Lagomorph and sheep effects on vegetation growth in dry and mesic grasslands in Otago, New Zealand
Michael P. Scroggie A , John P. Parkes B F , Grant Norbury C , Ben Reddiex D and Richard Heyward EA Arthur Rylah Institute for Environmental Research, Department of Sustainability and Environment, PO Box 137, Heidelberg, Vic. 3084, Australia.
B Landcare Research, PO Box 40, Lincoln, 7640, New Zealand.
C Landcare Research, PO Box 282, Alexandra, 9340, New Zealand.
D Department of Conservation, PO Box 5086, Wellington, 6145, New Zealand.
E Waldron Road, Road 1, Alexandra, New Zealand.
F Corresponding author. Email: parkesj@landcareresearch.co.nz
Wildlife Research 39(8) 721-730 https://doi.org/10.1071/WR11209
Submitted: 22 December 2011 Accepted: 31 October 2012 Published: 3 December 2012
Abstract
Context. Rabbits (Oryctolagus cuniculus) are major pests in the semiarid grasslands of eastern South Island. As the benefits of a viral biological control agent (rabbit haemorrhagic disease virus) introduced in 1997 begin to wane, landowners are again faced with the costs of controlling rabbits.
Aim. The study aimed to measure the extent of vegetation growth as rabbit and sheep densities changed to enable land managers to better justify decisions on pest and stock management.
Methods. We investigated the relationship between seasonal growth of vegetation at two replicate sites within each of three rabbit-prone areas in Otago. At these sites, the ambient densities of lagomorphs varied naturally and in response to pest-control operations, whereas the density of domestic sheep (Ovis aries) varied according to the farmers’ husbandry needs. The vegetation was highly degraded at one of the areas studied. Rabbits were present at all three sites and hares (Lepus europaeus) at two sites. At each site, we established exclosures that excluded either all herbivores or just sheep. The observed rates of vegetation growth were modelled as a function of prevailing herbivore densities, season and site. The fitted model was used to infer expected rates of change in vegetation biomass at the sites, under varying sheep and lagomorph density indices, and seasons.
Key results. In the absence of herbivores, vegetation was predicted to grow in all seasons apart from winter at the degraded sites. In the absence of sheep but in the presence of up to ~10 lagomorphs seen per kilometre of spotlight transect, accumulation of vegetation biomass follows the same seasonal pattern as in the absence of herbivores. As lagomorph counts reach 50 per kilometre, vegetation biomass accumulates only in spring and summer and only at the least degraded sites. The maximum stocking rates for sheep for which positive biomass accumulation could be maintained under varying lagomorph densities was predicted from the model.
Conclusions. At the least degraded sites some sheep could be grazed while maintaining positive pasture growth, even at high rabbit densities, except in winter if rabbit-density indices exceeded ~30 per kilometre. At the most degraded sites, a very low density of sheep could be maintained, but only in spring and only if lagomorph density indices were below ~10 per kilometre.
Additional keywords: bioeconomics, grazing impacts, hares, herbivory, pest control, rabbits.
References
Barlow, N. D. (1987). Pastures, pests and productivity: simple grazing models with two herbivores. New Zealand Journal of Ecology 10, 43–55.Blay, G. (1989). Food preferences of the European hare (Lepus europaeus Pallas) on a fescue grassland. M.Sc. Thesis, University of Canterbury, Christchurch, New Zealand.
Bolker, B. M., Brooks, M. E., Clark, C. J., Geange, S. W., Poulsen, J. R., Stevens, M. H. H., and White, J. S. (2009). Generalized linear mixed models: a practical guide for ecology and evolution. Trends in Ecology & Evolution 24, 127–135.
| Generalized linear mixed models: a practical guide for ecology and evolution.Crossref | GoogleScholarGoogle Scholar |
Caley, P. A., and Morley, C. G. (2002). Assessing growth rates of European rabbit populations using spotlight transects. The Journal of Wildlife Management 66, 131–137.
| Assessing growth rates of European rabbit populations using spotlight transects.Crossref | GoogleScholarGoogle Scholar |
Choquenot, D., and Parkes, J. (2001). Setting thresholds for pest control: how does pest density affect resource viability? Biological Conservation 99, 29–46.
| Setting thresholds for pest control: how does pest density affect resource viability?Crossref | GoogleScholarGoogle Scholar |
Glen, A. S., Byrom, A. E., Pech, R. P., Cruz, J., Schwab, A., Sweetapple, P. J., Yockney, I., Nugent, G., Coleman, M., and Whitford, J. (2012). Ecology of brushtail possums in a New Zealand dryland ecosystem. New Zealand Journal of Ecology 36, 29–37.
Hadfield, J. (2010). MCMC methods for multi-response generalized linear mixed models: the MCMCglmm R package. Journal of Statistical Software 33, 1–22.
