Abstract
Plant macrofossils and pollen were analyzed from sediment cores to identify long-term changes in the aquatic plant community of Jones Creek, Thousand Islands National Park, Ontario, Canada. Six sediment cores were recovered from Jones Creek in February 2014. One complete core and five top/bottom samples were analyzed for plant macrofossil abundance and diversity. Sediment analysis and 210Pb dating confirmed a productive wetland throughout the core, dating back beyond 1883 AD. Jones Creek is currently dominated by thick stands of cattails, particularly the hybrid white cattail (Typha x glauca Godr). The relative abundance of Typha pollen began to increase in the late nineteenth and early twentieth century, reaching a relative abundance of nearly 40% in the modern day surface sediment. Common macrofossils recovered from the sediment record included seeds of Carex, Schoenoplectus, Najas, and Eleocharis. There is evidence that community composition, as recorded by the macrofossil record, has shifted in Jones Creek in response to human activities. In particular there has been a reduction in sedge species between historical and present day conditions as the wetland shifted from a sedge dominated wet-meadow wetland to a cattail dominated system. The results of our study indicate that future restoration efforts should be directed towards reintroducing native sedge species that were present prior to major changes in land-use that occurred in the St. Lawrence region throughout the nineteenth and twentieth centuries.
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References
Allan JD (2004) Landscapes and riverscapes: the influence of land use on stream ecosystems. Annu Rev Ecol Syst 35:257–284
Angeloni NL, Jankowski KJ, Tuchman NC, Kelly JJ (2006) Effects of an invasive cattail species (Typha x glauca) on sediment nitrogen and microbial community composition in a freshwater wetland. FEMS Microbiol Lett 263:86–92
Appleby (2001) Chronostratigraphic techniques in recent sediments. In: Last WM, Smol JP (eds) Tracking environmental change using lake sediments: volume I: basing analysis, coring, and chronological techniques. Kluwer Academic Publishers, Dordrecht, pp 171–203
Ball JP (1990) Influence of subsequent flooding depth on cattail control by burning and mowing. J Aquat Plant Manag 28:28–32
Birks HH, Birks HJB (2000) Future uses of pollen analysis must include plant macrofossils. J Biogeogr 27:31–35
Bunn S, Arthington A (2002) Basic principles and ecological consequences of altered flow regimes for aquatic biodiversity. Environ Manag 30:492–507
Cvetkovic M, Chow-Fraser P (2011) Use of ecological indicators to assess the quality of great lakes coastal wetlands. Ecol Indic 11:1609–1622
de Groot R, Brander L, van der Ploeg S, Costanza R, Bernard F, Braat L, Christie M, Crossman N, Ghermandi A, Hein L, Hussain S, Kumar P, McVittie A, Portela R, Rodriguez L, Brink P, van Beukerin P (2012) Global estimate of the value of ecosystems and their services in monetary units. Ecosyst Serv 1:50–61
Eyles N, Meriano M, Chow-Fraser P (2013) Impacts of European settlement (1840–present) in a Great Lake watershed and lagoon: Frenchman’s Bay, Lake Ontario, Canada. Environ Earth Sci 68:2211–2228
Farrell JM, Murry BA, Leopold DJ, Halpern A, Rippke MB, Godwin KS, Hafner SD (2010) Water-level regulation and coastal wetland vegetation in the upper St. Lawrence River: inferences from historical aerial imagery, seed banks, and Typha dynamics. Hydrobiologia 647:127–144
Federation of Ontario Naturalists, Wake WC (1996) A nature guide to Ontario. University of Toronto Press, Toronto
Finkelstein SA (2003) Identifying pollen grains of Typha latifolia, Typha angustifolia, and Typha x glauca. Can J Bot 81:985–990
Frieswyk CB, Zedler JB (2007) Vegetation change in great lakes coastal wetlands: deviation from the historical cycle. J Great Lakes Res 33:366–380
Galatowitsch SM, Anderson NO, Ascher PD (1999) Invasiveness in wetland plants in temperate North America. Wetlands 19:733–755
Gibbs JP (2000) Wetland loss and biodiversity conservation. Conserv Biol 14:314–317
Grimm (1987) CONISS: a FORTRAN 77 program for stratigraphically constrained cluster analysis by the method of incremental sum of squares. Comput Geosci 13:13–35
Heiri O, Lotter AF, Lemcke G (2001) Loss on ignition as a method for estimating organic and carbonate content in sediments: reproducibility and comparability of results. J Paleolimnol 25:101–110
Juggins S (2014) Online paleoecological software version 1.7.6. Newcastle University, UK. https://www.staff.ncl.ac.uk/stephen.juggins/software/C2Home.htm. Accessed 14 Jun 2014
Juggins S (2015) Rioja: analysis of Quaternary science data. R package version 0.9-5. https://cran.r-project.org/web/packages/rioja/rioja.pdf
