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Ecology, management and conservation in natural and modified habitats
RESEARCH ARTICLE

Slow recruitment in a red-fox population following poison baiting: a non-invasive mark–recapture analysis

Oliver Berry A B E F , Jack Tatler A , Neil Hamilton B C , Steffi Hilmer C D , Yvette Hitchen A B and Dave Algar B C
+ Author Affiliations
- Author Affiliations

A School of Animal Biology (M092), The University of Western Australia, Crawley, WA 6009, Australia.

B Invasive Animals Co-operative Research Centre, Building 22, University of Canberra, University Drive South, Bruce, ACT 2617, Australia.

C Department of Parks and Wildlife, PO Box 51, Wanneroo, WA 6946, Australia.

D Johann Wolfgang Goethe-University, Frankfurt am Main 60323, Germany.

E Present address: CSIRO Marine and Atmospheric Research, PMB 5, Floreat, WA 6014, Australia.

F Corresponding author. Email: oliver.berry@csiro.au

Wildlife Research 40(7) 615-623 https://doi.org/10.1071/WR13073
Submitted: 16 April 2013  Accepted: 22 December 2013   Published: 30 January 2014

Abstract

Context: Optimal management of invasive species should determine the interval between lethal-control operations that will sustain a desired population suppression at minimum cost. This requires an understanding of the species’ rate of recruitment following control. These data are difficult to acquire for vertebrate carnivores such as the red fox (Vulpes vulpes), which are not readily trapped or observed.

Aims: To provide a long-term evaluation of the effects of 1080 poison baiting on the abundance and extent of movement of red foxes in a semiarid environment.

Methods: We used non‐invasive DNA sampling of fox hairs in semi-arid Western Australia where the population was subject to two episodes of aerially delivered sodium fluoroacetate (1080) poison baits within 12 months. Sampling took place at ~45-day intervals and individual foxes were identified by genotyping eight microsatellite DNA markers and a gender-specific marker. Open-population and spatially explicit mark–recapture models were used to estimate the density, apparent survival and movements of foxes before and following baiting.

Key results: Following a severe reduction in density after baiting, fox density during the ensuing 12 months increased slowly (0.01 foxes km–2 month–1), such that density had only reached 22% of pre-baiting levels ~10 months after the initial baiting. Moreover, recovery was non‐linear as population growth was negligible for 6 months, then exhibited a nine-fold increase 7–9 months after control, coincident with the dispersal of juveniles in autumn. Fox movements between recaptures were on average 470% greater after baiting than before, in line with expectations for low-density populations, suggesting that the probability of encountering baits during this period would be higher than before baiting.

Conclusions: Baiting with 1080 poison significantly reduced the density of foxes, and the low density was sustained for more than 6 months. Foxes moved significantly further between recaptures after baiting when at low densities.

Implications: Control programs in this region may be carried out at low frequency to suppress fox density to a fraction of unbaited levels. The intensity of follow-up baiting may also be adjusted downwards, to take account of an increased probability of bait encounter in more mobile foxes.


References

Algar, D., and Burrows, N. D. (2004). Feral cat control research: Western Shield review February 2003. Conservation Science Western Australia 5, 131–163.

Allen, S. H., and Sargeant, A. B. (1993). Dispersal patterns of red foxes relative to population density. The Journal of Wildlife Management 57, 526–533.
Dispersal patterns of red foxes relative to population density.Crossref | GoogleScholarGoogle Scholar |

Anderson, D. R. (2001). The need to get the basics right in wildlife field studies. Wildlife Society Bulletin 29, 1294–1297.

Arthur, T., Ramsey, D., and Efford, M. (2002). Changes in possum behaviour at reduced density: a review. Landcare Research Contract Report LC0102/102. Landcare Research, Palmerston North, New Zealand.