Haydock, K. P., and 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.
Hone, J. (1999). On rate of increase (r): patterns of variation in Australian mammals and the implications for wildlife management. Journal of Applied Ecology 36, 709–718.
| On rate of increase (r): patterns of variation in Australian mammals and the implications for wildlife management.Crossref | GoogleScholarGoogle Scholar |
Hone, J. (2006). Linking pasture, livestock productivity and vertebrate pest management. New Zealand Journal of Ecology 30, 13–23.
Kerr, I. G. C., Costello, E. J., and Leathers, K. L. (1983). The economics of rabbit control in central Otago. Centre for Resource Management, Lincoln College and University of Canterbury report (unpublished). Lincoln, New Zealand.
Lough, R. S. (2009). The current state of rabbit management in New Zealand. Report for MAF Biosecurity. Wellington, New Zealand.
McGlone, M. S. (2001). The origin of the indigenous grasslands of southeastern South Island in relation to pre-human woody ecosystems. New Zealand Journal of Ecology 25, 1–16.
Norbury, D. C., and Norbury, G. L. (1996). Short-term effects of rabbit grazing on a degraded short-tussock grassland in Central Otago. New Zealand Journal of Ecology 20, 285–288.
Norbury, G., and Reddiex, B. (2005). European rabbit. In ‘The Handbook of New Zealand Mammals’. 2nd edn. (Ed. C. M. King.) pp. 131–150. (Oxford University Press: Melbourne.)
Norbury, G., Heyward, R., and Parkes, J. (2002). Short-term ecological effects of rabbit haemorrhagic disease in the short-tussock grasslands of the South Island, New Zealand. Wildlife Research 29, 599–604.
| Short-term ecological effects of rabbit haemorrhagic disease in the short-tussock grasslands of the South Island, New Zealand.Crossref | GoogleScholarGoogle Scholar |
Norton, D. A., Espie, P. R., Murray, W., and Murray, J. (2006). Influence of pastoral management on plant diversity in a depleted short tussock grassland, Mackenzie basin. New Zealand Journal of Ecology 30, 335–344.
Nugent, G., Twigg, L. E., Warburton, B., McGlinchy, A., Fisher, P., Gormley, A. M., and Parkes, J. P. (2012). Why 0.02? A review of the basis for current practice in aerial 1080 baiting for rabbits in New Zealand. Wildlife Research 39, 89–103.
| Why 0.02? A review of the basis for current practice in aerial 1080 baiting for rabbits in New Zealand.Crossref | GoogleScholarGoogle Scholar |
Parkes, J. P., and Forsyth, D. M. (2008). Interspecific and seasonal dietary differences of Himalayan thar, chamois and brushtail possums in the central southern Alps, New Zealand. New Zealand Journal of Ecology 32, 46–56.
Parkes, J. P., Glentworth, B., and Sullivan, G. (2008). Changes in immunity to rabbit haemorrhagic disease virus, and in abundance and rates of increase of wild rabbits in Mackenzie Basin, New Zealand. Wildlife Research 35, 775–779.
| Changes in immunity to rabbit haemorrhagic disease virus, and in abundance and rates of increase of wild rabbits in Mackenzie Basin, New Zealand.Crossref | GoogleScholarGoogle Scholar |
Parliamentary Commissioner for the Environment (1991). Sustainable use for the dry tussock grasslands in the South Island. Parliamentary Commission for the Environment, Wellington, New Zealand.
R Development Core Team (2009). ‘R: A Language and Environment for Statistical Computing.’ (R Foundation for Statistical Computing: Vienna, Austria.)
Radcliffe, J. E., and Cossens, G. G. (1974). Seasonal distribution of pasture production in New Zealand. III Central Otago. New Zealand Journal of Experimental Agriculture 2, 349–358.
| Seasonal distribution of pasture production in New Zealand. III Central Otago.Crossref | GoogleScholarGoogle Scholar |
Reddiex, B. (1998). Diet selection of European rabbits (Oryctolagus cuniculus) in the semi-arid grasslands of the Mackenzie Basin, New Zealand. M.Sc. Thesis, Lincoln University, Lincoln, New Zealand.
Short, J. (1985). The functional response of kangaroos, sheep and rabbits in an arid grazing system. Journal of Applied Ecology 22, 435–447.
| The functional response of kangaroos, sheep and rabbits in an arid grazing system.Crossref | GoogleScholarGoogle Scholar |
Warburton, B., and Frampton, C. (1994). Evaluation of the McLean scale for scoring relative rabbit abundance. Unpublished contract report (LC9495/049). Landcare Research, Lincoln, New Zealand.
Williams, J. M. (1977). A possible basis for economic rabbit control in New Zealand. Proceedings of the New Zealand Ecological Society 24, 132–135.