 2(2): 58-66.
ARRUDA, M., ALMEIDA, M., BERTOCO, J., PEREIRA-JUNIOR, S., CASTRO-FILHO, E.S., FELICIANO, A.L., RODRIGUES, J. L., TORRES, R., COSTA, R.V., GRILO, L., and EZEQUIEL, J., 2020. Soybean molasses to replace corn for feedlot lambs on growth performance, carcass characteristics, and meat quality. Translational animal science, 5(1), txaa230. https://doi.org/10.1093/tas/txaa230
BAHRAMI-YEKDANGI, M., GHORBANI, G.R., KHORVASH, M., KHAN, M.A., and GHAFFARI, M.H., 2016. Reducing crude protein and rumen degradable protein with a constant concentration of Rumen undegradable protein in the diet of dairy cows: Production performance, nutrient digestibility, nitrogen efficiency, and blood metabolites. Journal of animal science, 94(2), 718–725. https://doi.org/10.2527/jas.2015-9947.
BOUCHER, S.E., CALSAMIGLIA, S., PARSONS, C.M., STEIN, H.H., STERN, M.D., ERICKSON, P.S., UTTERBACK, P.L., and SCHWAB, C.G., 2009. Intestinal digestibility of amino acids in Rumen undegradable protein estimated using a precision-fed vasectomized rooster bioassay: I. Soybean meal and SoyPlus. Journal of dairy science, 92(9), 4489–4498. https://doi.org/10.3168/jds.2008-1884.
BOULOS, S., TANNLER, A., and NYSTROM,L., 2020. Nitrogen-to-protein conversion Factors for Edible Insect on the swiss Market :T.molitor,A.domesticus,and L.migratoria.Front. Nutr. 7:89.doi: 10.3389/fnut.2020.00089
BURD, N.A., MCKENNA, C.F., SALVADOR, A.F., PAULUSSEN, K., and MOORE, D.R., 2019. Dietary Protein Quantity, Quality, and Exercise Are Key to Healthy Living: A Muscle-Centric Perspective Across the Lifespan. Frontiers in nutrition, 6, 83. https://doi.org/10.3389/fnut.2019.00083
CAPPER, J. L. 2020. Opportunities and Challenges in Animal Protein Industry Sustainability: The Battle Between Science and Consumer Perception. Animal frontiers: the review magazine of animal agriculture, 10(4), 7–13. https://doi.org/10.1093/af/vfaa034.
CHANU, Y.M., PAUL, S.S., DEY, A., and DAHIYA, S.S., 2020. Reducing Ruminal Ammonia Production with Improvement in Feed Utilization Efficiency and Performance of Murrah Buffalo (Bubalus bubalis) Through Dietary Supplementation of Plant-Based Feed Additive Blend. Frontiers in veterinary science, 7, 464. https://doi.org/10.3389/fvets.2020.00464
CHEN, H., WANG, C., HUASAI, S., and CHEN, A., 2021. Effects of dietary forage to concentrate ratio on nutrient digestibility, ruminal fermentation and rumen bacterial composition in Angus cows. Scientific reports, 11(1), 17023.
COLMENERO, J.J., and BRODERICK, G.A., 2006. Effect of amount and ruminal degradability of soybean meal protein on performance of lactating dairy cows. Journal of dairy science, 89(5), 1635–1643. https://doi.org/10.3168/jds.S0022-0302(06)72230-5
DAS, A.K., GOWDA, M.M., MUTHUSAMY, V., ZUNJARE, R.U., CHAUHAN, H.S., BAVEJA, A., BHATT, V., CHAND, G., BHAT, J.S., GULERIA, S.K., SAHA, S., GUPTA, H.S., and HOSSAIN, F., 2021. Development of Maize Hybrids with Enhanced Vitamin-E, Vitamin-A, Lysine, and Tryptophan Through Molecular Breeding. Frontiers in plant science, 12, 659381. https://doi.org/10.3389/fpls.2021.659381.
DARABIGHANE, B., MIRZAEI AGHJEHGHESHLAGH, F., MAHDAVI, A., NAVIDSHAD, B., and BERNARD, J.K., 2020. Effects of inclusion of corn gluten feed in dairy rations on dry matter intake, milk yield, milk components, and ruminal fermentation parameters: a meta-analysis. Tropical animal health and production, 52(5), 2359–2369. https://doi.org/10.1007/s11250-020-02261-2.
EMMANUEL, N., PATIL, N.V., BHAGWAT, S.R., LATEEF, A., XU, K., and LIU, H., 2015. Effects of different levels of urea supplementation on nutrient intake and growth performance in growing camels fed roughage based complete pellet diets. Animal nutrition (Zhongguo xu mu shou yi xue hui), 1(4), 356–361. https://doi.org/10.1016/j.aninu.2015.12.004 .
