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Undetected species losses, food webs, and ecological baselines: a cautionary tale from the Greater Yellowstone Ecosystem, USA

Published online by Cambridge University Press:  21 February 2008

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Abstract

Large protected areas are often considered natural yet outside pressures may compromise ecological integrity. This paper points to a problem in assessing ecological baselines: what if species’ extirpations go undetected? I present a data set spanning 130 years that demonstrates the loss of white-tailed jack rabbits Lepus townsendii from two National Parks in the well studied 60,000 km2 Greater Yellowstone Ecosystem, USA. While these extirpations have been unnoticed until now, an ecological consequence may be elevated predation on juvenile ungulates. A critical challenge we face is how to apply better the concept of shifting baselines to the restoration of functional relationships when species' losses are undetected.

Type
Short Communications
Copyright
Copyright © Fauna and Flora International 2008

Species and populations disappear, their passing often predating scientific description (Wilson, Reference Wilson1986) and knowledge about interactions (Berger, Reference Berger1999). For well known vertebrates, especially in countries with a history of ecological research, this tends not to be the case. Mammals larger than 3-5 kg offer an example. Their demise from protected reserves is often, but not always, detected (Newmark, Reference Newmark1995; Brasheres et al., Reference Brashares, Arcese and Sam2001). An appreciation of historical conditions is crucial to understand functional relationships and the possibility of restoration (Arcese & Sinclair, Reference Arcese and Sinclair1997; Dayton et al., Reference Dayton, Tegner, Edwards and Riser1998). The problem, however, is that when species disappear unnoticed, the utility of a baseline is greatly weakened. Here I highlight these issues by profiling previously unreported extirpations from two well-studied National Parks in the Greater Yellowstone Ecosystem, USA.

Yellowstone National Park, hereinafter Yellowstone, was established in 1872 and Grand Teton as a national monument in 1929, before elevation to Park status in 1950 (Fig. 1). Together these contiguous units, >1.2 million ha, are characterized by extensive scientific research, well developed species lists, and serve as testing grounds for restoration and potential effects of apex carnivores (Berger et al., Reference Berger, Stacey, Johnson and Bellis2001; Ripple et al., Reference Ripple, Larson, Renkin and Smith2001; Pyare & Berger, Reference Pyare and Berger2003; Smith et al., Reference Smith, Peterson and Houston2003). Nevertheless, when ecological conditions have not been accurately depicted, or change without detection, the concept of baselines loses utility.

Fig. 1 The study area, indicating the Greater Yellowstone Ecosystem and Yellowstone and Grand Teton National Parks. The inset indicates the position of the Greater Yellowstone Ecosystem in North America.

A case in point involves the poorly known white-tailed jack rabbit Lepus townsendii. This large, once abundant, lagomorph has slipped away without notice. I chronicled L. townsendii disappearances by collating historical information, unpublished and published notes, and queries to professional biologists and naturalists who have (or had) worked in the Yellowstone Ecosystem for up to 5 decades (Appendix). I also checked records and queried databases of the American Museum of Natural History, the California Academy of Sciences, the Chicago Field Museum, the Burke Museum (Seattle), the Denver Museum of Nature and Science, and the Museum of South-west Biology (Albuquerque). Only the American Museum of Natural History reported L. townsendii from Teton County, Wyoming; samples were from 1934-35, a period consistent with their presence in the region.

Descriptions in Yellowstone between 1876 and 1926 suggested a level of abundance (e.g. ‘Where … coyotes or wolves have been killed or driven off, the hares still exist in great numbers’, and ‘jackrabbits with their large white tails are common … and may also be seen almost anywhere in the open northern sections of the Park’) but by the early 1990s none were detected. For Grand Teton the pattern is similar, with descriptions between 1928 and 1949 limited to ‘regular occurrence’ and ‘commonly in the vicinity’, but few thereafter (Appendix). Hence, despite the spectacular scientific attention to coyotes Canis latrans, wolves Canis lupus, and their prey in the open habitats of Yellowstone and Grand Teton, not a single sighting of L. townsendii could be confirmed since 1991 in the former and only three since 1978 in the latter.

