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Effects of resource limitation on habitat usage by the browser guild in Hluhluwe-iMfolozi Park, South Africa

Published online by Cambridge University Press:  14 February 2013

Christopher A. J. O'Kane ,
Kevin J. Duffy ,
Bruce R. Page  and
David W. Macdonald
Christopher A. J. O'Kane*
Affiliation:
Wildlife Conservation Research Unit, Zoology Department, University of Oxford, The Recanati-Kaplan Centre, Tubney House, Tubney, Oxon OX13 5QL, UK
Kevin J. Duffy
Affiliation:
Institute of Systems Science, Durban University of Technology, P.O. Box 1334, Durban 4000, South Africa
Bruce R. Page
Affiliation:
School of Biological and Conservation Sciences, Westville Campus, University of KwaZulu Natal, Private Bag X 54001, Durban 4000, South Africa
David W. Macdonald
Affiliation:
Wildlife Conservation Research Unit, Zoology Department, University of Oxford, The Recanati-Kaplan Centre, Tubney House, Tubney, Oxon OX13 5QL, UK
*
1Corresponding author. Email: christopher.okane@zoo.ox.ac.uk
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Abstract:

Resource depletion and associated increases in interspecific competition are likely to influence differential habitat usage amongst a guild. We tested some prominent theoretical concepts using observed differences in seasonal habitat use amongst the savanna browser guild (elephant, giraffe, impala, kudu and nyala) in Hluhluwe-iMfolozi Park, South Africa. Herbivore locations (n = 3108) were recorded over 2 y using repeated road transects and, for elephant, GPS collars (187 254 downloads). Densities were calculated using a novel GIS approach designed to be a cost-effective method for annual censuses, but also able to cope with abrupt changes in visibility. Selectivity for (Manly's α) vegetation types, and overlap (Schoener's index) in vegetation type usage were calculated. Resource depletion in the dry season resulted in all members of the guild increasing selectivity for vegetation types (sum of absolute values away from the neutral value for Manly's alpha for the guild: dry seasons 3.97, 5.16; corresponding wet seasons 3.12, 3.68), but decreasing interspecific overlap (80% of Schoener's indices lower in dry season versus wet season). These effects were more marked over the second, more severe, dry season. We found support for the niche overlap hypothesis and the niche compression hypothesis. The Jarman–Bell principle was generally supported, although unexpectedly during the severe dry season elephant showed the most selectivity for vegetation type. The greater the resource depletion, the more relevant interspecific differences in habitat usage become in relation to the differential impacts of guild members.

Keywords

browserscompetitionelephantgiraffeGISimpalakudunichenyalasavannaselectivity
Type
Research Article
Information
Journal of Tropical Ecology , Volume 29 , Issue 1 , January 2013 , pp. 39 - 47
Copyright
Copyright © Cambridge University Press 2013

