The importance of eco-evolutionary dynamics for predicting and managing insect range shifts.

[1]  Rebekah A. Oomen,et al.  Genomic reaction norms inform predictions of plastic and adaptive responses to climate change , 2022, The Journal of animal ecology.

[2]  C. Parmesan,et al.  Mosaics of climatic stress across species' ranges: tradeoffs cause adaptive evolution to limits of climatic tolerance , 2022, Philosophical Transactions of the Royal Society B.

[3]  L. Lancaster On the macroecological significance of eco-evolutionary dynamics: the range shift–niche breadth hypothesis , 2022, Philosophical Transactions of the Royal Society B.

[4]  K. Pfeiffer,et al.  A new innovative real-time tracking method for flying insects applicable under natural conditions , 2021, BMC zoology.

[5]  R. Stoks,et al.  Convergence of life history and physiology during range expansion toward the phenotype of the native sister species. , 2021, The Science of the total environment.

[6]  M. Wiemers,et al.  Reduced host‐plant specialization is associated with the rapid range expansion of a Mediterranean butterfly , 2021, Journal of Biogeography.

[7]  C. Nieberding,et al.  Oviposition site selection and learning in a butterfly under niche expansion: an experimental test , 2021, Animal Behaviour.

[8]  L. Bernatchez,et al.  Epigenetic inheritance and reproductive mode in plants and animals. , 2021, Trends in ecology & evolution.

[9]  S. Beissinger,et al.  Why Are Species’ Traits Weak Predictors of Range Shifts? , 2021, Annual Review of Ecology, Evolution, and Systematics.

[10]  H. Hines,et al.  Expanding insect pollinators in the Anthropocene , 2021, Biological reviews of the Cambridge Philosophical Society.

[11]  C. Parmesan,et al.  Colonizations cause diversification of host preferences: A mechanism explaining increased generalization at range boundaries expanding under climate change , 2021, Global change biology.

[12]  K. Fischer,et al.  Indications for rapid evolution of trait means and thermal plasticity in range‐expanding populations of a butterfly , 2021, Journal of evolutionary biology.

[13]  S. Diamond,et al.  Buying Time: Plasticity and Population Persistence , 2021, Phenotypic Plasticity & Evolution.

[14]  Rachael Y. Dudaniec,et al.  Latitudinal clines in sexual selection, sexual size dimorphism, and sex-specific genetic dispersal during a poleward range expansion. , 2021, The Journal of animal ecology.

[15]  R. Stoks,et al.  Evolution of cold tolerance and thermal plasticity in life history, behaviour and physiology during a poleward range expansion. , 2021, The Journal of animal ecology.

[16]  S. Greenwood,et al.  The role of climate change in pollinator decline across the Northern Hemisphere is underestimated. , 2021, The Science of the total environment.

[17]  H. Van Dyck,et al.  Range expansion, habitat use, and choosiness in a butterfly under climate change: Marginality and tolerance of oviposition site selection , 2021, Ecology and evolution.

[18]  P. Sihvonen,et al.  Combining range and phenology shifts offers a winning strategy for boreal Lepidoptera. , 2021, Ecology letters.

[19]  A. Shapiro,et al.  Insects and recent climate change , 2020, Proceedings of the National Academy of Sciences.

[20]  J. Hill,et al.  Wing morphological responses to latitude and colonisation in a range expanding butterfly , 2020, PeerJ.

[21]  John D. J. Clare,et al.  Generalized model-based solutions to false positive error in species detection/non-detection data. , 2020, Ecology.

[22]  K. Spanier,et al.  Genetic compensation rather than genetic assimilation drives the evolution of plasticity in response to mild warming across latitudes in a damselfly , 2020, Molecular ecology.

[23]  Allison K. Shaw,et al.  Eco-evolutionary dynamics of range expansion. , 2020, Ecology.

[24]  T. J. Stevenson,et al.  Epigenetic responses to temperature and climate. , 2020, Integrative and comparative biology.

[25]  R. Bertrand,et al.  Species better track climate warming in the oceans than on land , 2020, Nature Ecology & Evolution.

[26]  L. Lancaster Host use diversification during range shifts shapes global variation in Lepidopteran dietary breadth , 2020, Nature Ecology & Evolution.