The intimation that L. townsendii have disappeared begs an obvious question; is a metric other than human observation superior for detection, particularly because tracks, faeces, and individuals become less obvious at low densities? Hence, I relied on a nutritional bioassay using the diets of coyotes as a marker for L. townsendii presence. Based on scat analyses conducted both in Teton and Yellowstone spanning up to 70 years (Murie, Reference Murie1935; Murie, Reference Murie1940), the amount of hare hair has declined. Faecal collections for 1931-1935 (n = 2,415) in the general region of what is currently Grand Teton contained c. 10% hare (Murie, Reference Murie1935; based on extrapolations in Weaver, Reference Weaver1977); for 1973-1975, c. 1% (n = 1,500; Weaver, Reference Weaver1977) and for 1998-1999, 0% (n = 339; Wigglesworth et al., Reference Wigglesworth, McClennen, Anderson and Wachob2001). The evidence points to simultaneous attrition in both parks coupled with little to no recolonization.

Lacking a sense of historical conditions it will always be difficult to decide whether current systems function ecologically like past ones. Consequently, what might be adduced can only come about by analogy using surrogate models although it is not obvious which leporid might be more appropriate, black-tailed jack rabbits Lepus californicus or snowshoe hares Lepus americana. Elsewhere, rabbits play key roles in boreal, desert and high altitude landscapes, and black-tailed jack rabbits drive the dynamics of coyote populations (Knowlton & Stoddart, Reference Knowlton, Stoddart and Boer1992). This predator-prey relationship has important ecological effects because predation on domestic ungulates increases when hare densities drop (Stoddart et al., Reference Stoddart, Griffiths and Knowlton2001). If L. townsendii once filled similar niches in more mesic or climatically more extreme regions such as the Greater Yellowstone area then their loss could have had a striking influence upon food webs.

As is common in many rangelands, large carnivores have been relentlessly persecuted, with unknown community-wide effects (Berger, Reference Berger2006). In Grand Teton, however, coyotes remove a high proportion of young elk Cervus elaphus and pronghorn Antilocapra americana (Smith & Anderson, Reference Smith and Anderson1996; Berger, Reference Berger2007). Whereas historical relationships are uncertain, coyotes are catholic feeders and switch between energetically-beneficial prey (Gese et al., Reference Gese, Ruff and Crabtree1995). It is possible that the localized extirpations of L. townsendii prompted independent but high levels of predation on pronghorn fawns in both Grand Teton (Berger, Reference Berger2007) and Yellowstone (Smith et al., Reference Smith, Peterson and Houston2003). Similar patterns have been noted on Montana's National Bison Range and South Dakota's Wind Cave National Park, both relatively small fenced areas managed for high ungulate biomass where lagomorphs are rare (Byers, Reference Byers1997; Sievers, Reference Sievers2004; J. Berger, unpubl. data) and coincident grazing impacts on vegetation large.

While the loss of L. townsendii from Grand Teton and Yellowstone, and reductions elsewhere, are likely to facilitate increased predation on ungulate neonates, at least in localized settings, prey-predator relationships are dynamic across space and time. If the loss of wolves promotes coyote numbers, then a top-down effect on fawn survival may be prominent (Berger, Reference Berger2007). Still, the role of potentially important bottom-up drivers, such as L. townsendii, requires clarification, something that will not occur when species are extirpated and, moreover, when their loss is unknown.

The reintroduction of carnivores has been pivotal in attempts to restore ecological integrity (Smith et al., Reference Smith, Peterson and Houston2003) but rarely have small or medium sized mammals been reintroduced with a goal beyond that of population recovery. The supplementation of native wild hare Oryctolagus cuniculus into Spain's Doñana National Park with an aim of offering a food base for Iberian lynx Lynx pardina is an obvious exception (Moreno et al., Reference Moreno, Villafuerte, Cabezas and Lombardi2004).

A similar but more dramatic manipulative approach to food webs from below is diversionary feeding. For example, in India's Sanjay Ghandi National Park, where leopards killed 19 people during 3 months, exotic pigs and rabbits were targeted for introduction as prey alternatives to humans (Soondas, Reference Soondas2004). In Alaska the relocation of train- or road-killed moose concentrated 12 t of carcasses to lure brown bears from sites with newborn calves (Orians, Reference Orians1997). These sorts of lateral or bottom-driven approaches are intended to achieve a specific management goal atypical of biological conservation. The case of L. townsendii in both Grand Teton and Yellowstone differs.