FAO., 2000. Food and Agriculture organization of the United Nations. Production year book. vol, 54.
FEIZI, L. K., ZAD, S.S., JALALI, S., RAFIEE, H., JAZI, M.B., SADEGHI, K., and KOWSAR, R., 2020. Fermented soybean meal affects the ruminal fermentation and the abundance of selected bacterial species in Holstein calves: a multilevel analysis. Scientific reports, 10(1), 12062. https://doi.org/10.1038/s41598-020-68778-6.
GANDRA, J. R., TAKIYA, C.S., OLIVERIRA, E.R., PAIVA, P.G., TONISSIE, R.H., GOES, B., GANDRA, E.R.S., and ARAKI, H.M.G., 2016. Nutrient digestion, microbial protein synthesis, and blood metabolites of Jersey heifers fed chitosan and whole raw soybeans. R. Bras. Zootec., 45(3):130-13.
GIANNENAS, I., BONOS, E., ANESTIS, V., FILIOUSSIS, G., PAPANASTASIOU, D.K., BARTZANAS, T., PAPAIOANNOU, N., TZORA, A., and SKOUFOS, I., 2017. Effects of Protease Addition and Replacement of Soybean Meal by Corn Gluten Meal on the Growth of Broilers and on the Environmental Performances of a Broiler Production System in Greece. PloS one, 12(1), e0169511. https://doi.org/10.1371/journal.pone.0169511.
GOPFERT, E., TRCKOVA, M., and DVORAK, R., 2006. The use of treated rape cake in a calf starter diet. Czech Journal Anim.Sci.,51(11): 491–501.
GORISSEN, S., CROMBAG, J., SENDEN, J., WATERVAL, W., BIERAU, J., VERDIJK, L.B., and VAN LOON, L., 2018. Protein content and amino acid composition of commercially available plant-based protein isolates. Amino acids, 50(12), 1685–1695. https://doi.org/10.1007/s00726-018-2640-5 .
HACKMANN, T.J., and FIRKINS, J.L., 2015. Maximizing efficiency of rumen microbial protein production. Frontiers in microbiology, 6, 465. https://doi.org/10.3389/fmicb.2015.00465.
HAILEMARIAM, S., ZHAO, S., H.E., Y., and WANG, J., 2021. Urea transport and hydrolysis in the Rumen: A review. Animal nutrition (Zhongguo xu mu shou yi xue hui), 7(4), 989–996. https://doi.org/10.1016/j.aninu.2021.07.002
HENCHION, M., HAYES, M., MULLEN, A.M., FENELON, M., and TIWARI, B., 2017. Future Protein Supply and Demand: Strategies and Factors Influencing a Sustainable Equilibrium. Foods (Basel, Switzerland), 6(7), 53.
IMRAN, M., SHAHID, M.Q., PASHA,T.N., and HAQUE,M.N., 2018. Effects of replacing soybean meal with corn gluten meal on milk productionand nitrogen efficiency in Holstein cows. South African Journal of Animal Science,48(3). http://dx.doi.org/10.4314/sajas
ISMAIL, B.P., SENARATNE-LENAGALA, L., STUBE, A., and BRACKENRIDGE, A., 2020. Protein demand: review of plant and animal proteins used in alternative protein product development and production. Animal frontiers: the review magazine of animal agriculture, 10(4), 53–63.
JAHAN-MIHAN, A., LUHOVYY, B.L., EL KHOURY, D., and ANDERSON, G.H., 2011. Dietary proteins as determinants of metabolic and physiologic functions of the gastrointestinal tract. Nutrients, 3(5), 574–603. https://doi.org/10.3390/nu3050574.
KAZEMI- BONCHENARI, M., ZADEH, A.R.A., TAHRIRI, A.R., KARKOODI, K. KARKOODI, JALALI, S. and SADRI, H., 2015. The Effects of Partial Replacement of Soybean Meal by Xylose-Treated Soybean Meal in the Starter Concentrate on Performance, Health Status, and Blood Metabolites of Holstein Calves. Italian Journal of Animal Science, 14(1):138-142.
KUMAR, D., DATT, C., DAS, L. K., and KUNDU, S. S. (2015). Evaluation of various feedstuffs of ruminants in terms of chemical composition and metabolisable energy content. Veterinary world, 8(5), 605–609.
MA, Y., KHAN, M. Z., LIU, Y., XIAO, J., CHEN, X., JI, S., CAO, Z., and LI, S., 2021. Analysis of Nutrient Composition, Rumen Degradation Characteristics, and Feeding Value of Chinese Rye Grass, Barley Grass, and Naked Oat Straw. Animals: an open access journal from MDPI, 11(9), 2486. https://doi.org/10.3390/ani11092486.
