Abstract
Outbreaks of many forest-defoliating insects are synchronous over broad geographic areas and occur with a period of approximately 10 years. Within the range of the gypsy moth in North America, however, there is considerable geographic heterogeneity in strength of periodicity and the frequency of outbreaks. Furthermore, gypsy moth outbreaks exhibit two significant periodicities: a dominant period of 8–10 years and a subdominant period of 4–5 years. In this study, we used a simulation model and spatially referenced time series of outbreak intensity data from the Northeastern United States to show that the bimodal periodicity in the intensity of gypsy moth outbreaks is largely a result of harmonic oscillations in gypsy moth abundance at and above a 4 km2 scale of resolution. We also used geographically weighted regression models to explore the effects of gypsy moth host-tree abundance on the periodicity of gypsy moths. We found that the strength of 5-year cycles increased relative to the strength of 10-year cycles with increasing host tree abundance. We suggest that this pattern emerges because high host-tree availability enhances the growth rates of gypsy moth populations.
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References
Baltensweiler W, Fischlin A (1988) The larch budmoth in the Alps. In: Berryman AA (ed) Dynamics of forest insect populations: patterns, causes, implications. Plenum, New York, pp 331–351
Berryman AA (1996) What causes population cycles of forest Lepidoptera? Trends Ecol Evol 11:28–32
Bjørnstad ON, Champely S, Stenseth NC, Saitoh T (1996) Cyclicity and stability of grey-sided voles, Clethrionomys rufocanus, of Hokkaido: spectral and principal components analyses. Philos Trans R Soc Lond B Biol Sci 351:867–875
Bjørnstad ON, Falck W, Stenseth NC (1995) Geographic gradient in small rodent density-fluctuations—a statistical modeling approach. Proc R Soc Lond B Biol Sci 262:127–133
Brundson C, Fotheringham AS, Charlton ME (1996) Geographically weighted regression: a method for exploring spatial nonstationarity. Geogr Anal 28:281–298
Campbell RW, Sloan RJ (1977) Natural regulation of innocuous gypsy moth populations. Environ Entomol 6:315–322
Cooke BJ, Lorenzetti F (2006) The dynamics of forest tent caterpillar outbreaks in Quebec, Canada. For Ecol Manage 226:110–121
Davidson CB, Johnson JE, Gottschalk KW, Amateis RL (2001) Prediction of stand susceptibility and gypsy moth defoliation in coastal plain mixed pine-hardwoods. Can J For Res 31:1914–1921
Dwyer G, Dushoff J, Yee SH (2004) The combined effects of pathogens and predators on insect outbreaks. Nature 430:341–345
Elias SP, Witham JW, Hunter ML (2004) Peromyscus leucopus abundance and acorn mast: population fluctuation patterns over 20 years. J Mammal 85:743–747
Elkinton JS, Healy WM, Buonaccorsi JP, Boettner GH, Hazzard A, Liebhold AM, Smith HR (1996) Interactions among gypsy moths, white-footed mice, and acorns. Ecology 77:2332–2342
Elkinton JS, Liebhold AM (1990) Population dynamics of gypsy moth in North America. Annu Rev Entomol 35:571–596
Eyre FH (1980) Forest cover types of the United States and Canada. Society of American Foresters, Washington
Farge M (1992) Wavelet transforms and their applications to turbulence. Annu Rev Fluid Mech 24:395–457
Fotheringham AS, Brundson C, Charlton ME (2002) Geographically weighted regression: the analysis of spatially varying relationships. Wiley, Hoboken
Fromentin JM, Stenseth NC, Gjosaeter J, Bjørnstad ON, Falck W, Johannessen T (1997) Spatial patterns of the temporal dynamics of three gadoid species along the Norwegian Skagerrak coast. Mar Ecol Prog Ser 155:209–222
Grenfell BT, Bjørnstad ON, Kappey J (2001) Travelling waves and spatial hierarchies in measles epidemics. Nature 414:716–723
Hamilton DJ, Lechowicz MJ (1991) Host effects on the development and fecundity of gypsy-moth, Lymantria dispar, reared under field conditions. Can J Zool 69:2217–2224