Baker, P. J., and Harris, S. (2006). Does culling reduce fox (Vulpes vulpes) density in commercial forests? European Journal of Wildlife Research 52, 99–108.
Does culling reduce fox (Vulpes vulpes) density in commercial forests?Crossref | GoogleScholarGoogle Scholar |

Baker, P. J., Funk, S. M., Harris, S., and White, P. C. L. (2000). Flexible spatial organization of urban foxes, Vulpes vulpes, before and during an outbreak of sarcoptic mange. Animal Behaviour 59, 127–146.
Flexible spatial organization of urban foxes, Vulpes vulpes, before and during an outbreak of sarcoptic mange.Crossref | GoogleScholarGoogle Scholar | 10640375PubMed |

Baxter, P. W., Sabo, J. L., Wilcox, C., McCarthy, M. A., and Possingham, H. P. (2008). Cost‐effective suppression and eradication of invasive predators. Conservation Biology 22, 89–98.
Cost‐effective suppression and eradication of invasive predators.Crossref | GoogleScholarGoogle Scholar | 18273952PubMed |

Berry, O., Algar, D., Angus, J., Hamilton, N., Hilmer, S., and Sutherland, D. (2012). Genetic tagging reveals a significant impact of poison baiting on an invasive species. The Journal of Wildlife Management 76, 729–739.
Genetic tagging reveals a significant impact of poison baiting on an invasive species.Crossref | GoogleScholarGoogle Scholar |

Bino, G., Dolev, A., Yosha, D., Guter, A., King, R., Saltz, D., and Kark, S. (2010). Abrupt spatial and numerical response of overabundant foxes to a reduction in anthropogenic resources. Journal of Applied Ecology 47, 1262–1271.
Abrupt spatial and numerical response of overabundant foxes to a reduction in anthropogenic resources.Crossref | GoogleScholarGoogle Scholar |

Borchers, D. L., and Efford, M. G. (2008). Spatially explicit maximum likelihood methods for capture–recapture studies. Biometrics 64, 377–385.
Spatially explicit maximum likelihood methods for capture–recapture studies.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DC%2BD1czhvVWlsA%3D%3D&md5=cdeee872d6b46a8432c56b10b0d8a36fCAS | 17970815PubMed |

Burnham, K. P., and Anderson, D. R. (2002). ‘Model Selection and Multimodel Inference – A Practical Information-Theoretic Approach.’ 2nd edn. (Springer-Verlag: New York.)

Cavallini, P. (1996). Variation in the social system of the red fox. Ethology Ecology and Evolution 8, 323–342.
Variation in the social system of the red fox.Crossref | GoogleScholarGoogle Scholar |

Chatterjee, S. (1973). A mathematical model for pest control. Biometrics 29, 727–734.
A mathematical model for pest control.Crossref | GoogleScholarGoogle Scholar |

Clobert, J., Dhondt, A. A., and Nichols, J. D. (Eds) (2001). ‘Dispersal.’ (Oxford University Press: Oxford, UK.)

Coman, B. J. (1988). The age structure of a sample of red foxes (Vulpes vulpes L.) taken by hunters in Victoria. Australian Wildlife Research 15, 223–229.
The age structure of a sample of red foxes (Vulpes vulpes L.) taken by hunters in Victoria.Crossref | GoogleScholarGoogle Scholar |

Efford, M. (2004). Density estimation in live-trapping studies. Oikos 106, 598–610.
Density estimation in live-trapping studies.Crossref | GoogleScholarGoogle Scholar |

Efford, M. G., Borchers, D. L., Byrom, A. E. (2009). Density estimation by spatially explicit capture–recapture: likelihood-based methods. In: ‘Environmental and Ecological Statistics. Modeling Demographic Processes in Marked Populations’. (Eds D. L. Thomson, E. G. Cooch and M. J. Conroy) Vol. 3, pp. 255–269. (Springer.)

Englund, J. (1980). Population dynamics of the red fox (Vulpes vulpes L., 1758) in Sweden. In ‘The Red Fox: Symposium on Behaviour and Ecology’. (Ed. E. Zimen.) pp. 107–122. (Dr. W Junk bv Publishers: The Hague, The Netherlands.)

