Evolution of critical day length for diapause induction enables range expansion of Diorhabda carinulata, a biological control agent against tamarisk (Tamarix spp.)
Version of Record online: 16 APR 2012
© 2012 The Authors. Evolutionary Applications published by Blackwell Publishing Ltd.
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Special Issue: Evolution and Biological Control
Volume 5, Issue 5, pages 511–523, July 2012
How to Cite
Bean, D. W., Dalin, P. and Dudley, T. L. (2012), Evolution of critical day length for diapause induction enables range expansion of Diorhabda carinulata, a biological control agent against tamarisk (Tamarix spp.). Evolutionary Applications, 5: 511–523. doi: 10.1111/j.1752-4571.2012.00262.x
- Issue online: 10 JUL 2012
- Version of Record online: 16 APR 2012
- Received: 19 February 2012 Accepted: 6 March 2012 First published online: 16 April 2012
- 2010. A river system to watch: documenting the effects of saltcedar (Tamarix spp.) biocontrol in the Virgin River valley. Ecological Restoration28:405–410. , , , , , and .
- 2007a. Seasonal timing of diapause induction limits the effective range of Diorhabda elongata deserticola (Coleoptera: Chrysomelidae) as a biological control agent for tamarisk (Tamarix spp.). Environmental Entomology36:15–25. , , and .
- 2007b. Diapause in the leaf beetle Diorhabda elongata (Coleoptera: Chrysomelidae), a biological control agent for tamarisk (Tamarix spp.). Environmental Entomology36:531–540. , , , and .
- 1980. Insect Photoperiodism, 2nd edn. Academic Press, New York, NY.
- 2001. Genetic shift in photoperiodic response correlated with global warming. Proceedings of the National Academy of Sciences of the United States of America98:14509–14511. , and .
- 2007. Evolution on ecological time scales. Functional Ecology21:387–393. , , , and .
- 1996. Epistasis as a source of increased additive genetic variance at population bottlenecks. Evolution50:1042–1051. , and .
- 2010. Why does phenology drive species distribution?Philosophical Transactions of the Royal Society B365:3149–3160.
- 2005. The aggregation pheromone of Diorhabda elongata, a biological control agent of saltcedar (Tamarix spp.): identification of two behaviorally active components. Journal of Chemical Ecology31:657–670. , , , , and .
- 2010. Seasonal adaptations to day length in ecotypes of Diorhabda spp. (Coleoptera: Chrysomelidae) inform selection of agents against saltcedars (Tamarix spp.). Environmental Entomology39:1666–1675. , , , , , , et al.
- 1987. Insect Dormancy: An Ecological Perspective. Biological Survey of Canada, Ottawa, Canada.
- 2003. Host specificity of the leaf beetle, Diorhabda elongata deserticola (Coleoptera: Chrysomelidae) from Asia, a biocontrol agent for saltcedars (Tamarix: Tamaricaceae) in the Western United States. Biological Control27:117–147. , , , , , and .
- 2004. First results for control of saltcedar (Tamarix spp.) in the open field in the western United States. in J. Cullen ed. Eleventh International Symposium on Biological Control of Weeds, Canberra, Australia. , , , , , , et al.
- 2008a. Founding events in species invasions: genetic variation, adaptive evolution and the role of multiple introductions. Molecular Ecology17:431–449. , and .
- 2008b. Invading populations of an ornamental shrub show rapid life history evolution despite genetic bottlenecks. Ecology Letters11:701–709. , and .
- 2012. Tamarisk biocontrol, endangered species risk and resolution of conflict through riparian restoration. BioControl57:331–347. , and .
- 2004. Saltcedar (Tamarix spp.), endangered species, and biological weed control – can they mix?Weed Technology18:1542–1551. , and .
- 2009. Complications of complexity: integrating environmental, genetic and hormonal control of insect diapause. Trends in Genetics25:217–225. , , and .
- 2005. Resolving the genetic paradox in invasive species. Heredity94:385.
- 2005. Dominance of non-native riparian trees in western USA. Biological Invasions7:747–751. , , , , , , and .
- 2011. Genetic and environmental influences on leaf phenology and cold hardiness of native and introduced riparian trees. International Journal of Biometeorology55:775–787. , , and .
- 2003. Molecular phylogenetic investigation of U.S. invasive Tamarix. Systematic Botany28:86–95. , and .
- 1997. Geographic variation in critical photoperiod for diapause induction and its temperature dependence in Hyphantria cunea Drury (Lepidoptera: Arctiidae). Oecologia111:160–165.
- 2007. Seasonal adaptations of the fall webworm Hyphantria cunea (Drury) (Lepidoptera: Arctiidae) following its invasion of Japan. Ecological Research22:855–861.
- 2004. Mitochondrial DNA analysis of the introduced fall webworm, showing its shift in life cycle in Japan. Entomological Science7:183–188. , , and .
- 2007. Shifting of the life cycle and life-history traits of the fall webworm in relation to climate change. Entomologia Experimentalis et Applicata125:179–184. , , , and .
- 2005. The voyage of an invasive species across continents: genetic diversity of North American and European Colorado potato beetle populations. Molecular Ecology14:4027–4219. , , , , and .
- 2005. Rapid evolution and the convergence of ecological and evolutionary time. Ecology Letters8:1114–1127. , , , , and .
- 1999. The pace of modern life: measuring rates of contemporary microevolution. Evolution53:1637–1653. , and .
