Wolf-Moose Populations on Isle Royale Modeling potential impacts of climate change.

Wolf-Moose Populations

on Isle Royale

Modeling potential impacts of climate change

The IslandIsle Royale is an island in Lake Superior, 14 mi from Canada.Its 544 km² of land is home to 165 miles of trailand a wide array of wild-life. It was among the first national parks in the

United States and is now the home of the world’s longest predator-prey population study.

The Study In the late 1940s, an ice bridge

over Lake Superior facilitated the colonization of Isle Royale by a pack of gray wolves (Canis lupus).

Over 90% of the wolves’ diet now consists of the moose (Alces alces) already inhabiting the island (Peterson and Page, 1988), and they are the only predator capable of hunting the moose.

Since 1958, the populations have been monitored and studied, and are a leading example of predator-prey relations in a three trophic level system.

The role of Winter Ticks Winter ticks (Dermacentor

albipictus) cause excessive moose grooming, leading to alopecia and reduced heat-trapping ability, making moose vulnerable in the winter months. Preoccupation with grooming, if infestation is severe enough, can also lead to reduced grazing and starvation (McLaughlin and Addison, 1986 and Mooring and Samuel, 1999).

Our Question In the past, outbreaks of winter ticks

(Dermacentor albipictus) have contributed to declines in moose populations.

As a result of climate change, increasing frequency of warm springs is expected, leading to a rise in tick populations.

How might climate change, with respect to impacts of ticks on moose populations, affect the wolf-moose population dynamic on Isle Royale?

Methods Using STELLA, we modeled the interactions between moose

and wolf with and without the influence of ticks. We assume the absence of other factors such as disease,

stochastic events, and other results of climate increase. Wolf predation and tick population are taken to be the only causes of moose mortality.

Tick population density is assumed to be directly correlated with temperature, with little activity at temperatures less than 4°C (DelGiudice, et al., 1997) and increasing impact as temperature rises thereafter.

Tick impact on moose mortality is also taken to be in direct correlation with population of ticks.

Methods, continued

Moose Deaths

Moose population

Wolf Population

Wolf Births

Moose Births

Wolf Deaths

Moose Birth Rate

Predation Rate

Tick Population

~

Average April Temperature

Carrying Capacity Graph 2

Wolf Death Rate

Graph 1

Results The first graph depicts a

generalization of the moose-wolf population in the absence of ticks. Rate of predation is based on a ratio dependent equation proposed by Vucetich, et al. (2002).

The second graph depicts the impact of increased tick population as a result of average April temperature according to projected changes in temperature (Boer, et al. 2000)

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Current Moose-Wolf Population Trend

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Populations at Projected Temperatures

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Summary Because of its distance from the mainland and

the decreasing odds of ice bridge formation over Lake Superior, additional colonization of the island is unlikely, as is the potential for northward migration of moose in response to pressure from higher tick populations.

Thus, climate change has the potential to significantly impact the population dynamic between wolves and moose on Isle Royale, MI, the subject of a population study nearly half a century long.

Sources Boer, G.J., G. Flato and D. Ramsden. 2000. A transient climate change simulation with greenhouse

gas and aerosol forcing: projected climate to the twenty-first century. Climate Dynamics, 16: 427-450.

DelGiudice, G.D., R.O. Peterson and W.M. Samuel. 1997. Trends of winter nutritional restriction, ticks, and numbers of moose on Isle Royale. Journal of Wildlife Management, 61(3): 895-903.

Environment Canada. “Canadian Climate Normals 1971-2000”. 25 February 2004. <http://www.climate.weatheroffice.ec.gc.ca/climate_normals> (3 December 2006)

McLaughlin, R.F. and Addison, E.M. 1986. Tick (Dermacentor albipictus)-induced winter hair-loss in captive moose (Alces alces). Journal of Wildlife Diseases, 22(4): 502-510.

Mooring, M.S. and Samuel, W.M. 1999. Premature loss of winter hair in free-ranging moose (Alces alces) infested with winter ticks (Dermacentor albipictus) is correlated with grooming

rate. Canadian Journal of Zoology, 77: 148-156. Peterson, Rolf O. and Richard E. Page. 1988. The Rise and Fall of Isle Royale Wolves, 1975-1986.

Journal of Mammalogy. 69(1): 89-99. Post, E., R.O. Peterson, N.C. Stenseth and B.E. McLaren. October 1999. Ecosystem consequences

of wolf behavioural response to climate. Nature, 401: 905-907. Thurber, Joanne M. and Rolf O. Peterson. 1993. Effects of population density and pack size on the

foraging ecology of gray wolves. Journal of Mammalogy, 74(4): 879-889. United States National Park Service. Isle Royale National Park. 30 July 2006. <http://

www.nps.gov/isro> 3 December 2006. Vucetich, John A. and Rolf O. Peterson. 2004. The influence of prey consumption and demographic

stochasticity on population growth rate of Isle Royale wolves Canis lupus. Oikos, 107(2): 309-318.

Vucetich, John A., Rolf O. Peterson, and Carrie L. Schaefer. 2002. The effect of prey and predator densities on wolf predation. Ecology, 83(11): 3003-3013.