Seasonal changes in the diet of the long-nosed bandicoot (Perameles nasuta) assessed by analysis of faecal scats and of stable isotopes in blood
Michele Thums A C , Marcel Klaassen B and Ian D. Hume A DA School of Biological Sciences A08, University of Sydney, NSW 2006, Australia.
B Department of Plant–Animal Interactions, Centre for Limnology, Netherlands Institute of Ecology, PO Box 1299, 3600 BG Maarssen, The Netherlands.
C Present address: School of Zoology, University of Tasmania, Hobart, Tas. 7005, Australia.
D Corresponding author. Email: ianhume@bio.usyd.edu.au
Australian Journal of Zoology 53(2) 87-93 https://doi.org/10.1071/ZO04030
Submitted: 16 April 2004 Accepted: 3 February 2005 Published: 6 April 2005
Abstract
The diet of long-nosed bandicoots (Perameles nasuta) on the central coast of New South Wales, Australia, was examined over two summers and two winters using a combination of faecal scat analysis for food fragments and stable isotope analysis (ratios of 13C/12C and 15N/14N) of blood. Isotope ratios in blood overlapped most strongly with those in invertebrate prey, and varied much less between seasons than did those in most dietary items, suggesting that the assimilated diet of long-nosed bandicoots is dominated by invertebrates throughout the year. Invertebrate remains dominated collected faeces in both seasons, even though the availability of invertebrate prey was higher in summer. Thus both techniques indicated that long-nosed bandicoots were primarily insectivorous year-round. Faecal scat analysis indicated that invertebrate eggs were more abundant in summer than winter. At a finer scale, spiders, orthopterans, lepidopteran larvae, ants, leaf material (non-grass monocot) and seeds were more abundant in summer, while cicada larvae, roots, fungi, grass leaves and Acacia bract (small modified leaves appearing as scales) were more abundant in winter. Subterranean foods (cicada larvae, plant roots and hypogeous fungi) were more abundant in winter and more abundant in the diet of males than of either lactating or non-lactating females.
Acknowledgments
We thank Evelyn Chia and Brett Parker for help in trapping bandicoots, Damien Higgins for assistance in obtaining blood samples, Peter McGee for identifying fungal samples, Dennis McNevin for help in drying the blood samples, and Vergilio Floris, Harry Korthals, Joop Nieuwenhuize and Roel Pel for the stable isotope ratio analyses. The bandicoots were trapped under the provisions of Licence A158 from the NSW National Parks and Wildlife Service. The study was supported by a Sesqui R & D Grant from the University of Sydney to IDH and a grant from the Schure-Beijerinck-Popping Foundation to MK. This is publication 3431 NIOO-KNAW of the Netherlands Institute of Ecology.
Broughton, S. K. , and Dickman, C. R. (1991). The effect of supplementary food on home range of the southern brown bandicoot, Isoodon obesulus (Marsupialia: Peramelidae). Australian Journal of Ecology 16, 71–78.
Dickman, C. R. , and Huang, C. (1988). The reliability of faecal analysis as a method for determining the diet of insectivorous mammals. Journal of Mammalogy 69, 108–113.
Greenslade, P. J. M. (1964). Pitfall trapping as a method for studying populations of Carabidae (Coleoptera). Journal of Animal Ecology 33, 301–310.
Hurtubia, J. (1973). Trophic diversity measurement in sympatric predatory species. Ecology 54, 885–890.