If the prospects for successful reintroduction of species of lower trophic levels were bright, then adoption of bottom-up as well as top-down approaches could serve multiple purposes. Firstly, a reintroduction may result in the establishment of dynamic ecological processes that were intact prior to extirpation. Secondly, from perspectives that involve ecological health and wildlife conservation, the public as well as managers of protected areas may find it easier to garner endorsement if it were clear that a species loss had serious ecological costs. In this case, it will be prudent to consider reintroduction of L. townsendii to Grand Teton and Yellowstone National Parks (Berger et al., Reference Berger, Berger, Brussard, Gibson, Rachlow and Smith2006). At a broader level the problems of species disappearance in the two parks in the Greater Yellowstone Ecosystem is not likely to be a unique episode restricted to this well studied region. A critical challenge we face is therefore how to apply better the concept of shifting baselines to the restoration of functional relationships when species' losses are undetected.

Acknowledgments

Thanks are due to many people for help with surveys and for comments, in particular K. Berger, J. Bohne, S. Cain, F. Camenzind, G.S. Clark, E. Gese, S. Gunther, D. Houston, T. Kerasote, R. Renkin and D. Smith, and especially Paul Schullery for historical insights. P. Brussard, S. Cain, K. Berger, R. Gibson, H. Harlow, J. Rachlow, A. Smith and others participated in the workshop Where Have All the Rabbits Gone? supported by the National Park Service (Grand Teton), the University of Wyoming-NPS Research Station, the Wildlife Conservation Society, Earth Friends Foundation, and the Community Foundation of Jackson Hole.

Appendix

The appendix for this article is available online at http://journals.cambridge.org

Biographical sketch

Joel Berger has researched questions involving food webs and the ecological role of carnivores in the greater Yellowstone and polar regions, Alaska, the Russian Far East, and southern Africa. His current work concentrates on the development of conservation strategies to protect long distance migration and wide ranging movements in terrestrial mammals both in Mongolia and western North America.

