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Feeding panicled tick-clover to growing goats reduces Haemonchus contortus infection without negative effects on growth

Published online by Cambridge University Press:  28 November 2014

N.M. Cherry ,
M. Bullinger ,
B.D. Lambert ,
J.P. Muir ,
T.W. Whitney ,
J.E. Miller  and
J.T. Sawyer
N.M. Cherry*
Affiliation:
Texas A&M AgriLife Research, Stephenville, USA
M. Bullinger
Affiliation:
Department of Animal Science and Wildlife Management, Tarleton State University, Stephenville, USA
B.D. Lambert
Affiliation:
Texas A&M AgriLife Research, Stephenville, USA Department of Animal Science and Wildlife Management, Tarleton State University, Stephenville, USA
J.P. Muir
Affiliation:
Texas A&M AgriLife Research, Stephenville, USA
T.W. Whitney
Affiliation:
Texas A&M AgriLife Research, San Angelo, USA Louisiana State University, Baton Rouge, USA
J.E. Miller
Affiliation:
Louisiana State University, Baton Rouge, USA
J.T. Sawyer
Affiliation:
Department of Animal Science and Wildlife Management, Tarleton State University, Stephenville, USA
*
*Corresponding author: Email: nmcherry@ag.tamu.edu
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Summary

In an effort to identify a forage legume with condensed tannins (CT) that reduce gastro-intestinal nematodes (GIN) in small ruminants without negative effects on nutrition, the following trial looked at the effects of two legumes containing CT on average daily gain (ADG) and faecal egg counts (FEC) in kid goats. Lespedeza cuneata (sericea lespedeza, SL) and Desmodium paniculatum (panicled tick-clover; PTC) were pelleted into isonitrogenous complete feeds containing 3.8% CT in a four week feeding trial. Compared to the alfalfa (Medicago sativa) control diet, SL decreased (P ≤ 0.05) feed efficiency and ADG while PTC had the same (P > 0.05) feed efficiency as alfalfa. The SL and PTC pelleted feeds increased (P = 0.006) daily feed intake by 4.5 kg and 3.7 kg, respectively, compared to alfalfa control, while kids consuming SL and PTC showed an average 44% reduction (P ≤ 0.05) in FEC compared to those fed alfalfa. The results showed that feeding PTC, an herbaceous, perennial legume native to much of North America, to goats may provide a natural means of reducing ruminant GIN while simultaneously providing a source of protein.

Keywords

condensed tanningoatgastro-intestinal nematodeslegumeprotein
Type
Original Research
Information
Journal of Applied Animal Nutrition , Volume 2 , 2013 , e15
Copyright
Copyright © Cambridge University Press and Journal of Applied Animal Nutrition Ltd. 2014 