Frantz, A. C., Pope, L. C., Carpenter, P. J., Roper, T. J., Wilson, G. J., Delahay, R. J., and Burke, T. (2003). Reliable microsatellite genotyping of the Eurasian badger (Meles meles) using faecal DNA. Molecular Ecology 12, 1649–1661.
Reliable microsatellite genotyping of the Eurasian badger (Meles meles) using faecal DNA.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3sXltlKhtLY%3D&md5=adeabf3e7537396822835eafe9ef2209CAS | 12755892PubMed |

Frey, S. N., and Conover, M. R. (2007). Influence of population reduction on predator home range size and spatial overlap. The Journal of Wildlife Management 71, 303–309.
Influence of population reduction on predator home range size and spatial overlap.Crossref | GoogleScholarGoogle Scholar |

Gentle, M., Saunders, G., and Dickman, C. (2007). Poisoning for production: how effective is fox baiting in south‐eastern Australia? Mammal Review 37, 177–190.
Poisoning for production: how effective is fox baiting in south‐eastern Australia?Crossref | GoogleScholarGoogle Scholar |

Greentree, C., Saunders, G., McLeod, L., and Hone, J. (2000). Lamb predation and fox control in south-eastern Australia. Journal of Applied Ecology 37, 935–943.
Lamb predation and fox control in south-eastern Australia.Crossref | GoogleScholarGoogle Scholar |

Harding, E. K., Doak, D., and Albertson, J. (2001). Evaluating the effectiveness of predator control: the non-native red fox as a case study. Conservation Biology 15, 1114–1122.
Evaluating the effectiveness of predator control: the non-native red fox as a case study.Crossref | GoogleScholarGoogle Scholar |

Harris, S., and Trewhella, W. (1988). An analysis of some of the factors affecting dispersal in an urban fox (Vulpes vulpes) population. Journal of Applied Ecology 25, 409–422.
An analysis of some of the factors affecting dispersal in an urban fox (Vulpes vulpes) population.Crossref | GoogleScholarGoogle Scholar |

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 |

Iossa, G., Soulsbury, C. D., Baker, P. J., Edwards, K. J., and Harris, S. (2009). Behavioral changes associated with a population density decline in the facultatively social red fox. Behavioral Ecology 20, 385–395.
Behavioral changes associated with a population density decline in the facultatively social red fox.Crossref | GoogleScholarGoogle Scholar |

Kinnear, J. E., Onus, M. L., and Bromilow, R. N. (1988). Fox control and rock-wallaby population dynamics. Australian Wildlife Research 15, 435–450.
Fox control and rock-wallaby population dynamics.Crossref | GoogleScholarGoogle Scholar |

Levins, R. (2006). Some demographic and genetic consequences of environmental heterogeneity for biological control. In ‘Foundation Papers in Landscape Ecology’. (Eds J. Weins, M. R. Moss, M. G. Turner and D. J. Mladenoff) pp. 237–240. (Columbia University Press: New York.)

Lloyd, H. G. (1980). Habitat requirements of the red fox. In ‘The Red Fox: Symposium on Behaviour and Ecology’. (Ed. E. Ziemen.) pp. 7–26. (Dr. W Junk bv Publishers: The Hague, The Netherlands.)

Lucchini, V., Fabbri, E., Marucco, F., Ricci, S., Boitani, L., and Randi, E. (2002). Noninvasive molecular tracking of colonising wolf (Canis lupus) packs in the western Italian Alps. Molecular Ecology 11, 857–868.
Noninvasive molecular tracking of colonising wolf (Canis lupus) packs in the western Italian Alps.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD38XksVKrs7s%3D&md5=655cfee7903a7f284dd30f6858930965CAS | 11975702PubMed |

Macdonald, D. (1977). ‘The Behavioural Ecology of the Red Fox. Rabies and Wildlife.’ (Ed. C. Kaplan.) pp. 70–90. (Oxford University Press: Oxford, UK.)