Larkin DJ, Freyman MJ, Lishawa SC, Geddes P, Tuchman NC (2012) Mechanisms of dominance by the invasive hybrid cattail Typha x glauca. Biol Invasions 14:65–77
Lévesque PEM, Dinel H, Larouche A (1988) Guide to the identification of plant macrofossils in Canadian peatlands. Agriculture Canada Publication No. 1817E, Ottawa. doi:10.5962/bhl.title.53794
Lishawa SC, Albert DA, Tuchman NC (2010) Water level decline promotes Typha x glauca establishment and vegetation change in great lakes coastal wetlands. Wetlands 30:1085–1096
Metzger MJ, Acosta-Michlik L, Rounsevell MDA, Leemans R, Schroter D (2006) The vulnerability of ecosystem services to land use change. Agriculture 114:69–85
Mitchell ME, Lishawa SC, Geddes P, Larkin DJ, Treering D, Tuchman NC (2011) Time-dependent impacts of cattail invasion in a great lakes coastal wetland complex. Wetlands 31:1143–1149
Økland KA, Økland J (2000) Freshwater bryozoans (Bryozoa) of Norway: distribution and ecology of Cristatella mucedo and Paludicella articulate. Hydrobiologia 421:1–24
Oksanen J, Blanchet FG, Kindt R, Legendre P, Minchin PR, O’Hara RB, Simpson GL, Solymos P, Stevens MHH, Wagner H (2015) Vegan: community ecology package. R package version 2.3-0. https://cran.r-project.org/web/packages/vegan/vegan.pdf
Osland MJ, Gonzalez E, Richardson CJ (2011) Restoring diversity after cattail expansion: disturbance, resilience, and seasonality in a tropical dry wetland. Ecol Appl 21:715–728
Parks Canada (2013) Ecological integrity statement. http://www.pc.gc.ca/eng/pn-np/on/lawren/natcul/natcul2.aspx. Accessed 5 Feb 2014
R Core Team (2015) R: a language and environment for statistical computing. http://www.R-project.org
Rippke MB, Distler MT, Farrell JM (2010) Holocene vegetation dynamics of an upper St. Lawrence River wetland: paleoecological evidence for a recent increase in cattail (Typha). Wetlands 30:805–816
Schütz W (2000) Ecology of seed dormancy and germination in sedges (Carex). Perspect Plant Ecol Evol Syst 3:67–89
Shih JG, Finkelstein SA (2008) Range dynamics and invasive tendencies in Typha latifolia and Typha angustifolia in eastern North America derived from herbarium and pollen records. Wetlands 28:1–16
Smith SG (1967) Experimental and natural hybrids in North American Typha (Typhaceae). Am Midl Nat 78:257–287
Sojda RS, Solberg KL (1993) Waterfowl management handbook. Fish Wildl Leafl 13(4):13
Stolze S (2015) Rapid determination of the pollen content in lake sediment cores as a tool in paleoenvironmental research. J Paleolimnol 54:161–170
Tianhong L, Wenkai L (2010) Variations in ecosystem service value in response to land use changes in Shenzhen. Ecol Econ 69:1427–1435
Tuchman NC, Larkin DJ, Geddes P, Wildova R, Jankowski K, Goldberg DE (2009) Patterns of environmental change associated with Typha x glauca invasion in a great lakes coastal wetland. Wetlands 29:964–975
UNESCO (2014) Ecological sciences for sustainable development. http://www.unesco.org/new/en/natural-sciences/environment/ecological-sciences/biosphere-reserves/europe-north-america/canada/thousand-islands-frontenac-arch/. Accessed 11 Aug 2014
Vaccaro LE, Bedford BL, Johnston CA (2009) Litter accumulation promotes dominance of invasive species of cattails (Typha spp.) in Lake Ontario wetlands. Wetlands 29:1036–1048
Van der Berg MS, Scheffer M, Van Nes E, Coops H (1999) Dynamics and stability of Chara sp. and Potamogeton pectinatus in a shallow lake changing in eutrophication level. In: Walz N, Nixdorf B (eds) Shallow lakes ’98: developments in hydrobiology, vol 143. Kluwer Academic Publishers, Dordrecht, pp 335–342
Vermaire JC, Prairie YT, Gregory-Eaves I (2012) Diatom-inferred decline of macrophyte abundance in lakes of southern Quebec, Canada. Can J Fish Aquat Sci 69:511–524
Werner KJ, Zedler JB (2002) How sedge meadow soils, microtopography, and vegetation respond to sedimentation. Wetlands 22:451–466
Zhao Y, Sayer CD, Birks HH, Hughes M, Peglar SM (2006) Spatial representation of aquatic vegetation by macrofossils and pollen in a small and shallow lake. J Paleolimnol 35:335–350
Żukowski W, Bogdanowicz AM, Lembicz M (2010) Seed germination in sedges: a short review. Biodivers Res Conserv 19:15–22
Acknowledgements
We would like to thank Sheldon Lambert and the staff of Parks Canada for their support with the fieldwork. Funding from Parks Canada and an NSERC Discovery Grant to JCV supported this project.
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Boxem, R., Davis, E.L. & Vermaire, J.C. Long-term environmental change and shifts in the aquatic plant community of Jones Creek, Thousand Islands National Park, Ontario, Canada based on plant macrofossil analysis. J Paleolimnol 60, 349–360 (2018). https://doi.org/10.1007/s10933-016-9938-7
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DOI: https://doi.org/10.1007/s10933-016-9938-7