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CHAPTER NINE - Grassland invasion in a changing climate

from Part II - Species traits, functional groups, and evolutionary change

Published online by Cambridge University Press:  22 March 2019

David J. Gibson
Affiliation:
Southern Illinois University, Carbondale
Jonathan A. Newman
Affiliation:
University of Guelph, Ontario
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Publisher: Cambridge University Press
Print publication year: 2019

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References

9.7 References

Bradley, BA, Blumenthal, DM, Wilcove, DS, Ziska, LH. Predicting plant invasions in an era of global change. Trends in Ecology & Evolution. 2010;25(5):310–8.CrossRefGoogle Scholar
Bowler, DE, Hof, C, Haase, P, Kröncke, I, Schweiger, O, Adrian, R, et al. Cross-realm assessment of climate change impacts on species’ abundance trends. Nature Ecology & Evolution. 2017;1:0067.CrossRefGoogle ScholarPubMed
Blumenthal, DM, Resco, V, Morgan, JA, Williams, DG, Lecain, DR, Hardy, EM, et al. Invasive forb benefits from water savings by native plants and carbon fertilization under elevated CO2 and warming. New Phytologist. 2013;200(4):1156–65.Google Scholar
Hulme, PE. Climate change and biological invasions: evidence, expectations, and response options. Biological Reviews. 2017;92(3):1297–313.CrossRefGoogle ScholarPubMed
Liu, Y, Oduor, AMO, Zhang, Z, Manea, A, Tooth, IM, Leishman, MR, et al. Do invasive alien plants benefit more from global environmental change than native plants? Global Change Biology. 2017;23(8):3363–70.CrossRefGoogle ScholarPubMed
Bellard, C, Thuiller, W, Leroy, B, Genovesi, P, Bakkenes, M, Courchamp, F. Will climate change promote future invasions? Global Change Biology. 2013;19:3740–8.Google Scholar
Bradley, BA. Regional analysis of the impacts of climate change on cheatgrass invasion shows potential risk and opportunity. Global Change Biology. 2009;15(1):196208.CrossRefGoogle Scholar
Catford, JA, Baumgartner, JB, Vesk, PA, White, M, Buckley, YM, McCarthy, MA. Disentangling the four demographic dimensions of species invasiveness. Journal of Ecology. 2016;104(6):1745–58.Google Scholar
Seabloom, EW, Borer, ET, Buckley, Y, Cleland, EE, Davies, K, Firn, J, et al. Predicting invasion in grassland ecosystems: is exotic dominance the real embarrassment of richness? Global Change Biology. 2013;19(12):3677–87.CrossRefGoogle ScholarPubMed
Catford, JA, Vesk, PA, Richardson, DM, Pyšek, P. Quantifying levels of biological invasion: towards the objective classification of invaded and invasible ecosystems. Global Change Biology. 2012;18(1):4462.Google Scholar
Fridley, JD, Sax, DF. The imbalance of nature: revisiting a Darwinian framework for invasion biology. Global Ecology and Biogeography. 2014;23(11):1157–66.Google Scholar
Invasive Species Specialist Group (ISSG). The Global Invasive Species Database (IUCN) 2015 [available from: www.iucngisd.org/gisd/].Google Scholar
Seabloom, EW, Borer, ET, Buckley, YM, Cleland, EE, Davies, KF, Firn, J, et al. Plant species’ origin predicts dominance and response to nutrient enrichment and herbivores in global grasslands. Nature Communications. 2015;6.Google Scholar
Catford, JA, Jansson, R. Drowned, buried and carried away: effects of plant traits on the distribution of native and alien species in riparian ecosystems. New Phytologist. 2014;204(1):1936.Google Scholar
Catford, JA, Jansson, R, Nilsson, C. Reducing redundancy in invasion ecology by integrating hypotheses into a single theoretical framework. Diversity & Distributions. 2009;15(1):2240.CrossRefGoogle Scholar