Macdonald, D. W. (1979). ‘Helpers’ in fox society. Nature 282, 69–71.
‘Helpers’ in fox society.Crossref | GoogleScholarGoogle Scholar |

Marlow, N. J., Thomson, P. C., Algar, D., Rose, K., Kok, N. E., and Sinagra, J. A. (2000). Demographic characteristics and social organisation of a population of red foxes in a rangeland area in Western Australia. Wildlife Research 27, 457–464.
Demographic characteristics and social organisation of a population of red foxes in a rangeland area in Western Australia.Crossref | GoogleScholarGoogle Scholar |

Marucco, F., Pletscher, D. H., Boitani, L., Schwartz, M. K., Pilgrim, K. L., and Lebreton, J.-D. (2009). Wolf survival and population trend using non-invasive capture–recapture techniques in the western Alps. Journal of Applied Ecology 46, 1003–1010.
Wolf survival and population trend using non-invasive capture–recapture techniques in the western Alps.Crossref | GoogleScholarGoogle Scholar |

McIlroy, J. C., Saunders, G. R., and Hinds, L. (2001). The reproductive performance of female red foxes, Vulpes vulpes, in central-western New South Wales during and after a drought. Canadian Journal of Zoology 79, 545–553.

McLeod, R. (2004). ‘Counting the Cost: Impact of Invasive Animals in Australia 2004.’ (Cooperative Research Centre for Pest Animal Control: Canberra.)

Meek, P. D., and Saunders, G. (2000). Home range and movement of foxes (Vulpes vulpes) in coastal New South Wales, Australia. Wildlife Research 27, 663–668.
Home range and movement of foxes (Vulpes vulpes) in coastal New South Wales, Australia.Crossref | GoogleScholarGoogle Scholar |

Moseby, K. E., and Read, J. L. (2006). The efficacy of feral cat, fox and rabbit exclusion fence designs for threatened species protection. Biological Conservation 127, 429–437.
The efficacy of feral cat, fox and rabbit exclusion fence designs for threatened species protection.Crossref | GoogleScholarGoogle Scholar |

Moseby, K. E., Stott, J., and Crisp, H. (2009). Movement patterns of feral predators in an arid environment – implications for control through poison baiting. Wildlife Research 36, 422–435.
Movement patterns of feral predators in an arid environment – implications for control through poison baiting.Crossref | GoogleScholarGoogle Scholar |

Piggott, M. P., Wilson, R., Banks, S. C., Marks, C. A., Gigliotti, F., and Taylor, A. C. (2008). Evaluating exotic predator control programs using non-invasive genetic tagging. Wildlife Research 35, 617–624.
Evaluating exotic predator control programs using non-invasive genetic tagging.Crossref | GoogleScholarGoogle Scholar |

Prugh, L. R., Ritland, C. E., Arthurs, M., and Krebs, C. J. (2005). Monitoring coyote population dynamics by genotyping faeces. Molecular Ecology 14, 1585–1596.
Monitoring coyote population dynamics by genotyping faeces.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2MXktleqsbg%3D&md5=b0b28c5d21b1b98930da4fe91fa7b8feCAS | 15813796PubMed |

Rushton, S., Shirley, M., MacDonald, D., and Reynolds, J. (2006). Effects of culling fox populations at the landscape scale: a spatially explicit population modelling approach. The Journal of Wildlife Management 70, 1102–1110.
Effects of culling fox populations at the landscape scale: a spatially explicit population modelling approach.Crossref | GoogleScholarGoogle Scholar |

Sargeant, A. B. (1972). Red fox spatial characteristics in relation to waterfowl predation. The Journal of Wildlife Management 36, 225–236.
Red fox spatial characteristics in relation to waterfowl predation.Crossref | GoogleScholarGoogle Scholar |

Saunders, G., and McLeod, L. (2007). ‘Improving Fox Management Strategies in Australia.’ (Bureau of Rural Sciences: Canberra.)

Saunders, G., Coman, B., Kinnear, J. E., and Braysher, M. (1995). ‘Managing Vertebrate Pests: Foxes.’ (Australian Government Publishing Service: Canberra.)

Saunders, G., McIlroy, J., Kay, B., Gifford, E., Berghout, M., and Van De Ven, R. (2002). Demography of foxes in central-western New South Wales, Australia. Mammalia 66, 247–257.
Demography of foxes in central-western New South Wales, Australia.Crossref | GoogleScholarGoogle Scholar |

Saunders, G. R., Gentle, M., and Dickman, C. (2010). The impacts and management of foxes Vulpes vulpes in Australia. Mammal Review 40, 181–211.
The impacts and management of foxes Vulpes vulpes in Australia.Crossref | GoogleScholarGoogle Scholar |

Storm, G. L., Andrews, R. D., Phillips, R. L., Bishop, R. A., Siniff, D. B., and Tester, J. R. (1976). Morphology, reproduction, dispersal, and mortality of midwestern red fox populations. Wildlife Monographs 49, 3–82.