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References

Beauchemin, K.A., McGinn, S.M., Martinez, T.F., McAllister, T.A. (2007) Use of condensed tannin extract from quebracho trees to reduce methane emissions from cattle. Journal of Animal Science, 85: 19901996.Google Scholar
Bow, J.R., Muir, J.P. (2010) Dynamics of feeding Cynodon Dactylon cv. ‘Tifton’ hay of varying maturities to wether goats. Small Ruminant Research, 93: 198201.Google Scholar
Bowman, J.G., Hunt, C.W., Kerley, M.S., Paterson, J.A. (1991) Effects of grass maturity and legume supplementation on large particle size reduction and small particle flow from the rumen of cattle. Journal of Animal Science, 69: 369378.Google Scholar
Datta, F.U., Nolan, J.V., Rowe, J.B., Gray, G.D. (1998) Protein supplementation improves the performance of parasitised sheep fed a straw-based diet. International Journal for Parasitology, 28:12691278.Google Scholar
Diggs, Jr. G.M., Lipscomb, B.L., O'Kennon, R.J. (1999) Shinner and Mahler's illustrated flora of North Central Texas. Botanical Research Institute, Fort Worth, TX.Google Scholar
Foster, J.L., Muir, J.P., Lambert, B.D., Pawelek, D. (2007) In situ and in vitro degradation of native warm-season legumes and alfalfa in goats and steers fed sorghum-sudan basal diet. Animal Feed Science and Technology, 133: 228239.Google Scholar
Howell, S.B., Burke, J.M., Miller, J.E., Terrill, T.H., Valencia, E., Williams, M.J., Williamson, L.H., Zajac, A.M., Kaplan, R.M. (2008) Anthelmintic resistance on sheep and goat farms in the southeastern United States. Journal of the American Veterinary Medical Association, 233:19131919.Google Scholar
Johnson, R.C., Gee, D.H., Costello, W.J., Carlson, C.W. (1986) Effects of anabolic implants and breed group on carcass traits and palatability characteristics of bullock beef. Journal of Animal Science, 63: 399406.Google Scholar
Krueger, W.K., Gutierrez-Banuelos, H., Carstens, H.E., Min, B.R., Pinchak, W.E., Gomez, R.R., Anderson, R.C., Krueger, N.K., Forbes, T.D.A. (2010) Effects of dietary tannin source on performance, feed efficiency, ruminal fermentation, and carcass and non-carcass traits in steers fed a high grain diet. Animal Feed Science and Technology, 159: 19.Google Scholar
Leupp, J.L., Lardy, G.P., Bauer, M.L., Karges, K.K., Gibson, M.L., Caton, J.S., Maddock, R.J. (2009) Effects of distillers grains with soluble on growing and finishing steer intake, performance, carcass characteristics, and steak color and sensory attributes. Journal of Animal Science, 87: 41184124.Google Scholar
McGraw, R.L., Shockley, F.W., Thompson, J.F., Roberts, C.A. (2004) Evaluation of native legume species for forage yield, quality, and seed production. Native Plants Journal, 52: 152159.Google Scholar
McSweeney, C.S., Palmer, B., McNeill, D.M., Krause, D.O. (2001) Microbial interactions with tannins: nutritional consequences for ruminants. Animal Feed Science and Technology, 91: 8393.Google Scholar
Min, B.R., Attwood, G.T., Reilly, K., Sun, W., Peters, J.S., Barry, J.S., McNabb, W.C. (2002) Lotus corniculatus condensed tannins decrease in vivo populations of proteolytic bacteria and affect nitrogen metabolism in the rumen of sheep. Canadian Journal of Microbiology, 48: 911921.Google Scholar
Min, B.R., McNabb, W.C., Barry, W.T., Peters, J.S. (2000) Solubilisation and degradation of ribulose-1,5-bisphosphate carboxylase/oxygenase (EC 4.1.1.39; Rubisco) protein from whiteclover (Trifolium repens) and Lotus corniculatus by rumen microorganisms and the effect of condensed tannins on these processes. Journal of Agricultural Science, 134: 305317.Google Scholar
Mosjidis, J.A. (1995) Variability for biomass production and plant composition in Sericea lespedeza. Biomass and Bioenergy 11: 6368.Google Scholar
Mosjidis, J.A. (2001) Registration of AU Grazer. Crop Science, 41: 262.Google Scholar
Muir, J.P., Bow, J.R. (2008) Defoliation of panicled tick-clover, tweedy's tick-clover, and tall bush-clover: I. winter survival and yields of nitrogen, herbage, and seed. Agronomy Journal, 100: 16311634.Google Scholar
Muir, J.P., Taylor, J., Interrante, S.M. (2005) Herbage and seed from native perennial herbaceous legumes of Texas. Rangeland Ecology and Management, 58: 643651.Google Scholar
Moore, D.A., Terrill, T.H., Kouakou, B., Shaik, S.A., Mosjidis, J.A., Miller, J.E., Vanguru, M., Kannan, G., Burke, J.M. (2008) The effects of feeding Sericea lespedeza hay on growth rate of goats naturally infected with gastrointestinal nematodes. J. Anim. Sci. 86: 23282337.Google Scholar