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References

LITERATURE CITED

ABRAMS, P. 1980. Some comments on measuring niche overlap. Ecology 61:4449.CrossRefGoogle Scholar
ANDERSON, J. L. 1978. Aspects of the ecology of the nyala (Tragelaphus angasi Gray 1849) in Zululand. PhD dissertation. Imperial College, University of London, London.Google Scholar
BAGCHI, S., GOYAL, S. P. & SANKAR, K. 2003. Niche relationships of an ungulate assemblage in a dry tropical forest. Journal of Mammalogy 84:981988.CrossRefGoogle Scholar
BELL, R. H. V. 1970. The use of the herb layer by grazing ungulates in the Serengeti. Pp. 111124 in Watson, A. (ed.). Animal populations in relation to their food resources. Blackwell Scientific Publications, Oxford.Google Scholar
BELL, R. H. V. 1971. A grazing system in the Serengeti. Scientific American 225:8693.CrossRefGoogle Scholar
BELOVSKY, G. E. 1997. Optimal foraging and community structure: the allometry of herbivore food selection and competition. Evolutionary Ecology 11:641672.CrossRefGoogle Scholar
BODASING, T. 2008. Elephant movement and behaviour in Hluhluwe-iMfolozi Park. KZN Wildlife, Hluhluwe. 18 pp.Google Scholar
BODASING, T. 2011. Determinants of elephant spatial use, habitat selection and daily movement patterns in Hluhluwe-iMfolozi Park. MSc dissertation. University of KwaZulu Natal, Durban. 120 pp.Google Scholar
BONESI, L., CHANIN, P. & MACDONALD, D. W. 2004. Competition between Eurasian otter Lutra lutra and American mink Mustela vison probed by niche shift. Oikos 106:1926.CrossRefGoogle Scholar
BRODY, S., PROCTOR, R. C. & ASHWORTH, U. S. 1934. Growth and development with special reference to domestic animals, Part 34. Research Bulletin. Missouri Agricultural Experiment Station 220:32.Google Scholar
BROWN, J. S. 1988. Patch use as an indicator of habitat preference, predation risk, and competition. Behavioral Ecology and Sociobiology 22:3747.CrossRefGoogle Scholar
BUCKLAND, S. T., ANDERSON, D. R., BURNHAM, K. P., LAAKE, J. L., BORCHERS, D. L. & THOMAS, L. 2001. Introduction to distance sampling: estimating abundance of biological populations. Oxford University Press, Oxford. 416 pp.CrossRefGoogle Scholar
CLAUSS, M. & HUMMEL, J. 2005. The digestive performance of mammalian herbivores: why big may not be that much better. Mammal Review 35:174187.CrossRefGoogle Scholar
CROMSIGT, J., PRINS, H. H. T. & OLFF, H. 2009. Habitat heterogeneity as a driver of ungulate diversity and distribution patterns: interaction of body mass and digestive strategy. Diversity and Distributions 15:513522.CrossRefGoogle Scholar
DAGG, A. I. & FOSTER, J. B. 1976. The giraffe: its biology, behaviour and ecology. Van Nostrand Reinhold, New York. 210 pp.Google Scholar
DE KNEGT, H. J., GROEN, T. A., VAN DE VIJVER, C., PRINS, H. H. T. & VAN LANGEVELDE, F. 2008. Herbivores as architects of savannas: inducing and modifying spatial vegetation patterning. Oikos 117:543554.CrossRefGoogle Scholar
DEKKER, B., VAN ROOYEN, N. & BOTHMA, J. D. P. 1996. Habitat partitioning by ungulates on a game ranch in the Mopani veld. South African Journal of Wildlife Research 26:117122.Google Scholar
DEMMENT, M. W. & VAN SOEST, P. J. 1985. A nutritional explanation for body-size patterns of ruminant and nonruminant herbivores. American Naturalist 125:641672.CrossRefGoogle Scholar
DU TOIT, J. T. 1990. Home range–body mass relations: a field study on African browsing ruminants. Oecologia 85:301303.CrossRefGoogle Scholar
ELMHAGEN, B., TANNERFELDT, M. & ANGERBJOERN, A. 2002. Food-niche overlap between arctic and red foxes. Canadian Journal of Zoology 80:12741285.CrossRefGoogle Scholar
ESTES, R. D. 1991. The behavior guide to African mammals. University of California Press, Berkeley. 611 pp.Google Scholar
FERRAR, A. A. & WALKER, B. H. 1974. An analysis of herbivore–habitat relationships in Kyle National park, Rhodesia. Journal of the South African Wildlife Management Association 4:137147.Google Scholar
FIELD, C. R. & LAWS, R. M. 1970. The distribution of the larger herbivores in the Queen Elizabeth National Park, Uganda. Journal of Applied Ecology 7:273294.CrossRefGoogle Scholar