[27]  Jenica M. Allen,et al.  Adjusting the lens of invasion biology to focus on the impacts of climate-driven range shifts , 2020, Nature Climate Change.

[28]  Lynn B. Martin,et al.  Epigenetic Potential in Native and Introduced Populations of House Sparrows (Passer domesticus). , 2020, Integrative and comparative biology.

[29]  A. Hargreaves,et al.  Miniaturizing landscapes to understand species distributions , 2020 .

[30]  S. Eigenbrode,et al.  Complex responses of global insect pests to climate warming , 2020 .

[31]  Brad M. Ochocki,et al.  Demography-Dispersal Trait Correlations Modify the Eco-Evolutionary Dynamics of Range Expansion , 2020, The American Naturalist.

[32]  F. Ronquist,et al.  The Swedish Malaise Trap Project: A 15 Year Retrospective on a Countrywide Insect Inventory , 2020, Biodiversity data journal.

[33]  R. Kofler,et al.  Evolutionary genomics can improve prediction of species’ responses to climate change , 2020, Evolution letters.

[34]  S. Strauss,et al.  Host plant adaptation during contemporary range expansion in the monarch butterfly , 2019, Evolution; international journal of organic evolution.

[35]  S. Cushman,et al.  Modelling multilocus selection in an individual‐based, spatially‐explicit landscape genetics framework , 2019, Molecular ecology resources.

[36]  K. Tougeron,et al.  Animal-Microbe Interactions in the Context of Diapause , 2019, The Biological Bulletin.

[37]  P. Haase,et al.  Elevated temperatures translate into reduced dispersal abilities in a natural population of an aquatic insect. , 2019, The Journal of animal ecology.

[38]  Nicolas Ray,et al.  SPLATCHE3: simulation of serial genetic data under spatially explicit evolutionary scenarios including long-distance dispersal , 2019, Bioinform..

[39]  Brenna R. Forester,et al.  Considering adaptive genetic variation in climate change vulnerability assessment reduces species range loss projections , 2019, Proceedings of the National Academy of Sciences.

[40]  L. Lancaster,et al.  Evolving social dynamics prime thermal tolerance during a poleward range shift , 2019, Biological Journal of the Linnean Society.

[41]  M. Duryea,et al.  Temperature drives pre-reproductive selection and shapes the biogeography of a female polymorphism. , 2019, Ecology letters.

[42]  Rachael Y. Dudaniec,et al.  Signatures of local adaptation along environmental gradients in a range‐expanding damselfly (Ischnura elegans) , 2018, Molecular ecology.

[43]  C. Nieberding,et al.  Adaptive learning in non-social insects: from theory to field work, and back. , 2018, Current opinion in insect science.

[44]  S. Chown,et al.  Basal resistance enhances warming tolerance of alien over indigenous species across latitude , 2017, Proceedings of the National Academy of Sciences.

[45]  J. Polechová Is the sky the limit? On the expansion threshold of a species’ range , 2017, bioRxiv.

[46]  L. Lancaster,et al.  Range shifting species reduce phylogenetic diversity in high latitude communities via competition , 2017, The Journal of animal ecology.

[47]  L. Lancaster,et al.  Life history trade-offs, the intensity of competition, and coexistence in novel and evolving communities under climate change , 2017, Philosophical Transactions of the Royal Society B: Biological Sciences.

[48]  L. Lancaster Widespread range expansions shape latitudinal variation in insect thermal limits , 2016 .

[49]  M. Wellenreuther,et al.  Gene expression under thermal stress varies across a geographical range expansion front , 2016, Molecular ecology.

[50]  R. Stoks,et al.  Neutral and adaptive genomic signatures of rapid poleward range expansion , 2015, Molecular ecology.

[51]  I. Hanski,et al.  Eco-evolutionary spatial dynamics in the Glanville fritillary butterfly , 2011, Proceedings of the National Academy of Sciences.

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

[53]  Tim G Benton,et al.  Accelerating invasion rates result from the evolution of density-dependent dispersal. , 2009, Journal of theoretical biology.

[54]  L. Conradt,et al.  Ecological and evolutionary processes at expanding range margins , 2001 .