National Research Council (1981) Nutrient Requirements of Goats: Angora, Dairy, and Meat Goats in Temperate and Tropical Countries. No. 15. National Academy Press, Washington, DC 91.Google Scholar
Naumann, H.D., Muir, J.P., Lambert, B.D., Tedeschi, L.O., Kothmann, M.M. (2013) Condensed tannins in the ruminant environment: A perspective on biological activity. Journal of Agricultural Science, 1: 820.Google Scholar
Naumann, H.D., Hagerman, A.E., Lambert, B.D., Muir, J.P., Tedeschi, L.O., Kothmann, M.M. (2013) Molecular weight and protein-precipitating ability of condensed tannins from warm-season perennial legumes. Journal of Plant Interactions, 9:212219.Google Scholar
Packard, C.E., Muir, J.P., Wittie, R.D. (2007) Groundnut stover and bermudagrass hay for wethers on winter hardwood range in north central Texas. Small Ruminant Research, 67: 16.Google Scholar
Pagán-Riestra, S., Muir, J.P., Lambert, B.D., Tedeschi, L., Redmon, L. (2010) Phosphorus and other nutrient disappearance from plants containing condensed tannins using the nylon bag technique. Animal Feed Science and Technology, 156: 1925.Google Scholar
Pawelek, D.L., Muir, J.P., Lambert, B.D., Wittie, R.D. (2008) In sacco rumen disappearance of condensed tannins, fiber, and nitrogen from herbaceous native Texas legumes in goats. Animal Feed Science and Technology, 140: 225240.Google Scholar
Puchala, R., Min, B.R., Goetsch, A.L., Sahlu, T. (2005) The effect of condensed tannin-containing forage on methane emission by goats. Journal of Animal Science, 83: 182186.Google Scholar
Shaik, S.A., Terrill, T.H., Miller, J.E., Kouakou, B., Kannan, B., Kaplan, R.M., Burke, J.M., Mosjidis, J. (2006) Sericea lespedeza hay as a natural deworming agent against gastrointestinal nematode infection in goats. Veterinary Parasitology, 139: 150157.Google Scholar
Spires, H.R., Clark, J.H. (1979) Effect of intraruminal urea administration on glucose metabolism in dairy steers. Journal of Nutrition, 109: 14381447.Google Scholar
Solaiman, S., Thomasm, J., Dupre, Y., Min, B.R., Gurung, N., Terrill, T.H., Hainlein, J.F.W. (2010) Effect of feeding Sericea lespedeza on growth performance, blood metabolites, and carcass characteristics of Kiko crossbred male kids. Small Ruminant Research, 93: 149156.CrossRefGoogle Scholar
Terrill, T.H., Mosjidis, J.A., Moore, D.A., Shaik, S.A., Miller, J.E., Burke, J.M., Muir, J.P., Wolfe, R.M. (2007) Effect of pelleting on efficacy of Sericea lespedeza hay as a natural dewormer in goats. Veterinary Parasitology, 146: 117122.Google Scholar
Terrill, T.H., Larsen, M., Samples, O., Husted, S., Miller, J.E., Kaplan, R.M., Gelaye, S. (2004) Capability of the nematode-trapping fungus Duddingtonia flagrans to reduce infective larvae of gastrointestinal nematodes in goat feces in the southeastern United States: dose titration and dose time interval studies. Veterinary Parasitology, 120: 285296.Google Scholar
Turner, K.E., Wildeus, S., Collins, J.R. (2005) Intake, performance, and blood parameters in young goats offered high forage diets of lespedeza or alfalfa hay. Small Ruminant Research, 59: 1523.Google Scholar
Van Wyk, J.A., Stenson, M.O., Van Der Merwe, J.S., Vorster, R.J., Viljoen, P.G. (1999) Anthelmintic resistance in South Africa: surveys indicate an extremely serious situation in sheep and goat farming. Oderstepoort Journal of Veterinary Research, 66: 273284.Google Scholar
Waghorn, G.C. (2008) Beneficial and detrimental effects of dietary condensed tannins for sustainable sheep and goat production-progress and challenges. Animal Feed Science and Technology, 147: 116139.Google Scholar
Whitlock, H.V. (1948) Some modifications of the McMaster helminth egg counting technique and apparatus. Council for Scientific and Industrial Research, 21: 177180.Google Scholar
Wolfe, R.M., Terrill, T.H., Muir, J.P. (2008) Drying method and origin of standard affect condensed tannin (CT) concentrations in perennial herbaceous legumes using simplified butanol-HCL CT analysis. Journal of the Science of Food and Agriculture, 88: 10601067.Google Scholar
Woodward, S.L., Waghorn, G.C., Lassey, K.R., Laboyre, P.L. (2002) Does feeding sulla (Hedysarum coronarium) reduce methane emissions from dairy cows? Proceedings of New Zealand Society of Animal Production, 62: 227230.Google Scholar