MANOUKIAN, M., DELCURTO, T., KLUTH, J., CARLISLE, T., DAVIS, N., NACK, M., WYFFELS, S., SCHEAFFER, A., and VAN EMON, M., 2021. Impacts of Rumen Degradable or Undegradable Protein Supplementation with or without Salt on Nutrient Digestion, and V.F.A. Concentrations. Animals: an open access journal from MDPI, 11(11), 3011. https://doi.org/10.3390/ani11113011 .
MARIOTTI, F. 2019. Animal and Plant Protein Sources and Cardiometabolic Health. Advances in nutrition (Bethesda, Md.), 10(Suppl_4), S351–S366.
NAFIKOVA, E., MIRONOVA, I., GAZEEV, I., BLAGOV, D., and NIGMATIYANOV, A., 2021. The effect of an energy additive on the metabolism of cattle. Canadian journal of veterinary research = Revue canadienne de recherche veterinaire, 85(3), 210–217.
NASSER, A.K., SHAMS AL-DAIN, Q.Z., and ABOU, N.Y., 2014. Effect of using rations different in nitrogen sources on growth and blood parameters for growing local sharabi calf under environment condition of Nineveh province. Journal of Diyala Agricultural Sciences, 6(2):18-26.
NASSER, A.K., SHAMS AL-DAIN, Q.Z., ABDULLA, M.N., and ABOU, N.Y., 2013. Natural feed additives effects on some hematological and biochemical parameters of native male calves. Tikrit Journal for Agricultural Sciences, 13(2): 111-116.
NISA, M., JAVAID, A., SHAHZAD, M.A., and SARWAR, M., 2008. Influence of varying ruminally degradable to undegradable protein ratio on nutrient intake, milk yield, nitrogen balance, conception rate and days open in early lactating Nili-Ravi buffaloes (Bubalus bubalis). Asian-Aust. J. of Anim. Sci., 21(9): 1303-1311.
NUR ATIKAH, I., ALIMON, A.R., YAAKUB, H., ABDULLAH, N., JAHROMI, M.F., IVAN, M., and SAMSUDIN, A.A., 2018. Profiling of rumen fermentation, microbial population and digestibility in goats fed with dietary oils containing different fatty acids. B.M.C. veterinary research, 14(1), 344. https://doi.org/10.1186/s12917-018-1672-0.
OBEIDAT, B.S., KRIDLI, R.T., MAHMOUD, K.Z., OBEIDAT, M.D., HADDAD, S.G., SUBIH, H.S., ATA, M., AL-JAMAL, A.E., ABU GHAZAL, T., and Al-KHAZÁLEH, J.M., 2019. Replacing Soybean Meal with Sesame Meal in the Diets of Lactating Awassi Ewes Suckling Single Lambs: Nutrient Digestibility, Milk Production, and Lamb Growth. Animals : an open access journal from MDPI, 9(4), 157. https://doi.org/10.3390/ani9040157
PATRA, A.K., and ASCHENBACH, J.R., 2018. Ureases in the gastrointestinal tracts of ruminant and monogastric animals and their implication in urea-N/ammonia metabolism: A review. Journal of advanced research, 13, 39–50. https://doi.org/10.1016/j.jare.2018.02.005
PENG, Y., TAN, H., LIU, S., LI, H., CHEN, Y., and LIN, J., 2017. Effects of Different Grain Sources in Both Maternal and Offspring Diets on Pigmentation and Growth Performance in Yellow-Skinned Chickens. The journal of poultry science, 54(3), 228–235. https://doi.org/10.2141/jpsa.0160101
PUTRI, E.M., ZAIN, M., WARLY, L., and HERMON, H., 2021. Effects of rumen-degradable-to-undegradable protein ratio in ruminant diet on in vitro digestibility, rumen fermentation, and microbial protein synthesis. Veterinary world, 14(3), 640–648. https://doi.org/10.14202/vetworld.2021.640-648.
REN, Z., YAO, R., LIU, Q., DENG, Y., SHEN, L., DENG, H., ZUO, Z., WANG, Y., DENG, J., CUI, H., HU, Y., MA, X., and FANG, J., 2019. Effects of antibacterial peptides on rumen fermentation function and rumen microorganisms in goats. PloS one, 14(8), e0221815. https://doi.org/10.1371/journal.pone.0221815
RIBEIRO, G.O., GRUNINGER, R.J., JONES, D.R., BEAUCHEMIN, K.A., YANG, W.Z., WANG, Y., ABBOTT, D.W., TSANG, A., and MCALLISTER, T.A., 2020. Effect of ammonia fiber expansion-treated wheat straw and a recombinant fibrolytic enzyme on rumen microbiota and fermentation parameters, total tract digestibility, and performance of lambs. Journal of animal science, 98(5), skaa116. https://doi.org/10.1093/jas/skaa116.
