Changes in faecal δ13C in response to changing proportions of legume (C3) and grass (C4) in the diet of sheep and cattle

D. B. Coates; A. P. A. Van Der Weide; J. D. Kerr

doi:10.1017/S0021859600077704

Summary

Feeding studies were conducted in 1986 with penned sheep and cattle fed legume (C3) and grass (C4) hays mixed in different proportions. Large fluctuations in diet δ13C within or between days were associated with much smaller fluctuations in the δ13C of faeces. When the overall daily legume percentage in the diet was held constant, there was little variation in the δ13C of faeces irrespective of when during the day the legume, relative to the grass, was eaten.

Cattle set stocked on Stylosanthes/grass pastures in Queensland showed only minor variations in faecal δ13C within or between days in the short term. All animals within a group showed similar trends when the diet was changing. The changes in the δ13C of faeces from day to day reflected small but real changes in diet selection.

It was concluded that the δ13C of a single faecal sample reliably reflects the integrated diet over the previous 3–4 days of a free-grazing ruminant so that the frequency and pattern of faecal sampling for estimating diet composition may be determined by considerations other than reliability

References

REFERENCES

Balch, C. C. (1950). Factors affecting the utilization of food by dairy cows. 1. The rate of passage of food through the digestive tract. British Journal of Nutrition 4, 361–388.CrossRef Google Scholar

Coates, D. B., Schachenmann, P. & Jones, R. J. (1987). Reliability of extrusa samples collected from steers fistulated at the oesophagus to estimate the diet of resident animals in grazing experiments. Australian Journal of Experimental Agriculture 27, 739–745.CrossRef Google Scholar

Craig, H. (1957). Isotopic standards for carbon and oxygen and correction factors for mass-spectrometric analysis of carbon dioxide. Geochimica et Cosmochimica Ada 12, 133–149.CrossRef Google Scholar

Haydock, K. P. & Shaw, N. H. (1975). The comparative yield method for estimating dry matter yield of pasture. Australian Journal of Experimental Agriculture and Animal Husbandry 15, 663–670.Google Scholar

Jones, R. J. (1981) The use of natural carbon isotope ratios in studies with grazing animals. In Forage Evaluation: Concepts and Techniques. (Eds Wheeler, J. L. & Mochrie, R. D.), pp. 227–285. Armidale, NSW, Australia: CSIRO.Google Scholar

Jones, R. J., Ludlow, M. M., Troughton, J. H. & Blunt, C. G. (1979). Estimation of the proportion of C₃ and C₄ lant species in the diet of animals from the ratio of natural ¹²C and ¹³C isotopes in the faeces. Journal of Agricultural Science, Cambridge 92, 91–100.CrossRef Google Scholar

Lambourne, L. J. (1957). Measurement of feed intake of grazing sheep. 1. Rate of passage of inert reference materials through the ruminant digestive tract. Journal of Agricultural Science, Cambridge 48, 273–285.CrossRef Google Scholar

Le Feuvre, R. P. & Jones, R. J. (1988). The static combustion of biological samples sealed in glass tubes as a preparation for δS¹³C determination. The Analyst 113, 817–823.CrossRef Google Scholar PubMed

Lourenço, A. J., Matsui, E. & Arcaro, I. (1984). Variações de valores de delta ¹³C nas fezes, leite e sangue de vacas em lactacao mantidas em pastagens exclusivas de gramineas ou consorciadas. Boletim de Industria Animal 41, 183–192.Google Scholar

McManus, W. R. (1980). Oesophageal fistulation technique as an aid to diet evaluation of the grazing ruminant. In Forage Evaluation: Concepts and Techniques.(Eds Wheeler, J. L. & Mochrie, R. D.), pp. 249–260. Armidale, NSW, Australia: CSIROGoogle Scholar

t Mannetje, L. & Haydock, R. P. (1963). The dry-weightrank method for the botanical analysis of pasture. Journal of the British Grassland Society 18, 268–275.CrossRef Google Scholar

Minson, D. J. (1966). The apparent retention of food in the reticulo-rumen at two levels of feeding by means of an hourly feeding technique. British Journal of Nutrition 20, 765–773.CrossRef Google Scholar PubMed

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Südekum, K. H. Ziggers, W. Roos, N. Sick, H. Tamminga, S. and Stangassinger, M. 1995. Estimating the Passage of Digesta in Steers and Wethers Using the Ratio of13C to12C and Titanium(Iv)-oxide. Isotopes in Environmental and Health Studies, Vol. 31, Issue. 2, p. 219.

Witt, G.Bradd and Ayliffe, Linda K. 2001. Carbon Isotope Variability in the Bone Collagen of Red Kangaroos (Macropus rufus) is Age Dependent: Implications for Palaeodietary Studies. Journal of Archaeological Science, Vol. 28, Issue. 3, p. 247.

Sponheimer, Matt Robinson, Todd Ayliffe, Linda Passey, Ben Roeder, Beverly Shipley, Lisa Lopez, Elvia Cerling, Thure Dearing, Denise and Ehleringer, Jim 2003. An experimental study of carbon-isotope fractionation between diet, hair, and feces of mammalian herbivores. Canadian Journal of Zoology, Vol. 81, Issue. 5, p. 871.

