Abstract
Numerous simulation studies have considered the effects of impending climate change on lakes. Predictive models exist for the responses of a multitude of variables to a warmer climate, and potential effects on food webs and ecosystem functions. Although these predictions are numerous, there is a need for manipulative experiments testing for the effects of warming on actual lake systems. We used power plant lakes across the central Midwestern US as a substitute for future climate change effects. These treatment lakes receive heated effluent and are typically 2–6 °C warmer than other regional lakes. We collected data from 1997 to 2010 on a number of abiotic and biotic variables from three of these treatment lakes and six control lakes that were of similar size and location but did not have an artificial thermal regime. Phosphorus and phytoplankton concentrations were similar between treatment groups, although treatment lakes had greater phosphorus and less phytoplankton in September. No differences existed in turbidity (measured as Secchi depth transparency). Zooplankton were less abundant in treatment lakes than in control lakes throughout our sampling period (May–October), with differences in cladocerans driving this disparity. There was evidence of earlier spawning of gizzard shad (Dorosoma cepedianum) due to the warmer temperature regime, but not for bluegill (Lepomis macrochirus). Average sizes of juvenile bluegill were larger in warmed systems in July and August. Juvenile largemouth bass (Micropterus salmoides) were larger in heated systems in June, but no differences existed in July or August. Growth of adult largemouth bass was greater in systems with a warmer thermal regime. Our results provide insights into patterns that can be expected in the future, and may be used to further understand the wide-reaching implications of climate change.
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References
Amirbahman A, Pearce AR, Bouchard RJ, Norton SA, Kahl JS (2003) Relationship between hypolimnetic phosphorus and iron release from eleven lakes in Maine, USA. Biogeochemistry 65:369–386
Beisner BE, Dent CL, Carpenter SR (2003) Variability of lakes on the landscape: roles of phosphorus, food webs, and dissolved organic carbon. Ecology 84(6):1563–1575
Bradshaw WE, Holzapfel CM (2008) Genetic response to rapid climate change: it’s seasonal timing that matters. Mol Ecol 17:157–166
Carlson DM (1973) Responses of planktonic cladocerans to heated waters. In: Gibbons JW, Sharitz RR (eds) Thermal ecology. Technical Information Center, Oak Ridge
Carpenter SR, Kitchell JF, Hodgson JR (1985) Cascading trophic interactions and lake productivity. Bioscience 35(10):634–639
Casselman JM, Brown DM, Hoyle JA, Eckert TH (2002) Effects of climate and global warming on year-class strength and relative abundance of smallmouth bass in eastern Lake Ontario. Am Fish Soc Symp 31:73–90
Claramunt RM, Shoup DE, Wahl DH (2005) Comparison of push nets and tow nets for sampling larval fish with implications for assessing littoral habitat utilization. N Am J Fish Manag 25:86–92
Coulter DP, Sepúlveda MS, Troy CD, Höök TO (2014) Thermal habitat quality of aquatic organisms near power plant discharges: potential exacerbating effects of climate warming. Fish Manag Ecol 21:196–210
Cox PM, Betts RA, Jones CD, Spall SA, Totterdell IJ (2000) Acceleration of global warming due to carbon-cycle feedbacks in a coupled climate model. Nature 408(9):184–187
DeStasio BT, Hill DK, Kleinhans JM, Nibbelink NP, Magnuson JJ (1996) Potential effects of global climate change on small north-temperate lakes: physics, fish, and plankton. Limnol Oceanogr 41:1136–1149
Dupuis AP, Hann BJ (2009) Climate change, diapauses termination and zooplankton population dynamics: an experimental and modeling approach. Freshw Biol 54:221–235
Ekvall MK, Hansson LA (2012) Differences in recruitment and life-history strategy alter zooplankton spring dynamics under climate-change conditions. PLoS One 7(9):e44614
Feuchtmayr H, Moran R, Hatton K, Connor L, Heyes T, Moss B, Harvey I, Atkinson D (2009) Global warming and eutrophication: effects on water chemistry and autotrophic communities in experimental hypertrophic shallow lake mesocosms. J Appl Ecol 46:713–723
Ficke AD, Myrick CA, Hansen LJ (2007) Potential impacts of global climate change on freshwater fisheries. Rev Fish Biol Fish 17:581–613
Galloway ML, Kilambi RV (1988) Thermal enrichment of a reservoir and the effects on annulus formation and growth of largemouth bass, Micropterus salmoides. J Fish Biol 32(533):543
