Is a larger refuge always better? Dispersal and dose in pesticide resistance evolution

The evolution of resistance against pesticides is an important problem of modern agriculture. The high‐dose/refuge strategy, which divides the landscape into treated and nontreated (refuge) patches, has proven effective at delaying resistance evolution. However, theoretical understanding is still incomplete, especially for combinations of limited dispersal and partially recessive resistance. We reformulate a two‐patch model based on the Comins model and derive a simple quadratic approximation to analyze the effects of limited dispersal, refuge size, and dominance for high efficacy treatments on the rate of evolution. When a small but substantial number of heterozygotes can survive in the treated patch, a larger refuge always reduces the rate of resistance evolution. However, when dominance is small enough, the evolutionary dynamics in the refuge population, which is indirectly driven by migrants from the treated patch, mainly describes the resistance evolution in the landscape. In this case, for small refuges, increasing the refuge size will increase the rate of resistance evolution. Our analysis distils major driving forces from the model, and can provide a framework for understanding directional selection in source‐sink environments.

[1]  Rodrigo J. Sorgatto,et al.  Dominance of Cry1F resistance in Spodoptera frugiperda (Lepidoptera: Noctuidae) on TC1507 Bt maize in Brazil. , 2016, Pest management science.

[2]  B. Tabashnik,et al.  Insect resistance to Bt crops: lessons from the first billion acres , 2013, Nature Biotechnology.

[3]  A. Ives,et al.  Contamination and management of resistance evolution to high-dose transgenic insecticidal crops , 2012, Theoretical Ecology.

[4]  J. Ringland,et al.  Boundaries of sustainability in simple and elaborate models of agricultural pest control with a pesticide and a non-toxic refuge , 2012, Journal of biological dynamics.

[5]  A. Alyokhin Scant evidence supports EPA's pyramided Bt corn refuge size of 5% , 2011, Nature Biotechnology.

[6]  D. Andow,et al.  Success of the high‐dose/refuge resistance management strategy after 15 years of Bt crop use in North America , 2011 .

[7]  A. Ives,et al.  The evolution of resistance to two-toxin pyramid transgenic crops. , 2011, Ecological applications : a publication of the Ecological Society of America.

[8]  J. Ringland,et al.  Analysis of sustainable pest control using a pesticide and a screened refuge , 2010, Evolutionary applications.

[9]  Richard Shine,et al.  Life-history evolution in range-shifting populations. , 2010, Ecology.

[10]  G. Luikart,et al.  Genetic effects of harvest on wild animal populations. , 2008, Trends in ecology & evolution.

[11]  D. Crowder,et al.  Insect resistance to Bt crops: evidence versus theory , 2008, Nature Biotechnology.

[12]  J. Ringland,et al.  A situation in which a local nontoxic refuge promotes pest resistance to toxic crops. , 2007, Theoretical population biology.

[13]  B. Tabashnik,et al.  Evolution of resistance to transgenic crops: interactions between insect movement and field distribution. , 2005, Journal of economic entomology.

[14]  C. Ellers-kirk,et al.  Effects of insect population size on evolution of resistance to transgenic crops. , 2004, Journal of economic entomology.

[15]  F. Gould,et al.  Delaying evolution of insect resistance to transgenic crops by decreasing dominance and heritability , 2004, Journal of evolutionary biology.

[16]  Andrew P. Hendry,et al.  Contemporary evolution meets conservation biology , 2003 .

[17]  A. Ives,et al.  Evolution of resistance to Bt crops: directional selection in structured environments , 2002 .

[18]  M. Rausher Co-evolution and plant resistance to natural enemies , 2001, Nature.

[19]  M. Caprio,et al.  Source-Sink Dynamics Between Transgenic and Non-Transgenic Habitats and Their Role in the Evolution of Resistance , 2001, Journal of economic entomology.

[20]  M. Raymond,et al.  Insecticide Resistance and Dominance Levels , 2000, Journal of economic entomology.

[21]  F. Gould Testing Bt refuge strategies in the field , 2000, Nature Biotechnology.

[22]  R. T. Roush,et al.  Two-toxin strategies for management of insecticidal transgenic crops: can pyramiding succeed where pesticide mixtures have not? , 1998 .

[23]  Michael A. Caprio,et al.  Evaluating Resistance Management Strategies for Multiple Toxins in the Presence of External Refuges , 1998 .

[24]  D. Andow,et al.  Evolution of Insect Resistance to Bacillus thuringiensis-Transformed Plants , 1996, Science.

[25]  D. Andow,et al.  Managing the Evolution of Insect Resistance to Transgenic Plants , 1995, Science.

[26]  B. Tabashnik Managing resistance with multiple pesticide tactics: theory, evidence, and recommendations. , 1989, Journal of economic entomology.

[27]  G. Mani Evolution of resistance in the presence of two insecticides. , 1985, Genetics.

[28]  C. Taylor,et al.  Genetic and biological influences in the evolution of insecticide resistance. , 1977, Journal of economic entomology.

[29]  H. Comins,et al.  The management of pesticide resistance. , 1977, Journal of theoretical biology.

[30]  H. Comins,et al.  The development of insecticide resistance in the presence of migration. , 1977, Journal of theoretical biology.

[31]  Michael P. Hassell,et al.  DENSITY-DEPENDENCE IN SINGLE-SPECIES POPULATIONS , 1975 .

[32]  Rex Consortium,et al.  Heterogeneity of selection and the evolution of resistance. , 2013, Trends in ecology & evolution.

[33]  Robert D. Holt,et al.  On the evolutionary ecology of species' ranges , 2003 .

[34]  S. Sims,et al.  Evaluating transgenic plants for suitability in pest and resistance management programs , 2000 .

[35]  F. Gould Sustainability of transgenic insecticidal cultivars: integrating pest genetics and ecology. , 1998, Annual review of entomology.