Long-term monitoring of cycles in Clethrionomys rutilus in the Yukon boreal forest

Charles J. KREBS , Alice J. KENNEY , B. Scott GILBERT , Rudy BOONSTRA

Integrative Zoology ›› 2024, Vol. 19 ›› Issue (1) : 27 -36.

PDF
Integrative Zoology ›› 2024, Vol. 19 ›› Issue (1) :27 -36. DOI: 10.1111/1749-4877.12718
ORIGINAL ARTICLE
Long-term monitoring of cycles in Clethrionomys rutilus in the Yukon boreal forest
Author information +
History +
PDF

Abstract

Baseline studies of small rodent populations in undisturbed ecosystems are rare. We report here 50 years of monitoring and experimentation in Yukon of a dominant rodent species in the North American boreal forest, the red-backed vole Clethrionomys rutilus. These voles breed in summer, weigh 20–25 g, and reach a maximum density of 20 to 25 per ha. Their populations have shown consistent 3–4-year cycles for the last 50 years with the only change being that peak densities averaged 8/ha until 2000 and 18/ha since that year. During the last 25 years, we have measured food resources, predator numbers, and winter weather, and for 1-year social interactions, to estimate their contribution to changes in the rate of summer increase and the rate of overwinter decline. All these potential limiting factors could contribute to changes in density, and we measured their relative contributions statistically with multiple regressions. The rate of winter decline in density was related to both food supply and winter severity. The rate of summer increase was related to summer berry crops and white spruce cone production. No measure of predator numbers was related to winter or summer changes in vole abundance. There was a large signal of climate change effects in these populations. There is no density dependence in summer population growth and only a weak one in winter population declines. None of our results provide a clear understanding of what generates 3–4-year cycles in these voles, and the major missing piece may be an understanding of social interactions at high density.

Keywords

boreal forest / climate change / density dependence / population cycles / predation / winter severity

Cite this article

Download citation ▾
Charles J. KREBS, Alice J. KENNEY, B. Scott GILBERT, Rudy BOONSTRA. Long-term monitoring of cycles in Clethrionomys rutilus in the Yukon boreal forest. Integrative Zoology, 2024, 19(1): 27-36 DOI:10.1111/1749-4877.12718

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Andreassen HP, Sundell J, Ecke F et al. (2021). Population cycles and outbreaks of small rodents: Ten essential questions we still need to solve. Oecologia 195, 601–22.
[2]

Arif S, MacNeil MA (2022). Predictive models aren't for causal inference. Ecology Letters 25, 1741–5.
[3]

Boonstra R, Andreassen HP, Boutin S et al. (2016). Why do the boreal forest ecosystems of Northwestern Europe differ from those of Western North America? Bio-Science 66, 722–34.
[4]

Boonstra R, Boutin S, Jung TS, Krebs CJ, Taylor S (2018). Impact of rewilding, species introductions and climate change on the structure and function of the Yukon boreal forest ecosystem. Integrative Zoology 13, 123–38.
[5]

Boonstra R, Krebs CJ (2012). Population dynamics of red-backed voles (Myodes) in North America. Oecologia 168, 601–20.
[6]

Boonstra R, Krebs CJ, Gilbert S, Schweiger S (2001). Chapter 10: Voles and mice. In: Krebs CJ, Boutin S, Boonstra R, eds. Ecosystem Dynamics of the Boreal Forest: The Kluane Project. Oxford University Press, New York, pp. 215–39.
[7]

Boonstra R, Krebs CJ, Kanter M (1990). Arctic ground squirrel predation on collared lemmings. Canadian Journal of Zoology 68, 757–60.
[8]

Boonstra R, Krebs CJ (2006). Population limitation of the northern red-backed vole in the boreal forests of northern Canada. Journal of Animal Ecology 75, 1269–84.
[9]

Boonstra R, Krebs CJ, Cowcill K (2017). Responses of key understory plants in the boreal forests of western North America to natural versus anthropogenic nitrogen levels. Forest Ecology and Management 401, 45–54.
[10]

Boutin S, Krebs CJ, Boonstra R et al. (1995).Population changes of the vertebrate community during a snowshoe hare cycle in Canada's boreal forest. Oikos 74, 69–80.
[11]

Bujalska G (1973). The role of spacing behaviour among females in the regulation of reproduction in the bank vole. Journal of Reproduction and Fertility, Supplement 19, 465–74.
[12]

Doyle FI, Smith JNM (2001). Raptors and scavengers. In: Krebs CJ, Boutin S, Boonstra R, eds. Ecosystem Dynamics of the Boreal Forest: The Kluane Project. Oxford University Press, New York, pp. 377–404.
[13]

Edwards PD, Frenette-Ling C, Palme R, Boonstra R (2021). A mechanism for population self-regulation: social density suppresses GnRH expression and reduces reproductivity in voles. Journal of Animal Ecology 90, 784–95.
[14]

Fauteux D, Gauthier G, Berteaux D (2016). Top-down limitation of lemmings revealed by experimental reduction of predators. Ecology 97, 3231–41.
[15]

Gilbert BS, Krebs CJ (1981). Effects of extra food on Peromyscus and Clethrionomys populations in the southern Yukon. Oecologia 51, 326–31.
[16]