FLECKER, A. S. 1997. Habitat modification by tropical fishes: environmental heterogeneity and the variability of interaction strength. Journal of the North American Benthological Society 16:286295.CrossRefGoogle Scholar
FRANZ, R., HUMMEL, J., MULLER, D. W. H., BAUERT, M., HATT, J.-M. & CLAUSS, M. 2011. Herbivorous reptiles and body mass: effects on food intake, digesta retention, digestibility and gut capacity, and a comparison with mammals. Comparative Biochemistry and Physiology 158:94101.CrossRefGoogle Scholar
FRETWELL, S. D. & LUCAS, H. L. 1970. On territorial behavior and other factors influencing habitat distribution in birds. 1. Theoretical development. Acta Biotheoretica 14:1636.Google Scholar
FRITZ, H., DE GARINE-WICHATITSKY, M. & LETESSIER, G. 1996. Habitat use by sympatric wild and domestic herbivores in an African savanna woodland: the influence of cattle spatial behaviour. Journal of Applied Ecology 33:589598.CrossRefGoogle Scholar
GALLIVAN, G. J. & HORAK, I. G. 1997. Body size and habitat as determinants of tick infestations of wild ungulates in South Africa. South African Journal of Wildlife Research 27:6370.Google Scholar
GRAND, T. C. 2002. Alternative forms of competition and predation dramatically affect habitat selection under foraging-predation-risk trade-offs. Behavioural Ecology 13:280290.CrossRefGoogle Scholar
GRUNOW, J. O. 1980. Feed and habitat preferences among some large herbivores on African veld. Proceedings of the Grassland Society of South Africa 15:141146.CrossRefGoogle Scholar
HART, B. L., HART, L. A. & MOORING, M. S. 1990. Differential foraging of oxpeckers on impala in comparison with sympatric antelope species. African Journal of Ecology 28:240249.CrossRefGoogle Scholar
HUNGATE, R. E., PHILLIPS, G. D., MCGREGOR, A., HUNGATE, D. P. & BUECHNER, H. K. 1959. Microbial fermentation in certain animals. Science 130:11921194.CrossRefGoogle Scholar
ILLIUS, A. W. & GORDON, I. J. 1992. Modelling the nutritional ecology of ungulate herbivores – evolution of body size and competitive interactions. Oecologia 89:428434.CrossRefGoogle ScholarPubMed
IVLEV, V. S. 1961. Experimental ecology of the feeding of fishes. Yale University Press, New Haven. 302 pp.Google Scholar
JARMAN, P. J. 1972. Seasonal distribution of large mammal populations in the unflooded Middle Zambezi Valley. Journal of Applied Ecology 9:283299.CrossRefGoogle Scholar
JARMAN, P. J. 1974. The social organisation of antelope in relation to their ecology. Behaviour 48:215267.CrossRefGoogle Scholar
JONES, M. E. & BARMUTA, L. A. 2000. Niche differentiation among sympatric Australian dasyurid carnivores. Journal of Mammalogy 81:434447.2.0.CO;2>CrossRefGoogle Scholar
KREBS, J. R. 1999. Ecological methodology. Benjamin/Cummings, Menlo Park. 620 pp.Google Scholar
K.Z.N.WILDLIFE. 2008. Population Estimates for Hluhluwe-iMfolozi Park. K.Z.N. Wildlife, Hluhluwe. 14 pp.Google Scholar
LAMPREY, H. F. 1963. Ecological separation of the large mammal species in the Tarangire Game Reserve, Tanganyika. East African Wildlife Journal 1:6392.CrossRefGoogle Scholar
LAWS, R. M. 1970. Elephants as agents of habitat and landscape change in East Africa. Oikos 21:115.CrossRefGoogle Scholar
LECHOWICZ, M. J. 1982. The sampling characteristics of electivity indices. Oecologia 52:2230.CrossRefGoogle ScholarPubMed
LOVERIDGE, A. J. & MACDONALD, D. W. 2003. Niche separation in sympatric jackals (Canis mesomelas and Canis adustus). Journal of Zoology 259:143153.CrossRefGoogle Scholar
MACARTHUR, R. H. & PIANKA, E. R. 1966. On optimal use of a patchy environment. American Naturalist 100:603609.CrossRefGoogle Scholar
MADHUSUDAN, M. D. 2004. Recovery of wild large herbivores following livestock decline in a tropical Indian wildlife reserve. Journal of Applied Ecology 41:858869.CrossRefGoogle Scholar
MAKHABU, S. W. 2005. Resource partitioning within a browsing guild in a key habitat, the Chobe Riverfront, Botswana. Journal of Tropical Ecology 21:641649.CrossRefGoogle Scholar
MANLY, B. F. J., MILLER, P. & COOK, L. M. 1972. Analysis of a selective predation experiment. American Naturalist 106:719736.CrossRefGoogle Scholar
MORISITA, M. 1959. Measuring of interspecific association and similarity between communities. Memoirs of the Faculty of Science Kyushu University series E 3:6580.Google Scholar