Gallucci VF, Quinn TJ II (1979) Reparameterizing, fitting, and testing a simple growth model. Trans Am Fish Soc 108:14–25
George DG, Harris GP (1985) The effect of climate on long-term changes in the crustacean zooplankton biomass of Lake Windermere, U.K. Nature 316:536–539
Hader DP, Worrest RC, Kumar HD, Smith RC (1995) Effects of increased solar ultraviolet-radiation on aquatic ecosystems. Ambio 24(3):174–180
Harrington R, Woiwod I, Sparks T (1999) Climate change and trophic interactions. Trends Ecol Evol 14:146–150
Hondzo M, Stefan HG (1993) Regional water characteristics of lakes subjected to climate change. Clim Change 24:187–211
IPCC (2007) Summary for policymakers. In: Climate Change 2007: the physical science basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change [Solomon S, Qin D, Manning M, Chen Z, Marquis M, Averyt KB, Tignor M, Miller HL (eds)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA
Jacobson PC, Jones TS, Rivers P, Pereira DL (2008) Field estimation of a lethal oxythermal niche boundary for adult ciscoes in Minnesota Lakes. Trans Am Fish Soc 137:1464–1474
Jensen HS, Kristensen P, Jeppesen E, Skytthe A (1992) Iron:phosphorus ratio in surface sediment as an indicator of phosphate release from aerobic sediments in shallow lakes. Hydrobiolgia 235(236):731–743
Jeppesen E, Sondergaard M, Jensen JP (2003) Climatic warming and regime shifts in lake food webs: some comments. Limnol Oceanogr 48(3):1346–1349
Johnk KD, Huisman J, Sharples JP, Sommeijer B, Visser PM, Stroom JM (2008) Summer heatwaves promote blooms of harmful cyanobacteria. Glob Change Biol 14:495–512
Jolley JC, Edwards KR, Willis DW (2009) Bluegill (Lepomis macrochirus) spawning periodicity and hatching duration in the northern Great Plains, USA. J Freshw Ecol 24:29–37
King JR, Shuter BJ, Zimmerman AP (1999) Empirical links between thermal habitat, fish growth, and climate change. Trans Am Fish Soc 128(4):656–665
Leeper DA, Taylor BE (1995) Plankton composition, abundance and dynamics in a severely stressed cooling reservoir. J Plankton Res 17(4):821–843
Magnuson JJ, Webster KE, Assel RA, Bowser CJ, Dillon PJ, Eaton JG, Evans HE, Fee EJ, Hall RI, Mortsch LR, Schindler DW, Quinn FH (1997) Potential effects of climate changes on aquatic systems: laurentian Great Lakes and Precambrian Shield region. Hydrol Process 11:825–871
Markensten H, Moore K, Persson I (2010) Simulated lake phytoplankton composition shifts towards cyanobacteria dominance in a future warmer climate. Ecol Appl 20:752–767
McKee D, Atkinson D, Collings SE, Eaton JW, Gill AB, Harvey I, Hatton K, Heyes T, Wilson D, Moss B (2003) Response of freshwater microcosm communities to nutrients, fish, and elevated temperature during winter and summer. Limnol Oceanogr 48:707–722
Metzke BA, Pederson CL (2012) Cladoceran community dynamics reflect temperature gradients in a cooling water reservoir. Am Midl Nat 167:344–355
Meyer JL, Sale MJ, Mulholland PJ, Poff NL (1999) Impacts of climate change on aquatic ecosystem functioning and health. J Am Water Resour Assoc 35:1373–1386
Mooij WM, Hulsmann S, De Senerpont Domis LN, Nolet BA, Bodelier PLE, Boers PCM, Dionisio Pires LM, Gons HJ, Ibelings BW, Noordhuis R, Portielje R, Wolfstein K, Lammens EHRR (2005) The impact of climate change on lakes in the Netherlands: a review. Aquat Ecol 39:381–400
Mooij WM, Domis LND, Hulsmann S (2008) The impact of climate warming on water temperature, timing of hatching and young-of-the-year growth of fish in shallow lakes in the Netherlands. J Sea Res 60:32–43
Moore MV, Folt CL, Stemberger RS (1996) Consequences of elevated temperatures for zooplankton assemblages in temperate lakes. Arch Hydrobiol 135(3):289–319
Moore MV, Pace ML, Mather JR, Murdoch PS, Howarth RW, Folt CL, Chen CY, Hemond HF, Flebbe PA, Driscoll CT (1997) Potential effects of climate change on freshwater ecosystems of the New England/Mid-Atlantic region. Hydrol Process 11:925–947
Morrongiello JR, Crook DA, King AJ, Ramsey DSL, Brown P (2011) Impacts of drought and predicted effects of climate change on fish growth in temperate Australian lakes. Glob Change Biol 17:745–755
Murphy BR, Willis DW (eds) (1996) Fisheries techniques, 2nd ed. American Fisheries Society, Bethesda, Maryland
Nicolle A, Hallgren P, von Einem J, Bronmark C, Hannson LA (2012) Predicted warming and browning affect timing and magnitude of plankton phonological events in lakes: a mesocosm study. Freshw Biol 57(4):684–695
