Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Wildlife Research Wildlife Research Society
Ecology, management and conservation in natural and modified habitats
RESEARCH ARTICLE

Can outbreaks of house mice in south-eastern Australia be predicted by weather models?

Charles J. Krebs A B D , Alice J. Kenney A , Grant R. Singleton A , Greg Mutze C , Roger P. Pech A , Peter R. Brown A and Stephen A. Davis A
+ Author Affiliations
- Author Affiliations

A CSIRO Sustainable Ecosystems, GPO Box 284, Canberra, ACT 2601, Australia.

B Department of Zoology, University of British Columbia, 6270 University Boulevard, Vancouver, B.C. V6T 1Z4, Canada.

C Animal and Plant Control Commission, GPO Box 2834, Adelaide, SA 5001, Australia.

D Corresponding author. Email: Charles.Krebs@csiro.au

Wildlife Research 31(5) 465-474 https://doi.org/10.1071/WR03131
Submitted: 24 December 2003  Accepted: 24 June 2004   Published: 13 December 2004

Abstract

Outbreaks of house mice (Mus domesticus) occur irregularly in the wheat-growing areas of south-eastern Australia, and are thought to be driven by weather variability, particularly rainfall. If rainfall drives grass and seed production, and vegetation production drives mouse dynamics, we should achieve better predictability of mouse outbreaks by the use of plant-production data. On a broader scale, if climatic variability is affected by El Niño–Southern Oscillation (ENSO) events, large-scale weather variables might be associated with mouse outbreaks. We could not find any association of mouse outbreaks over the last century with any ENSO measurements or other large-scale weather variables, indicating that the causal change linking mouse numbers with weather variation is more complex than is commonly assumed. For the 1960–2002 period we were only partly successful in using variation in cereal production to predict outbreaks of mice in nine areas of Victoria and South Australia, and we got better predictability of outbreaks from rainfall data alone. We achieved 70% correct predictions for a qualitative model using rainfall and 58% for a quantitative model using rainfall and spring mouse numbers. Without the detailed specific mechanisms underlying mouse population dynamics, we may not be able to improve on these simple models that link rainfall to mouse outbreaks.


Acknowledgments

We thank Dean Jones, Micah Davies, Colin Tann, Pip Masters, Jason Cody, and Fiona Cavanaugh for their efforts in collecting the house mouse data from the Walpeup area, and David Chinner, Frank Anderson and students from Roseworthy Agricultural College for collecting data from Roseworthy. This study was funded by the Grains Research and Development Corporation (CSV 15) and the Pest Animal Control CRC.


References

Bomford, M. (1987). Food and reproduction of wild house mice. II. A field experiment to examine the effect of food availability and food quality on breeding in spring. Australian Wildlife Research 14, 197–206.
Cantrill S. (1991). The population dynamics of the house mouse (Mus domesticus) in an unstable agricultural ecosystem. Ph.D. Thesis, Queensland Institute of Technology.

Caughley J. , Monamy V. , and Heiden K. (1994). Impact of the 1993 mouse plague. Grains Research & Development Corporation Occasional Paper Series No. 7. 73 pp.

Davis, S. A. , Leirs, H. , Pech, R. , Zhang, Z. , and Stenseth, N. C. (2004). On the economic benefit of predicting rodent outbreaks in agricultural systems. Crop Protection 23, 305–314.
Hamblin A. , and Kyneur G. (1993). ‘Trends in Wheat Yields and Soil Fertility in Australia.’ (Department of Primary Industries and Energy, Bureau of Resource Sciences: Canberra.)

Holmgren, M. , Scheffer, M. , Ezcurra, E. , Gutierrez, J. R. , and Mohren, G. M. J. (2001). El Niño effects on the dynamics of terrestrial ecosystems. Trends in Ecology & Evolution 16, 89–94.
Crossref | GoogleScholarGoogle Scholar | Kenney A. J. , Krebs C. J. , Davis S. , Pech R. , Mutze G. , and Singleton G. R. (2003). Predicting house mouse outbreaks in the wheat-growing areas of south-eastern Australia. In ‘Rats, Mice and People: Rodent Biology and Management’. (Eds G. R. Singleton, L. A. Hinds, C. J. Krebs and D. M. Spratt.) pp. 325–328. (Australian Centre for International Agricultural Research: Canberra.)

Krebs, C. J. , Chitty, D. , Singleton, G. R. , and Boonstra, R. (1995). Can changes in social behaviour help to explain house mouse plagues in Australia? Oikos 73, 429–434.
Montgomery D. C. , Peck E. A. , and Vining G. G. (2001). ‘Introduction to Linear Regression Analysis.’ 3rd edn. (Wiley: New York.)

Mutze, G. J. (1989). Mouse plagues in South Australian cereal-growing areas. I. Occurrence and distribution of plagues from 1900 to 1984. Australian Wildlife Research 16, 677–683.
Pech R. , Hood G. M. , Davis S. , and Singleton G. R. (2001). Models for forecasting and managing mouse plagues. In ‘Proceedings of the 12th Australasian Vertebrate Pest Conference, Melbourne’. pp. 65–69.

Pech R. P. , Hood G. M. , Singleton G. R. , Salmon E. , Forrester R. I. , and Brown P. R. (1999). Models for predicting plagues of house mice (Mus domesticus) in Australia. In ‘Ecologically-based Management of Rodent Pests’. (Eds G. R. Singleton, L. A. Hinds, H. Leirs and Z. Zhang.) pp. 81–112. (Australian Centre for International Agricultural Research: Canberra.)

Redhead, T. , and Singleton, G. (1988). The PICA strategy for the prevention of losses caused by plagues of Mus domesticus in rural Australia. EPPO Bulletin 18, 237–248.
Singleton G. R. , and Redhead T. D. (1989). House mouse plagues. In ‘Mediterranean Landscapes in Australia – Mallee Ecosystems and Their Management’. (Eds J. C. Noble and R. A. Bradstock.) pp. 418–433. (CSIRO: Melbourne.)

Singleton, G. R. , and Redhead, T. D. (1990). Structure and biology of house mouse populations that plague irregularly: an evolutionary perspective. Biological Journal of the Linnean Society 41, 285–300.
Thornthwaite C. W. , and Mather J. R. (1957). ‘Instructions and Tables for Computing Potential Evapotranspiration and the Water Balance.’ (Drexel Institute of Technology, Laboratory of Climatology: Centerton, NJ.)

Thresher, R. E. (2002). Solar correlates of Southern Hemisphere mid-latitude climatic variability. International Journal of Climatology 22, 901–915.
Crossref | GoogleScholarGoogle Scholar | Wang Q. J. (2001). ‘Climatic Atlas of Australia: Evapotranspiration.’ (Australian Bureau of Meteorology: Melbourne.)

White, T. C. R. (2002). Outbreaks of house mice in Australia: limitation by a key resource. Australian Journal of Agricultural Research 53, 505–509.
Crossref | GoogleScholarGoogle Scholar |

Ylönen, H. , Jacob, J. , Runcie, M. J. , and Singleton, G. R. (2003). Is reproduction of the Australian house mouse (Mus domesticus) constrained by food: a large-scale field experiment? Oecologia 135, 372–377.