Mitchell, RM, Bakker, JD, Vincent, JB, Davies, GM. Relative importance of abiotic, biotic, and disturbance drivers of plant community structure in the sagebrush steppe. Ecological Applications. 2017;27(3):756–68.CrossRefGoogle ScholarPubMed
Moles, AT, Flores-Moreno, H, Bonser, SP, Warton, DI, Helm, A, Warman, L, et al. Invasions: the trail behind, the path ahead, and a test of a disturbing idea. Journal of Ecology. 2012;100(1):116–27.CrossRefGoogle Scholar
Davis, MA, Grime, JP, Thompson, K. Fluctuating resources in plant communities: a general theory of invasibility. Journal of Ecology. 2000;88:528–34.Google Scholar
MacDougall, AS, Turkington, R. Are invasive species the drivers or passengers of change in degraded ecosystems? Ecology. 2005;86(1):4255.Google Scholar
Blumenthal, DM, Kray, JA. Climate change, plant traits, and invasion in natural and agricultural ecosystems. In: Ziska, L, Dukes, JS, editors. Invasive species and global climate change. Wallingford: CABI Press; 2014. pp. 6280.CrossRefGoogle Scholar
Catford, JA, Downes, BJ, Gippel, CJ, Vesk, PA. Flow regulation reduces native plant cover and facilitates exotic invasion in riparian wetlands. Journal of Applied Ecology. 2011;48(2):432–42.Google Scholar
Catford, JA, Morris, WK, Vesk, PA, Gippel, CJ, Downes, BJ. Species and environmental characteristics point to flow regulation and drought as drivers of riparian plant invasion. Diversity and Distributions. 2014;20(9):1084–96.Google Scholar
Dawson, SK, Warton, DI, Kingsford, RT, Berney, P, Keith, DA, Catford, JA. Plant traits of propagule banks and standing vegetation reveal flooding alleviates impacts of agriculture on wetland restoration. Journal of Applied Ecology. 2017;54(6):1907–18.CrossRefGoogle Scholar
Tecco, PA, Díaz, S, Cabido, M, Urcelay, C. Functional traits of alien plants across contrasting climatic and land-use regimes: do aliens join the locals or try harder than them? Journal of Ecology. 2010;98(1):1727.Google Scholar
Bradley, BA, Early, R, Sorte, CJB. Space to invade? Comparative range infilling and potential range of invasive and native plants. Global Ecology and Biogeography. 2015;24(3):348–59.Google Scholar
Higgins, SI, Richardson, DM. Invasive plants have broader physiological niches. Proceedings of the National Academy of Sciences of the USA. 2014;111(29):10,610–4.CrossRefGoogle ScholarPubMed
Rejmánek, M. Invasiveness. In: Simberloff, D, Rejmánek, M, editors. Encyclopedia of biological invasions. Berkeley, CA: University of California Press; 2011. pp. 379–85.Google Scholar
Wainwright, CE, Wolkovich, EM, Cleland, EE. Seasonal priority effects: implications for invasion and restoration in a semi-arid system. Journal of Applied Ecology. 2012;49(1):234–41.CrossRefGoogle Scholar
Wolkovich, EM, Cleland, EE. The phenology of plant invasions: a community ecology perspective. Frontiers in Ecology and the Environment. 2011;9(5):287–94.Google Scholar
Wolkovich, EM, Cleland, EE. Phenological niches and the future of invaded ecosystems with climate change. AoB Plants. 2014;6:plu013.CrossRefGoogle ScholarPubMed
van Kleunen, M, Weber, E, Fischer, M. A meta-analysis of trait differences between invasive and non-invasive plant species. Ecology Letters. 2010;13(2):235–45.Google Scholar
Sandel, B, Dangremond, EM. Climate change and the invasion of California by grasses. Global Change Biology. 2012;18(1):277–89.CrossRefGoogle Scholar
Hellmann, JJ, Byers, JE, Bierwagen, BG, Dukes, JS. Five potential consequences of climate change for invasive species. Conservation Biology. 2008;22(3):534–43.Google Scholar
Petitpierre, B, McDougall, K, Seipel, T, Broennimann, O, Guisan, A, Kueffer, C. Will climate change increase the risk of plant invasions into mountains? Ecological Applications. 2016;26(2):530–44.CrossRefGoogle ScholarPubMed