- 2011. Evolutionary principles and their practical application. Evolutionary Applications4:159–183. , , , , , , et al.
- 2005. Estimating temperature-dependent developmental rates of Diorhabda elongata (Coleoptera: Chrysomelidae), a biological control agent of saltcedar (Tamarix spp.). Environmental Entomology34:775–784. , , , and .
- 2007. Defoliation by introduced Diorhabda elongata leaf beetles (Coleoptera: Chrysomelidae) reduces carbohydrate reserves and regrowth of Tamarix (Tamaricaceae). Biological Control43:213–221. , , , , , , and .
- 2008. Biological invasions: paradox lost and paradise gained. Current Biology18:R246–R247.
- 2005. Microevolution in biological control: mechanisms, patterns and processes. Biological Control35:227–239. , and .
- 2005. Evolution of phenotypic plasticity: patterns of plasticity and the emergence of ecotypes. New Phytologist166:101–118.
- 1991. Geographic origin of the United States and Brazilian Aedes albopictus inferred from allozyme analysis. Heredity67:85–94. , , and .
- 2002. Is host specificity of weed biological control agents likely to evolve rapidly following establishment?Ecology Letters5:590–596. , and .
- 2011. Incorporating evolutionary principles into environmental management and policy. Evolutionary Applications4:315–325. , , , and .
- 2003. Biology of Diorhabda elongata deserticola (Coleoptera: Chrysomelidae), an Asian leaf beetle for biological control of saltcedars (Tamarix spp.) in the United States. Biological Control27:101–116. , , , and .
- 2000. An observation on the life cycle of Diorhabda elongata deserticola Chen: a potential biocontrol agent of saltcedar. Chinese Journal of Biological Control16:48–49. , , and .
- 2010. Underutilized resources for studying the evolution of invasive species during their introduction, establishment, and lag phases. Evolutionary Applications3:203–219. , , , , , , et al.
- 1975. The bottleneck effect and genetic variability in populations. Evolution29:1–10. , , and .
- 2010. Methods to control saltcedar and Russian olive. pp. 65–102. In P. B. Shafroth, C. A. Brown, and D. M. Merritt, eds. Saltcedar and Russian olive control demonstration act science assessment: U.S. Geological Survey Scientific Investigations Report 2009–5247, 143 p. , , and
- 2007. The ecology of the southwestern willow flycatcher in Central Arizona-a 10-year synthesis report. USGS Open-File Report 2007-1381. , , , , and
- 2000. Predictable risk to native plants in weed biological control. Oecologia125:489–494.
- 2010. Life-history evolution in range-shifting populations. Ecology96:1617–1627. , , and .
- 2011. Energy use, diapause behavior and northern range expansion potential in the invasive Colorado potato beetle. Functional Ecology25:527–536. , , , and .
- 2001. The population ecology of contemporary adaptations: what empirical studies reveal about the conditions that promote adaptive evolution. Genetica112–113:183–198. , and .
- 2003. Genes in new environments: genetics and evolution in biological control. Nature Review Genetics4:889–899. , and .
- 2001. Geographical strains and selection for the diapause trait in Calliphora vicina. In D. L. Denlinger, J. M. Giebultowicz, and D. S. Saunders, eds. Insect Timing: Circadian Rhythmicity to Seasonality, pp. 113–122. Elsevier, New York, NY.
- 2002. Insect Clocks, 3rd edn. Elsevier Science, Amsterdam, The Netherlands.
- SAS Institute2008. SAS/STAT User’s Guide, Version 9.2. SAS Institute, Cary, NC, USA.
- 2011. The newest synthesis: understanding the interplay of evolutionary and ecological dynamics. Science331:426–429.
- 2005. Control of Tamarix in the western United States: implications for water salvage, wildlife use, and riparian restoration. Environmental Management35:231–246. , , , , , , and .
- 1986. Seasonal Adaptations of Insects. Oxford University Press, New York, NY. , , and .
- 1988. Fitness functions for alternative developmental pathways in the timing of diapause induction. American Naturalist131:678–699. , and .
- 2001. Ecological and evolutionary processes at expanding range margins. Nature411:577–581. , , , , , , and .
- 2011. Evolution in agriculture: the application of evolutionary approaches to the management of biotic interactions in agro-ecosystems. Evolutionary Applications4:200–215. , , , , , , et al.
- 2009. Taxonomic revision and biogeography of the Tamarix-feeding Diorhabda elongata (Brullé, 1832) species group (Coleoptera: Chrysomelidae: Galerucinae: Galerucini) and analysis of their potential in biological control of Tamarisk. Zootaxa2101:1–152. , and .
- 2006. Will population bottlenecks and multilocus epistasis increase additive genetic variance?Evolution60:1763–1776. , and .
- 2012. Rapid adaptive evolution of photoperiodic response during invasion and range expansion across climatic gradient. The American Naturalist179:490–500. , , , , , and .
- 2009. Population genetics of Aedes albopictus (Diptera: Culicidae) invading populations, using mitochondrial nicotinamide adenine dinucleotide dehydrogenase subunit 5 sequences. Annals of the Entomological Society of America102:144–150. , , and .
- 2003. Developmental Plasticity and Evolution. Oxford, Oxford University Press.
- 1981. Geographic diversity of the Colorado potato beetle and its infestation in Eurasia. In J. H. Lashcomb, and R. Casagrande, eds. Advances in Potato Pest Management, pp. 47–68. Hutchinson Ross, Stroudsburg, PA. , and .