Gilbert BS, Krebs CJ (1991). Population dynamics of Clethrionomys and Peromyscus in southwestern Yukon, 1973–1989. Holarctic Ecology 14, 250–59.
[17]

Gilbert BS, Krebs CJ, Talarico D, Cichowski DB (1986). Do Clethrionomys rutilus females suppress maturation of juvenile females? Journal of Animal Ecology 55, 543–52.
[18]

Huang S, Li G, Pan Y et al. (2021a). Population variation alters aggression-associated oxytocin and vasopressin expressions in brains of Brandt's voles in field conditions. Frontiers in Zoology 18, 56.
[19]

Huang S, Li G, Pan Y et al. (2021b). Density-induced social stress alters oxytocin and vasopressin activities in the brain of a small rodent species. Integrative Zoology 16, 149–59.
[20]

Hughes BB, Beas-Luna R, Barner A et al. (2017). Long-term studies contribute disproportionately to ecology and policy. BioScience 67, 271–81.
[21]

Johnsen K, Boonstra R, Boutin S, Devineau O, Krebs CJ, Andreassen HP (2017). Surviving winter: Food, but not habitat structure, prevents crashes in cyclic vole populations. Ecology and Evolution 7, 115–24.
[22]

Korpimäki E, Norrdahl K, Huitu O, Klemola T (2005). Predator-induced synchrony in population oscillations of coexisting small mammal species. Proceedings of the Royal Society of London B 272, 193–202.
[23]

Krebs CJ, Boonstra R (1978). Demographic attributes of the spring decline in populations of the vole Microtus townsendii. Journal of Animal Ecology 47, 1007–15.
[24]

Krebs CJ, Boonstra R (1984). Trappability estimates for mark-recapture data. Canadian Journal of Zoology 62, 2440–44.
[25]

Krebs CJ, Boonstra R, Cowcill K, Kenney AJ (2009). Climatic determinants of berry crops in the boreal forest of the southwestern Yukon. Botany 87, 401–8.
[26]

Krebs CJ, Boonstra R, Gilbert BS, Kenney AJ, Boutin S (2019). Impact of climate change on the small mammal community of the Yukon boreal forest. Integrative Zoology 14, 528–41.
[27]

Krebs CJ, Boutin S, Boonstra R (2001). Ecosystem Dynamics of the Boreal Forest: the Kluane Project. Oxford University Press, New York.
[28]

Krebs CJ, Carrier P, Boutin S, Boonstra R, Hofer EJ (2008). Mushroom crops in relation to weather in the southwestern Yukon. Botany 86, 1497–502.
[29]

Krebs CJ, Wingate I (1976). Small mammal communities of the Kluane Region, Yukon Territory. Canadian Field-Naturalist 90, 379–89.
[30]

LaMontagne JM, Peters S, Boutin S (2005). A visual index for estimating cone production for individual white spruce trees. Canadian Journal of Forest Research 35, 3020–26.
[31]

Lindenmayer DB, Likens GE (2009). Adaptive monitoring: a new paradigm for long-term research and monitoring. Trends in Ecology & Evolution 24, 482–86.
[32]

Lindenmayer DB, Likens GE, Andersen A et al. (2012). Value of long-term ecological studies. Austral Ecology 37, 745–57.
[33]

McLean BS (2018). Urocitellus parryii (Rodentia: Sciuridae). Mammalian Species 50, 84–99.
[34]

Mihok S, Boonstra R (1992). Breeding performance in captivity of meadow voles (Microtus pennsylvanicus) from decline- and increase-phase populations. Canadian Journal of Zoology 70, 1561–6.
[35]

Nagy KA, Girard IA,Brown TK (1999). Energetics of free-ranging mammals, reptiles, and birds. Annual Review of Nutrition 19, 247–77.
[36]

O'Donoghue M, Slough BG, Poole K et al. (2022). Snow track counts for density estimation of mammalian predators in the boreal forest. Wildlife Research 50, 425–434.
[37]

Rohner C, Doyle FI, Smith JNM (2001). Great horned owls. In: Krebs CJ, Boutin S, Boonstra R, eds. Ecosystem Dynamics of the Boreal Forest: The Kluane Project. Oxford University Press, New York, pp. 339–76.
[38]

Saitoh T (1981). Control of female maturation in high density populations of the red-backed vole, Clethrionomys rufocanus bedfordiae. Journal of Animal Ecology 50, 79–87.
[39]

Schweiger S, Boutin S (1995). The effects of winter food addition on the population dynamics of Clethrionomys rutilus. Canadian Journal of Zoology 73, 419–26.
[40]

Sinclair ARE (1998). Natural regulation of ecosystems in protected areas as ecological baselines. Wildlife Society Bulletin 26, 399–409.
[41]

Werner JR, Krebs CJ, Donker SA, Boonstra R, Sheriff MJ (2015). Arctic ground squirrel population collapse in the boreal forests of the Southern Yukon. Wildlife Research 42, 176–84.

RIGHTS & PERMISSIONS

2023 The Authors. Integrative Zoology published by International Society of Zoological Sciences, Institute of Zoology/Chinese Academy of Sciences and John Wiley & Sons Australia, Ltd.

PDF

342

Accesses

0

Citation

Detail
Sections
Recommended

/