Northward migration under a changing climate: a case study of blackgum (Nyssa sylvatica)
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Species are predicted to shift their distribution ranges in response to climate change. Region-wide, empirically-based studies, however, are still limited to support these predictions. We used a model tree species, blackgum (Nyssa sylvatica), to study climate-induced range shift. Data collected from two separate sampling periods (1980s and 2007) by the USDA’s Forestry and Inventory Analysis (FIA) Program were used to investigate changes in abundance and dominance, and shifts in distribution, of blackgum in four ecoregions of the eastern United States. Our results indicated new recruitment of blackgum in the northern portion of its range, along with increases in both density and annual rates of change in importance value (IV). Conversely, declines in recruitment were found in the southern portion of blackgum’s range, along with decreases in density and IV. The center portion of blackgum’s range had mixed patterns of change (i.e., both increases and decreases) throughout. A northward range expansion was also detected by comparing blackgum’s historic range to where it was detected during our two more-recent sampling periods. Our findings suggest that blackgum is migrating north in response to climate change. Our study also suggests two broader implications about tree migration patterns in response to climate change: (1) species can respond to changing climate in relatively short time periods, at least for generalist species such as blackgum, and (2) climate-induced vegetation dynamic patterns can be detected at the regional level, but are inherently complex.
KeywordsKriging Stem Density Range Shift Valuable Ecosystem Service Importance Value
We would like to thank Gabriela Nuñez-Mir, Teresa Clark and Louis Desprez for editing prior versions of this manuscript, and three anonymous reviewers for providing constructive comments on an earlier version of the manuscript.
Johanna Desprez contributed to the idea development, conducted most data analysis, most of the writing and manuscript preparation. Basil V. Iannone III provided intellectual input, statistical and organizational advice, and contributed to editing and writing. Peilin Yang conducted data analysis. Chris Oswalt contributed to data compilation and organization. Songlin Fei contributed the initial idea, participated in data analysis, and manuscript preparation.
Conflict of Interest
- Abrams MD, Copenheaver CA, Black BA, Svd G (2001) Dendroecology and climatic impacts for a relict, old-growth, bog forest in the Ridge and Valley Province of central Pennsylvania, USA. Can J Bot 79:58–69Google Scholar
- Bailey RG, Avers PE, King T, McNab WH (1994) Ecoregions and subregions of the United States (map). Washington, DC. US Geological Survey. Scale 1Google Scholar
- Bechtold WA, Patterson PL (eds.) (2005) The enhanced forest inventory and analysis program - national sampling design and estimation procedures. General Technical Report SRS-80., U.S. Department of Agriculture, Forest Service, Southern Research Station, Asheville.Google Scholar
- Burns RM, Honkala BH (1990) Silvics of North America: Volume 2, Hardwoods. Agriculture handbook 654Google Scholar
- Dale VH, Joyce LA, McNulty S, Neilson RP, Ayres MP, Flannigan MD, Hanson PJ, Irland LC, Lugo AE, Peterson CJ (2001) Climate change and forest disturbances: climate change can affect forests by altering the frequency, intensity, duration, and timing of fire, drought, introduced species, insect and pathogen outbreaks, hurricanes, windstorms, ice storms, or landslides. Bioscience 51:723–734CrossRefGoogle Scholar
- Gonzalez P, Hasson R, Lakyda P, McCallum I, Nilsson S, Pulhin J, van Rosenberg B, Scholes B, Shvidenko A, Barber CV, Persson R (2005) Forest and woodland systems. In: Hassan R, Scholes R, Ash N (eds) Millennium ecosystem assessment: ecosystems and human well-being: current state & trends assessment. Island Press, Washington, pp 585–621Google Scholar
- Heffernan JB, Soranno PA, Angilletta MJ, Buckley LB, Gruner DS, Keitt TH, Kellner JR, Kominoski JS, Rocha AV, Xiao J, Harms TK, Goring SJ, Koenig LE, McDowell WH, Powell H, Richardson AD, Stow CA, Vargas R, Weathers KC (2014) Macrosystems ecology: understanding ecological patterns and processes at continental scales. Front Ecol Environ 12:5–14CrossRefGoogle Scholar
- Karl TR, Melillo JM, Peterson TC (2009) Global climate change impacts in the United States. Cambridge University Press, CambridgeGoogle Scholar
- Little EL (1971) Atlas of United States trees: Vol. 1. Conifers and important hardwoods. US Dep. Agric. Misc. Publ.Google Scholar
- Stocker T, Qin D, Plattner G, Tignor M, Allen S, Boschung J, Nauels A, Xia Y, Bex V, Midgley P (2013) IPCC 2013: Summary for Policy Makers. Climate ChangeGoogle Scholar