Pascual DL, Johengen TH, Filippelli GM, Tedesco LP, Moran D (2008) Cultural eutrophication of three midwest urban reservoirs: the role of nitrogen limitation in determining phytoplankton community structure. Adv Exp Med Biol 619:307
Rice JA, Breck JE, Bartell SM, Kitchell JF (1983) Evaluating the constraints of temperature, activity and consumption on growth of largemouth bass. Environ Biol Fish 9:263–275
Robarts RD, Zohary T (1987) Temperature effects on photosynthetic capacity, respiration, and growth rates of bloom-forming cyanobacteria. NZ J Mar Freshw Res 21:391–399
Roessig JM, Woodley CM, Cech JJ, Hansen LJ (2004) Effects of global climate change on marine and estuarine fishes and fisheries. Rev Fish Biol Fish 14:251–275
Rogers MW, Allen MS (2009) Exploring the generality of recruitment hypotheses for largemouth bass along a latitudinal gradient of Florida lakes. Trans Am Fish Soc 138:23–37
Rooney N, Kalff J (2000) Inter-annual variation in submerged macrophyte community biomass and distribution: the influence of temperature and lake morphometry. Aquat Bot 68:321–335
Rypel AL (2009) Climate-growth relationships for largemouth bass (Micropterus salmoides) across three southeastern USA states. Ecol Freshw Fish 18(4):620–628
Scheffer M, van Nes EH (2007) Shallow lakes theory revisited: various alternative regimes driven by climate, nutrients, depth and lake size. Hydrobiologia 584:455–466
Schindler DE, Rogers DE, Scheuerell MD, Abrey CA (2005) Effects of changing climate on zooplankton and juvenile sockeye salmon growth in southwestern Alaska. Ecology 86(1):198–209
Shuter BJ, Wismer DA, Regier HA, Matuszek JE (1985) An application of ecological modelling: impact of thermal effluent on a smallmouth bass population. Trans Am Fish Soc 114:631–651
Smith LM, Whitehouse S, Oviatt CA (2010) Impacts of climate change on Narragansett Bay. Northeas Nat 17:77–90
Sondergaard M, Jensen JP, Jeppesen E (2003) Role of sediment and internal loading of phosphorus in shallow lakes. Hydrobiologia 506–509:135–145
Stauffer RE (1985) Nutrient internal cycling and the trophic regulation of Green Lake, Wisconsin. Limnol Oceanogr 30:347–363
Stefan HG, Fang X, Eaton JG (2001) Simulated fish habitat changes in North American lakes in response to projected climate warming. Trans Am Fish Soc 130(3):459–477
Straile D (2002) North Atlantic Oscillation synchronizes food-web interactions in central European lakes. Proc R Soc Edinb Sect B Biol Sci 269:391–395
Taylor BE, Debiase AE, Mahoney DL (1993) Development of the zooplankton assemblage in a new cooling reservoir. Arch Hydrobiol 128(2):129–148
Threlkeld ST (1979) The midsummer dynamics of two Daphnia species in Wintergreen Lake, Michigan. Ecology 60:165–179
Welschmeyer NA, Naughton SL (1994) Improved chlorophyll a analysis: single fluorometric measurement with no acidification. Lake Reserv Manag 9:123
Weyhenmeyer GA (2001) Warmer winters: are planktonic algal populations in Sweden’s largest lakes affected? Ambio 30(8):565–571
Wilde EW (1983) Phytoplankton distribution in three thermally distinct reactor cooling reservoirs. Trans Am Fish Soc 102(2):145–164
Williams JE, Haak AL, Neville HM, Colyer WT (2009) Potential consequences of climate change to persistence of cutthroat trout populations. N Am J Fish Manag 29(3):533–548
Winder M, Schindler DE (2004) Climatic effects on the phenology of lake processes. Glob Change Biol 10:1844–1856
Yvon-Durocher G, Montoya JM, Trimmer M, Woodward G (2011) Warming alters the size spectrum and shifts the distribution of biomass in freshwater ecosystems. Glob Change Biol 17(4):1681–1694
Acknowledgments
Funding for this project was provided in part by Federal Aid in Sport Fish Restoration Project F-135-R administered through the Illinois Department of Natural Resources (IDNR) Division of Fisheries. We would like to thank D. Austin, D. Bruce, S. Pallo, J. Ferencak, and J. Mick for coordinating activities with the Division of Fisheries, IDNR. We thank R. Heidinger, R. Brooks, and A. Porreca for assistance in data acquisition on Newton and Coffeen Lakes. We thank Matt Diana and the staff of the Kaskaskia and Sam Parr Biological Stations, and the Illinois Natural History Survey for collecting and maintaining the long-term data used for the study.
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Mulhollem, J.J., Colombo, R.E. & Wahl, D.H. Effects of heated effluent on Midwestern US lakes: implications for future climate change. Aquat Sci 78, 743–753 (2016). https://doi.org/10.1007/s00027-016-0466-3
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DOI: https://doi.org/10.1007/s00027-016-0466-3