Dukes, JS, Mooney, HA. Does global change increase the success of biological invaders? Trends in Ecology & Evolution. 1999;14(4):135–9.CrossRefGoogle ScholarPubMed
White, TA, Campbell, BD, Kemp, PD, Hunt, CL. Impacts of extreme climatic events on competition during grassland invasions. Global Change Biology. 2001;7(1):113.Google Scholar
Bremond, L, Boom, A, Favier, C. Neotropical C3/C4 grass distributions – present, past and future. Global Change Biology. 2012;18(7):2324–34.CrossRefGoogle Scholar
Walther, G-R, Roques, A, Hulme, PE, Sykes, MT, Pyšek, P, Kühn, I, et al. Alien species in a warmer world: risks and opportunities. Trends in Ecology & Evolution. 2009;24(12):686–93.Google Scholar
Berg, RY. Plant distribution as seen from plant dispersal: general principles and basic modes of plant dispersal. In: Kubitzki, K, editor. Dispersal and distribution: an international symposium. Hamburg: Paul Parey; 1983. pp. 1336.Google Scholar
Nathan, R, Schurr, FM, Spiegel, O, Steinitz, O, Trakhtenbrot, A, Tsoar, A. Mechanisms of long-distance seed dispersal. Trends in Ecology & Evolution. 2008;23(11):638–47.CrossRefGoogle ScholarPubMed
Bates, AE, Pecl, GT, Frusher, S, Hobday, AJ, Wernberg, T, Smale, DA, et al. Defining and observing stages of climate-mediated range shifts in marine systems. Global Environmental Change – Human Policy Dimensions. 2014;26:2738.Google Scholar
Sheppard, CS, Alexander, JM, Billeter, R. The invasion of plant communities following extreme weather events under ambient and elevated temperature. Plant Ecology. 2012;213:1289–301.Google Scholar
Diez, JM, D’Antonio, CM, Dukes, JS, Grosholz, ED, Olden, JD, Sorte, CJB, et al. Will extreme climatic events facilitate biological invasions? Frontiers in Ecology and the Environment. 2012;10(5):249–57.CrossRefGoogle Scholar
Catford, JA, Daehler, CC, Murphy, HT, Sheppard, AW, Hardesty, BD, Westcott, DA, et al. The intermediate disturbance hypothesis and plant invasions: implications for species richness and management. Perspectives in Plant Ecology, Evolution and Systematics. 2012;14:231–41.Google Scholar
Grime, JP. Evidence for the existence of three primary strategies in plants and its relevance to ecological and evolutionary theory. The American Naturalist. 1977;111(982):1169–94.Google Scholar
Tilman, D. Resource competition and community structure. Princeton, NJ: Princeton University Press; 1982.Google ScholarPubMed
Mata, TM, Haddad, NM, Holyoak, M. How invader traits interact with resident communities and resource availability to determine invasion success. Oikos. 2013;122(1):149–60.CrossRefGoogle Scholar
Seabloom, EW, Harpole, WS, Reichman, OJ, Tilman, D. Invasion, competitive dominance, and resource use by exotic and native California grassland species. Proceedings of the National Academy of Sciences of the USA. 2003;100(23):13,384–9.Google Scholar
Kane, JM, Meinhardt, KA, Chang, T, Cardall, BL, Michalet, R, Whitham, TG. Drought-induced mortality of a foundation species (Juniperus monosperma) promotes positive afterlife effects in understory vegetation. Plant Ecology. 2011;212(5):733–41.CrossRefGoogle Scholar
Liu, Y, Oduor, AMO, Zhang, Z, Manea, A, Tooth, IM, Leishman, MR, et al. Do invasive alien plants benefit more from global environmental change than native plants? Global Change Biology. 2017;23(8):3363–70.Google Scholar
Blumenthal, D, Mitchell, CE, Pyšek, P, Jarošík, V. Synergy between pathogen release and resource availability in plant invasion. Proceedings of the National Academy of Sciences of the USA. 2009;106(19):7899–904.Google Scholar
Richardson, DM, Pyšek, P, Rejmánek, M, Barbour, MG, Panetta, FD, West, CJ. Naturalization and invasion of alien plants: concepts and definitions. Diversity and Distributions. 2000;6:93107.Google Scholar