Johnson DM, Bjørnstad ON, Liebhold AM (2006a) Landscape mosaic induces traveling waves of insect outbreaks. Oecologia 148:51–60
Johnson DM, Liebhold AM, Bjørnstad ON, McManus ML (2005) Circumpolar variation in periodicity and synchrony among gypsy moth populations. J Anim Ecol 74:882–892
Johnson DM, Liebhold AM, Bjørnstad ON (2006b) Geographical variation in the periodicity of gypsy moth outbreaks. Ecography 29:367–374
Johnson DM, Liebhold AM, Tobin PC, Bjørnstad ON (2006c) Allee effects and pulsed invasion by the gypsy moth. Nature 444:361–363
Kingsley NP (1985) A forester’s atlas of the northeast. USDA Forest Service General Technical Report NE-95
Kleiner KW, Montgomery ME (1994) Forest stand susceptibility to the gypsy moth—species and site effects on foliage quality to larvae. Environ Entomol 23:699–711
Klvana I, Berteaux D, Cazelles B (2004) Porcupine feeding scars and climatic data show ecosystem effects of the solar cycle. Am Nat 164:283–297
Liebhold AM, Elkinton J, Williams D, Muzika RM (2000) What causes outbreaks of the gypsy moth in North America? Popul Ecol 42:257–266
Liebhold AM, Gottschalk KW, Muzika R, Montgomery ME, Young R, O’Day K, Kelley B (1995) Suitability of North American tree species to the gypsy moth: a summary of field and laboratory tests. USDA Forest Service General Technical Report NE-221
Liebhold AM, Gottschalk KW, Luzader ER, Mason DA, Bush R, Twardus TB (1997) Gypsy moth in the United States: an atlas. USDA Forest Service General Technical Report NE-233 p 33
Liebhold A, Kamata N (2000) Introduction—are population cycles and spatial synchrony a universal characteristic of forest insect populations? Popul Ecol 42:205–209
Morin RS, Liebhold AM, Luzader ER, Lister AJ, Gottschalk KW, Twardus DB (2004) Mapping host-species abundance of three major exotic forest pests. USDA Forest Service Northeastern Research Station Research Paper NE-726
Peltonen M, Liebhold AM, Bjørnstad ON, Williams DW (2002) Spatial synchrony in forest insect outbreaks: roles of regional stochasticity and dispersal. Ecology 83:3120–3129
Royama T (1992) Analytical population dynamics. Chapman and Hall, London
Smith HR (1985) Wildlife and the gypsy moth. Wildl Soc Bull 13:166–174
Torrence C, Compo GP (1998) A practical guide to wavelet analysis. Bull Am Meteorol Soc 79:61–78
Turchin P, Wood SN, Ellner SP, Kendall BE, Murdoch WW, Fischlin A, Casas J, McCauley E, Briggs CJ (2003) Dynamical effects of plant quality and parasitism on population cycles of larch budmoth. Ecology 84:1207–1214
Volney WJA, McCullough DG (1994) Jack pine budworm population behaviour in northwestern Wisconsin. Can J For Res 24:502–510
Williams DW, Liebhold AM (1995) Influence of weather on the synchrony of gypsy moth outbreaks in New England. Environ Entomol 24:987–995
Wolff JO (1996) Population fluctuations of mast-eating rodents are correlated with production of acorns. J Mammal 77:850–856
Yahner RH, Smith HR (1991) Small mammal abundance and habitat relationships on deciduous forested sites with different susceptibility to gypsy-moth defoliation. Environ Manage 15:113–120
Acknowledgments
Funding for this study was provided by a USDA-NRI Grant (2006-35306-17264) to D.M.J. We thank J.M. Constible for providing useful comments on an earlier draft of the manuscript. We also thank G. Luzader for assisting with database queries and for generating Fig. 4. The study described in this manuscript complies with the current laws of the United States.
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Communicated by Konrad Fiedler.
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Haynes, K.J., Liebhold, A.M. & Johnson, D.M. Spatial analysis of harmonic oscillation of gypsy moth outbreak intensity. Oecologia 159, 249–256 (2009). https://doi.org/10.1007/s00442-008-1207-7
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DOI: https://doi.org/10.1007/s00442-008-1207-7