RIMOLA, A., UGLIENGO, P., and SODUPE, M., 2009. Formation versus hydrolysis of the peptide bond from a quantum-mechanical viewpoint: The role of mineral surfaces and implications for the origin of life. International journal of molecular sciences, 10(3), 746–760. https://doi.org/10.3390/ijms10030746
SARO, C., MATEO, J., CARO, I., CARBALLO, D. E., FERNÁNDEZ, M., VALDÉS, C., BODAS, R., and GIRÁLDEZ, F.J., 2020. Effect of Dietary Crude Protein on Animal Performance, Blood Biochemistry Profile, Ruminal Fermentation Parameters and Carcass and Meat Quality of Heavy Fattening Assaf Lambs. Animals: an open access journal from MDPI, 10(11), 2177.
SHEN, J.S., SONG, L.J., SUN, H.Z., WANG, B., CHAI, Z., CHACHER, B., and LIU, J.X., 2015. Effects of corn and soybean meal types on rumen fermentation, nitrogen metabolism and productivity in dairy cows. Asian-Australasian journal of animal sciences, 28(3), 351–359. https://doi.org/10.5713/ajas.14.0504
SINGH, K.J., ROY,D., KUMAR,V., KUMAR, M., and SIROHI, R., 2015. Effect of Supplementing Rumen Protected Methionine and Lysine on Nutrient Utilization, Growth and Blood Biochemical Parameters in Hariana Heifers. Indian J. Anim. Nutr. 2015. 32 (2): 187-191. https://www.researchgate.net/publication/280232127.
SOK, M., OUELLET, D.R., FIRKINS, J.L., PELLERIN, D., and LAPIERRE, H., 2017. Amino acid composition of rumen bacteria and protozoa in cattle. Journal of dairy science, 100(7), 5241–5249. https://doi.org/10.3168/jds.2016-12447
TACOMA, R., FIELDS, J., EBENSTEIN, D.B., LAM, Y.W., and GREENWOOD, S. L., 2017. Ratio of dietary Rumen degradable protein to Rumen undegradable protein affects nitrogen partitioning but does not affect the bovine milk proteome produced by mid-lactation Holstein dairy cows. Journal of dairy science, 100(9), 7246–7261. https://doi.org/10.3168/jds.2017-12647.
WANG, Y., JIN, L., WEN, Q.N., KOPPARAPU, N.K., LIU, J., LIU, X.L., and ZHANG, Y.G., 2016. Rumen Degradability and Small Intestinal Digestibility of the Amino Acids in Four Protein Supplements. Asian-Australasian journal of animal sciences, 29(2), 241–249. https://doi.org/10.5713/ajas.15.0342.
WAHYONO, T., SHOLIKIN, M.M., KONCA, Y., OBITSU, T., SADARMAN, S., and JAYANEGARA, A., 2022. Effects of urea supplementation on ruminal fermentation characteristics, nutrient intake, digestibility, and performance in sheep: A meta-analysis. Veterinary world, 15(2), 331–340. https://doi.org/10.14202/vetworld.2022.331-340
XIA,C., RAHMAN, M.A., YANG, H., SHAO, T., QIU, Q., SU, H., and CAO, B., 2018. Effect of increased dietary crude protein levels on production performance, nitrogen utilisation, blood metabolites and ruminal fermentation of Holstein bulls. Asian-Australas J. Anim. Sci,31(10):1643-1653. https://doi.org/10.5713/ajas.18.0125
XIE, Y.M., XU, Q.B., WU, Y.M., HUANG, X.B., and LIU, J.X., 2015. Duodenum has the greatest potential to absorb soluble non-ammonia nitrogen in the non-mesenteric gastrointestinal tissues of dairy cows. Journal of Zhejiang University. Science. B, 16(6), 503–510. https://doi.org/10.1631/jzus.B1400299.
XU, Y., LI, Z., MORAES, L.E., SHEN, J., YU, Z., and ZHU, W., 2019. Effects of Incremental Urea Supplementation on Rumen Fermentation, Nutrient Digestion, Plasma Metabolites, and Growth Performance in Fattening Lambs. Animals: an open access journal from MDPI, 9(9), 652. https://doi.org/10.3390/ani9090652
ZHONG, C., LONG, R., and STEWART, G. S., 2022. The role of rumen epithelial urea transport proteins in urea nitrogen salvage: A review. Animal nutrition (Zhongguo xu mu shou yi xue hui), 9, 304–313. https://doi.org/10.1016/j.aninu.2022.01.008.
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