D’Antonio, CM, Vitousek, PM. Biological invasions by exotic grasses, the grass/fire cycle, and global change. Annual Review of Ecology and Systematics. 1992;23(1):6387.Google Scholar
Rossiter, NA, Setterfield, SA, Douglas, MM, Hutley, LB. Testing the grass–fire cycle: alien grass invasion in the tropical savannas of northern Australia. Diversity & Distributions. 2003;9(3):169–76.Google Scholar
D’Antonio, CM. Fire, plant invasions, and global changes. In: Mooney, H, Hobbs, RJ, editors. Invasive species in a changing world. Washington, DC: Island Press; 2000. pp. 6594.Google Scholar
Kueffer, C. Transdisciplinary research is needed to predict plant invasions in an era of global change. Trends in Ecology & Evolution. 2010;25(11):619–20.Google Scholar
Tilman, D, Hill, J, Lehman, C. Carbon-negative biofuels from low-input high-diversity grassland biomass. Science. 2006;314(5805):1598–600.Google Scholar
Hager, HA, Sinasac, SE, Gedalof, Ze, Newman, JA. Predicting potential global distributions of two Miscanthus grasses: implications for horticulture, biofuel production, and biological invasions. PLoS ONE. 2014;9(6):e100032.Google Scholar
Parrish, DJ, Fike, JH. The biology and agronomy of switchgrass for biofuels. Critical Reviews in Plant Sciences. 2005;24(5–6):423–59.Google Scholar
Barney, JN, DiTomaso, JM. Bioclimatic predictions of habitat suitability for the biofuel switchgrass in North America under current and future climate scenarios. Biomass and Bioenergy. 2010;34(1):124–33.Google Scholar
Driscoll, D, Catford, J. Invasive plants: new pasture plants pose weed risk. Nature. 2014;516(7529):37.CrossRefGoogle Scholar
Driscoll, DA, Catford, JA, Barney, JN, Hulme, PE, Inderjit, , Martin, TG, et al. New pasture plants intensify invasive species risk. Proceedings of the National Academy of Sciences of the USA. 2014; 111(46):16,622–7.Google Scholar
Bradley, BA, Blumenthal, DM, Early, R, Grosholz, ED, Lawler, JJ, Miller, LP, et al. Global change, global trade, and the next wave of plant invasions. Frontiers in Ecology and the Environment. 2012;10(1):20–8.Google Scholar
Haeuser, E, Dawson, W, van Kleunen, M. The effects of climate warming and disturbance on the colonization potential of ornamental alien plant species. Journal of Ecology. 2017;105(6):1698–708.Google Scholar
Rinella, MJ, Maxwell, BD, Fay, PK, Weaver, T, Sheley, RL. Control effort exacerbates invasive-species problem. Ecological Applications. 2009;19(1):155–62.Google Scholar
Mueller, KE, Blumenthal, DM, Pendall, E, Carrillo, Y, Dijkstra, FA, Williams, DG, et al. Impacts of warming and elevated CO2 on a semi-arid grassland are non-additive, shift with precipitation, and reverse over time. Ecology Letters. 2016;19(8):956–66.Google Scholar
Blumenthal, DM, Kray, JA, Ortmans, W, Ziska, LH, Pendall, E. Cheatgrass is favored by warming but not CO2 enrichment in a semi-arid grassland. Global Change Biology. 2016;22(9):3026–38.Google Scholar
Adler, PB, Leiker, J, Levine, JM. Direct and indirect effects of climate change on a prairie plant community. PLoS ONE. 2009;4(9):e6887.Google Scholar
Bansal, S, Sheley, RL. Annual grass invasion in sagebrush steppe: the relative importance of climate, soil properties and biotic interactions. Oecologia. 2016;181(2):543–57.CrossRefGoogle ScholarPubMed
Alexander, JM, Diez, JM, Levine, JM. Novel competitors shape species’ responses to climate change. Nature. 2015;525(7570):515–8.Google Scholar

References

Weaver, JE. North American prairie. Lincoln, NB: Johnson Publishing Company; 1954.Google Scholar
Weaver, JE, Albertson, FW. Effects of the great drought on the prairies of Iowa, Nebraska, and Kansas. Ecology. 1936;17:567639.CrossRefGoogle Scholar

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