References

Arcese, P. & Sinclair, A.R.E. (1997) The role of protected areas as ecological baselines. Journal of Wildlife Management, 61, 587602.CrossRefGoogle Scholar
Barnosky, E.H. (1994) Ecosystem dynamics through the past 2000 years as revealed by fossil mammals from Lamar Cave in Yellowstone National Park, USA. Historical Biology, 8, 7190.CrossRefGoogle Scholar
Berger, J. (1999) Anthropogenic extinction of top carnivores and interspecific animal behaviour: implications of rapid decoupling of a web involving wolves, bears, moose, and ravens. Proceedings of the Royal Society, 266, 22612267.CrossRefGoogle ScholarPubMed
Berger, J., Berger, K.M., Brussard, P.F., Gibson, R., Rachlow, J. & Smith, A.T. (2006) Where Have all the Rabbits Gone? Wildlife Conservation Society, New York, USA [http://www.ualberta.ca/~dhik/lsg/White-tailed%20Jackrabbit%20Report.pdf, accessed 3 January 2008].Google Scholar
Berger, J., Stacey, P.B., Johnson, M.L. & Bellis, L. (2001) A mammalian predator-prey imbalance: grizzly bear and wolf extinction affects avian Neotropical migrants. Ecological Applications, 11, 947960.Google Scholar
Berger, K.M. (2006) Carnivore-livestock conflicts: effects of subsidized predator control and economic correlates on the sheep industry. Conservation Biology, 20, 751761.CrossRefGoogle ScholarPubMed
Berger, K.M. (2007) Conservation implications of food webs involving wolves, coyotes, and pronghorn. PhD thesis, Utah State University, Logan, USA.Google Scholar
Brashares, J.S., Arcese, P. & Sam, M.K. (2001) Human demography and reserve design predict wildlife extinction in West Africa. Proceedings of the Royal Society, 268, 24732478.CrossRefGoogle Scholar
Byers, J.A. (1997) American Pronghorn: Social Adaptations and Ghosts of Predators Past. University of Chicago Press, Chicago, USA.Google Scholar
Dayton, P.K., Tegner, M.J., Edwards, P.B. & Riser, K.L. (1998) Sliding baselines, ghosts, and reduced expectations in kelp forest communities. Ecological Applications, 8, 309322.Google Scholar
Gese, E., Ruff, M.R. & Crabtree, R.L. (1995) Intrinsic and extrinsic factors influencing coyote predation of small mammals in Yellowstone National Park. Canadian Journal of Zoology, 74, 784797.Google Scholar
Johnson, K.A. & Crabtree, R.L. (1999) Small prey of carnivores in the Greater Yellowstone Ecosystem. In Carnivores in Ecosystems: The Yellowstone Experience (eds Clark, T.W., Curlee, A.P., Minta, S.C. & Kareiva, P.M.), pp. 239263. Yale University Press, New Haven, USA.Google Scholar
Knowlton, F.F. & Stoddart, L.C. (1992) Some observations from two coyote-prey studies. In Ecology and Management of the Eastern Coyote (ed. Boer, A.), pp. 101121. Wildlife Research Unit, University of New Brunswick, Canada.Google Scholar
Ludlow, W. (1876) Report of a Reconnaissance from Carrol, Montana Territory, on the Upper Missouri to the Yellowstone National Park and Return Made in the Summer of 1875. Government Printing Office, Washington, DC, USA.Google Scholar
Moreno, S., Villafuerte, R., Cabezas, S. & Lombardi, L. (2004) Wild rabbit restocking for predator conservation in Spain. Biological Conservation, 118, 183193.CrossRefGoogle Scholar
Murie, A. (1940) Ecology of the coyote in the Yellowstone. Fauna of the National Parks of the United States Bulletin, 4, 1206.Google Scholar
Murie, O. (1935) Food habits of the coyote in Jackson Hole, Wyoming. U.S. Department of Agriculture Bulletin, 362, 124.Google Scholar
Negus, N.C. & Findley, J.S. (1959) Mammals of Jackson Hole, Wyoming. Journal of Mammalogy, 40, 371381.Google Scholar
Newmark, W.D. (1995) Extinction of mammal populations in western North American national parks. Conservation Biology, 9, 512526.CrossRefGoogle Scholar
Orians, G.H. (1997) Wolves, Bears, and their Prey in Alaska. National Academy of Sciences Press, Washington, DC, USA.Google Scholar
Pyare, S. & Berger, J. (2003) Beyond demography and delisting: ecological recovery for Yellowstone's grizzly bears and wolves. Biological Conservation, 113, 6373.CrossRefGoogle Scholar
Reed, J.M. (1996) Using statistical probability to increase confidence of inferring species extinction. Conservation Biology, 10, 12831285.Google Scholar
Ripple, W.J., Larson, E.J., Renkin, R.A. & Smith, D.W. (2001) Trophic cascades among wolves, elk, and aspen on Yellowstone National Park's northern range. Biological Conservation, 102, 227234.CrossRefGoogle Scholar
Roberts, D.L. & Kitchener, A.C. (2006) Inferring extinction from biological records: were we too quick to write off Miss Waldron's red colobus monkey (Pilocolobus badius waldronae)? Biological Conservation, 128, 285287.Google Scholar
Schullery, P. (1997) Searching for Yellowstone: Ecology and Wonder in the Last Wilderness. Houghton Mifflin, Boston, USA.Google Scholar
Sievers, J.D. (2004) Factors influencing a declining pronghorn population in Wind Cave National Park, South Dakota. MSc thesis, South Dakota State University, Brookings, USA.Google Scholar
Smith, B.L. & Anderson, S.H. (1996) Patterns of neonatal mortality of elk in Northwestern Wyoming. Canadian Journal of Zoology, 74, 12291237.CrossRefGoogle Scholar
Smith, D.W., Peterson, R.O. & Houston, D.B. (2003) Yellowstone after wolves. BioScience, 53, 330340.Google Scholar
Soondas, A. (2004) Mumbai eyes pigs to keep off leopards. The Telegraph-Calcutta, 29 June [http://www.telegraphindia.com/1040629/asp/nation/story_3430738.asp, accessed 3 January 2008].Google Scholar
Stoddart, I.C., Griffiths, R.C. & Knowlton, F.F. (2001) Coyote responses to changing jackrabbit abundance affect sheep predation. Journal of Range Management, 54, 1520.CrossRefGoogle Scholar
Weaver, J.L. (1977) Coyote food-base relationships in Jackson Hole, Wyoming. MSc thesis, Utah State University, Logan, USA.Google Scholar
Wigglesworth, R.R., McClennen, N., Anderson, S.H. & Wachob, D.G. (2001) Comparison of coyote diets between two areas of Jackson Hole, Wyoming. Intermountain Journal of Sciences, 6, 355366.Google Scholar
Wilson, E.O. (1986) The little things that run the world. Conservation Biology, 1, 344346.Google Scholar
Figure 0

Fig. 1 The study area, indicating the Greater Yellowstone Ecosystem and Yellowstone and Grand Teton National Parks. The inset indicates the position of the Greater Yellowstone Ecosystem in North America.

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