Bol, Roland Eriksen, Jorgen Smith, Pete Garnett, Mark H. Coleman, Kevin and Christensen, Bent T. 2005. The natural abundance of 13C, 15N, 34S and 14C in archived (1923–2000) plant and soil samples from the Askov long‐term experiments on animal manure and mineral fertilizer. Rapid Communications in Mass Spectrometry, Vol. 19, Issue. 22, p. 3216.

Magid, J. De Neergaard, A. and Brandt, M. 2006. Heterogeneous distribution may substantially decrease initial decomposition, long‐term microbial growth and N‐immobilization from high C‐to‐N ratio resources. European Journal of Soil Science, Vol. 57, Issue. 4, p. 517.

Codron, Daryl Lee-Thorp, Julia A. Sponheimer, Matt and Codron, Jacqui 2007. Stable carbon isotope reconstruction of ungulate diet changes through the seasonal cycle. South African Journal of Wildlife Research, Vol. 37, Issue. 2, p. 117.

Hwang, Y.T. Millar, J.S. and Longstaffe, F.J. 2007. Do δ15N and δ13C values of feces reflect the isotopic composition of diets in small mammals?. Canadian Journal of Zoology, Vol. 85, Issue. 3, p. 388.

Codron, D. Codron, J. Lee‐Thorp, J. A. Sponheimer, M. De Ruiter, D. Sealy, J. Grant, R. and Fourie, N. 2007. Diets of savanna ungulates from stable carbon isotope composition of faeces. Journal of Zoology, Vol. 273, Issue. 1, p. 21.

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Codron, Daryl and Codron, Jacqui 2009. Reliability of δ13C and δ15N in faeces for reconstructing savanna herbivore diet. Mammalian Biology, Vol. 74, Issue. 1, p. 36.

Dixon, Rob and Coates, David 2009. Review: Near Infrared Spectroscopy of Faeces to Evaluate the Nutrition and Physiology of Herbivores. Journal of Near Infrared Spectroscopy, Vol. 17, Issue. 1, p. 1.

Wittmer, M.H.O.M. Auerswald, K. Schönbach, P. Schäufele, R. Müller, K. Yang, H. Bai, Y.F. Susenbeth, A. Taube, F. and Schnyder, H. 2010. Do grazer hair and faeces reflect the carbon isotope composition of semi-arid C3/C4 grassland?. Basic and Applied Ecology, Vol. 11, Issue. 1, p. 83.

White, I. A. Hunt, L. P. Poppi, D. P. and Petty, S. R. 2010. Sampling requirements for predicting cattle diet quality using faecal near-infrared reflectance spectroscopy (F.NIRS) in heterogeneous tropical rangeland pastures. The Rangeland Journal, Vol. 32, Issue. 4, p. 435.

Macedo, Robert Tarré, Ricardo Martinez Ferreira, Elvino Rezende, Claudia de Paula Pereira, José Marques Cadisch, Georg Rouws, Janaina Ribeiro Costa Alves, Bruno José Rodrigues Urquiaga, Segundo and Boddey, Robert Michael 2010. Forage intake and botanical composition of feed for cattle fed Brachiaria/legume mixtures. Scientia Agricola, Vol. 67, Issue. 4, p. 384.

Klevenhusen, F. Bernasconi, S. M. Kreuzer, M. and Soliva, C. R. 2010. Experimental validation of the Intergovernmental Panel on Climate Change default values for ruminant-derived methane and its carbon-isotope signature. Animal Production Science, Vol. 50, Issue. 3, p. 159.

Codron, Jacqueline Codron, Daryl Lee-Thorp, Julia A. Sponheimer, Matt Kirkman, Kevin Duffy, Kevin J. and Sealy, Judith 2011. Landscape-scale feeding patterns of African elephant inferred from carbon isotope analysis of feces. Oecologia, Vol. 165, Issue. 1, p. 89.

Hatch, K. A. Roeder, B. L. Buckman, R. S. Gale, B. H. Bunnell, S. T. Eggett, D. L. Auger, J. Felicetti, L. A. and Hilderbrand, G. V. 2011. Isotopic and gross fecal analysis of American black bear scats. Ursus, Vol. 22, Issue. 2, p. 133.

Codron, Daryl Codron, Jacqui Sponheimer, Matt Bernasconi, Stefano M. and Clauss, Marcus 2011. When animals are not quite what they eat: diet digestibility influences13C-incorporation rates and apparent discrimination in a mixed-feeding herbivore. Canadian Journal of Zoology, Vol. 89, Issue. 6, p. 453.

Finstad, Gregory L. and Kielland, Knut 2011. Landscape Variation in the Diet and Productivity of Reindeer in Alaska Based on Stable Isotope Analyses. Arctic, Antarctic, and Alpine Research, Vol. 43, Issue. 4, p. 543.

Coates, D.B. and Dixon, R.M. 2011. Developing Robust Faecal near Infrared Spectroscopy Calibrations to Predict Diet Dry Matter Digestibility in Cattle Consuming Tropical Forages. Journal of Near Infrared Spectroscopy, Vol. 19, Issue. 6, p. 507.

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Changes in faecal δ13C in response to changing proportions of legume (C3) and grass (C4) in the diet of sheep and cattle

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This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Changes in faecal δ13C in response to changing proportions of legume (C3) and grass (C4) in the diet of sheep and cattle

Summary

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References

REFERENCES

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