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Rumen fermentation and food selection in East African sheep, goats, Thomson's gazelle, Grant's gazelle and impala

Published online by Cambridge University Press:  27 March 2009

P. P. Hoppe ,
S. A. Qvortrup  and
M. H. Woodford
P. P. Hoppe
Affiliation:
Department of Animal Physiology, University of Nairobi, Kenya
S. A. Qvortrup
Affiliation:
UNDP/FAO Kenya Wildlife Management Project, Nairobi, Kenya
M. H. Woodford
Affiliation:
UNDP/FAO Kenya Wildlife Management Project, Nairobi, Kenya
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Summary

The relationship between the selected food and rumen fermentation was investigated in Thomson's gazelle, Grant's gazelle, impala and Maasai haired sheep and goats. All animals were shot in the same grass-bushland area within 1 week during the dry season.

According to rumen contents, sheep were almost exclusively grazers. In goats, Thomson's gazelle and impala, grass accounted for about 70% of all plant parts identified. In Grant's gazelle, browse including Acacia seed constituted 68% of rumen ingesta. The two gazelle species showed a very marked preference for green grass leaves.

In sheep and goat rumens, concentrations of NH3-N and volatile fatty acids, and in vitro fermentation rates (262 and 272 μmoles gasNTPD/g D.M./h, respectively) were lowest. In the wild ruminants, concentrations of fermentation end-products were higher and the rate of fermentation significantly (P < 0·05) faster, namely 420 in Thomson's gazelle, 356 in Grant's gazelle and 376 in impala. Rumen pH was not significantly different between species, with mean values ranging between 6·3 and 6·0. Total VFA concentrations ranged between 124 and 178 m-equiv/1 in the rumen and around 25 m-equiv/1 in the abomasum. Acetic acid accounted for about 75% of the total VFAs.

It is concluded that there are large differences in the pattern of rumen fermentation between wild and domestic mixed-feeding ruminants which reflect their respective food preferences.

Type
Research Article
Information
The Journal of Agricultural Science , Volume 89 , Issue 1 , August 1977 , pp. 129 - 135
Copyright
Copyright © Cambridge University Press 1977

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References

Aafjes, J. H. (1967). The disappearance of volatile fatty acids through the rumen wall. Zeitschrift für Tierphysiologie, Tierernährung und Futtermittelkunde 22, 6975.Google ScholarPubMed
Allo, A. A., Oh, J. H., Longhurst, W. M. & Connolly, G. E. (1973). VFA production in the digestive systems of deer and sheep. Journal of Wildlife Management 37, 202–11.CrossRefGoogle Scholar
A.O.A.C. (1966). Official Methods of Analyses, 9th ed.Washington, D.C.: Association of Official Agricultural Chemists.Google Scholar
Church, D. C. (1969). Digestive Physiology and Nutrition of Ruminants, 316 pp. Oregon State University Book Stores.Google Scholar
Dougall, H. W., Drysdale, V. M. & Glover, P. E. (1964). The chemical composition of Kenya browse and pasture herbage. East African Wildlife Journal 2, 86121.CrossRefGoogle Scholar
Dougall, H. W. & Glover, P. E. (1964). On the chemical composition of Themeda triandra and Cynodon dactylon. East African Wildlife Journal 2, 6770.CrossRefGoogle Scholar
Engelhardt, W. von & Sallmann, H. P. (1972). Resorption und Sekretion im Pansen des Guanakos (Lama guanacoe). Zentralblatt fūr Veterinärmedizin A, 19, 117–32.CrossRefGoogle Scholar
Gwynne, M. D. (1969). The nutritive value of Acacia pods in relation to Acacia seed distribution by ungulates. East African Wildlife Journal 7, 176–8.Google Scholar
Gwynne, M. D. (1971). Selective food intake by some East African herbivores. A report to the UNDP/FAO Range Management Project in Kenya.Google Scholar
Hofmann, R. (1973). The ruminant stomach. Nairobi East African Literature Bureau, 354 pp.Google Scholar
Hoppe, P. P. (1977). Comparison of voluntary food and water consumption and digestion in Kirk's dikdik and suni. East African Wildlife Journal 15, 41–8.CrossRefGoogle Scholar
Hoppe, P. P., Qvortrup, S. A. & Woodford, M. H. (1977). Rumen fermentation and food selection in East African Zebu cattle, wildebeest, Coke's hartebeest and topi. Journal of Zoology (London) 181, 19.CrossRefGoogle Scholar
Hungate, R. E. (1950). The anerobic mesophyllic cellulolytic bacteria. Bacteriological Reviews 14, 149.CrossRefGoogle Scholar
Hungate, R. E. (1965). Quantitative aspects of the rumen fermentation. In Physiology of Digestion in the Ruminant (ed. Dougherty, R. W.), 480 pp. London: Butterworth.Google Scholar
Hungate, R. E. (1966). The Rumen and its Microbes, 533 pp. New York: Academic Press.Google Scholar
Hungate, R. E., Phillips, G. D.McGregor, A., Hungate, D. P. & Buechner, H. K. (1959). Microbial fermentation in certain mammals. Science 130, 1192–4.CrossRefGoogle ScholarPubMed
Ledger, H. P. (1968). Body composition as a basis for a comparable study of some East African mammals. In Comparative Nutrition of Wild Animals (ed. Crawford, M. A.). Symposium of the Zoological Society of London 21, 289310.Google Scholar
Pratt, D. J., Greenway, P. J. & Gwynne, M. D. (1966). A classification of East African rangeland, with an appendix on terminology. Journal of Applied Ecology 3, 369–82.CrossRefGoogle Scholar
Prins, R. A. & Geelen, M. J. H. (1971). Rumen characteristics of red deer, fallow deer and roe deer. Journal of Wildlife Management 35, 670–80.CrossRefGoogle Scholar
Talbot, L. M. & Talbot, M. H. (1962). Food preferences of some East African wild ungulates. East African Agriculture and Forestry Journal 27, 131–8.CrossRefGoogle Scholar
Van Gylswyk, N. O. & Giesecke, D. (1973). A summary of preliminary findings in a rumen microbiological investigation on wild ruminants. Koedoe 16, 191–4.CrossRefGoogle Scholar