Thomson, P., and Algar, D. (2000). The uptake of dried meat baits by foxes and investigations of baiting rates in Western Australia. Wildlife Research 27, 451–456.
The uptake of dried meat baits by foxes and investigations of baiting rates in Western Australia.Crossref | GoogleScholarGoogle Scholar |

Thomson, P., Marlow, N., Rose, K., and Kok, N. (2000). The effectiveness of a large-scale baiting campaign and an evaluation of a buffer zone strategy for fox control. Wildlife Research 27, 465–472.
The effectiveness of a large-scale baiting campaign and an evaluation of a buffer zone strategy for fox control.Crossref | GoogleScholarGoogle Scholar |

Tompkins, D. M., and Ramsey, D. (2007). Optimising bait-station delivery of fertility control agents to brushtail possum populations. Wildlife Research 34, 67–76.
Optimising bait-station delivery of fertility control agents to brushtail possum populations.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2sXit1art78%3D&md5=c647e21c3f6065252a5cf700aaf5ed4eCAS |

Trewhella, W. J., Harris, S., and McAllister, F. E. (1988). Dispersal distance, home-range size and population density in the red fox (Vulpes vulpes): a quantitative analysis. Journal of Applied Ecology 25, 423–434.
Dispersal distance, home-range size and population density in the red fox (Vulpes vulpes): a quantitative analysis.Crossref | GoogleScholarGoogle Scholar |

Valiere, N. (2002). GIMLET: a computer program for analysing genetic individual identification data. Molecular Ecology Notes 2, 377–379.
| 1:CAS:528:DC%2BD38XnvVWhsLo%3D&md5=2e595b36460374042232200c227924e6CAS |

Vine, S. J., Crowther, M. S., Lapidge, S. J., Dickman, C. R., Mooney, N., Piggott, M. P., and English, A. W. (2009). Comparison of methods to detect rare and cryptic species: a case study using the red fox (Vulpes vulpes). Wildlife Research 36, 436–446.
Comparison of methods to detect rare and cryptic species: a case study using the red fox (Vulpes vulpes).Crossref | GoogleScholarGoogle Scholar |

Waits, L. P., Luikart, G., and Taberlet, P. (2001). Estimating the probability of identity among genotypes in natural populations: cautions and guidelines. Molecular Ecology 10, 249–256.
Estimating the probability of identity among genotypes in natural populations: cautions and guidelines.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3MXjs1ejtbs%3D&md5=eed3ce44a544c70baa6875ccfd011db4CAS | 11251803PubMed |

White, G. C., and Burnham, K. P. (1999). Program MARK: survival estimation from populations of marked animals. Bird Study 46, S120–S139.
Program MARK: survival estimation from populations of marked animals.Crossref | GoogleScholarGoogle Scholar |

Wilberg, M. J., and Dreher, B. P. (2004). Genecap: a program for analysis of multilocus genotype data for non-invasive sampling and capture–recapture population estimation. Molecular Ecology Notes 4, 783–785.
Genecap: a program for analysis of multilocus genotype data for non-invasive sampling and capture–recapture population estimation.Crossref | GoogleScholarGoogle Scholar |

Woods, J. G., Paetkau, D., Lewis, D., McLellan, B. N., Proctor, M., and Strobeck, C. (1999). Genetic tagging of free-ranging black and brown bears. Wildlife Society Bulletin 27, 616–627.

Zabel, C. J., and Taggart, S. J. (1989). Shift in red fox, Vulpes vulpes, mating system associated with El Niño in the Bering Sea. Animal Behaviour 38, 830–838.
Shift in red fox, Vulpes vulpes, mating system associated with El Niño in the Bering Sea.Crossref | GoogleScholarGoogle Scholar |