MOSUGELO, D., MOE, S. R., RINGROSE, S. & NELLEMAN, C. 2002. Vegetation changes during a 36-year period in northern Chobe National Park, Botswana. African Journal of Ecology 40:232240.CrossRefGoogle Scholar
MUCINA, L. & RUTHERFORD, M. C. 2006. The vegetation of South Africa, Lesotho and Swaziland. South African National Biodiversity Institute, Pretoria. 807 pp.Google Scholar
NAPIER BAX, P. & SHELDRICK, D. L. W. 1963. Some preliminary observations on the food of elephant in the Tsavo Royal National Park (East) of Kenya. East African Wildlife Journal 1:4053.Google Scholar
O'KANE, C. A. J., DUFFY, K. J., PAGE, B. R. & MACDONALD, D. W. 2011. Overlap and seasonal shifts in use of woody plant species amongst a guild of savanna browsers. Journal of Tropical Ecology 27:249258.CrossRefGoogle Scholar
OLOFSSON, J., HULME, P. E., OKSANEN, L. & SUOMINEN, O. 2004. Importance of large and small mammalian herbivores for the plant community structure in the forest tundra ecotone. Oikos 106:324334.CrossRefGoogle Scholar
OLOO, T. W., BRETT, R. & YOUNG, T. P. 1994. Seasonal variation in the feeding ecology of the black rhinoceros (Diceros bicornis L.) in Laikipia, Kenya. African Journal of Ecology 32:142157.CrossRefGoogle Scholar
OWEN-SMITH, N. 1988. Megaherbivores: the influence of very large body size on ecology. Cambridge University Press, Cambridge. 300 pp.CrossRefGoogle Scholar
PELLEW, R. A. 1984. The feeding ecology of a selective browser, the giraffe (Giraffa camelopardalis). Journal of Zoology (London) 202:5781.CrossRefGoogle Scholar
PIANKA, E. R. 1972. r and K-selection or b and d selection? American Naturalist 106:581588.CrossRefGoogle Scholar
PIANKA, E. R. 1976. Competition and niche theory. Pp. 114141 in May, R. M. (ed.). Theoretical ecology. principles and applications. Blackwell Scientific Publications, Oxford.Google Scholar
POOLE, J. H., PAYNE, K., LANGBAUER, W. R. & MOSS, C. J. 1988. The social contexts of some very low frequency calls of African elephants. Behavioral Ecology and Sociobiology 22:385392.CrossRefGoogle Scholar
POOLEY, E. S. 2003. The complete field guide to trees of Natal, Zululand & Transkei. Natal Flora Publications Trust, Durban. 512 pp.Google Scholar
ROSENZWEIG, M. L. 1981. A theory of habitat selection. Ecology 62:327335.CrossRefGoogle Scholar
SCHOENER, T. W. 1974. Resource partitioning in ecological communities. Science 185:2739.CrossRefGoogle ScholarPubMed
SCHOLES, R. J. & MENNELL, K. G. 2008. Elephant management: a scientific assessment for South Africa. Wits University Press, Johannesburg. 645 pp.Google Scholar
SCHOOLEY, R. L. 1994. Annual variation in habitat selection: patterns concealed by pooled data. Journal of Wildlife Management 58:367374.CrossRefGoogle Scholar
SIMPSON, C. D. & COWRIE, D. 1967. The seasonal distribution of kudu Tragelaphus strepsiceros Pallas on a southern lowveld ranch in Rhodesia. Arnoldia 3:113.Google Scholar
STEPHENS, D. W. & KREBS, J. R. 1986. Foraging theory. Princeton University Press, Princeton. 262 pp.Google Scholar
TATMAN, S. C., STEVENS-WOOD, B. & SMITH, V. B. T. 2000. Ranging behaviour and habitat usage in black rhinoceros Diceros bicornis, in a Kenyan sanctuary. African Journal of Ecology 38:163172.CrossRefGoogle Scholar
VAN HOVEN, W., PRINS, R. A. & LANKHORST, A. 1981. Fermentative digestion in the African elephant. South African Journal of Wildlife Research 11:7886.Google Scholar
WALLACE, R. K. 1981. An assessment of diet-overlap indexes. Transactions of the American Fisheries Society 110:7276.2.0.CO;2>CrossRefGoogle Scholar
WECKERLY, F. W. 2009. Allometric scaling of rumen-reticulum capacity in white-tailed deer. Journal of Zoology 280:4148.CrossRefGoogle Scholar
WHATELEY, A. & PORTER, R. N. 1983. The woody vegetation communities of the Hluhluwe-Corridor-Umfolozi Game Reserve Complex. Bothalia 14:745758.CrossRefGoogle Scholar
WITTEMYER, G., GETZ, W. M., VOLLRATH, F. & DOUGLAS-HAMILTON, I. 2007. Social dominance, seasonal movements, and spatial segregation in African elephants: a contribution to conservation behavior. Behavioral Ecology and Sociobiology 61:19191931.CrossRefGoogle Scholar
WOLDA, H. 1981. Similarity indices, sample size and diversity. Oecologia 50:296302.CrossRefGoogle ScholarPubMed