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Predicting algal bloom dynamics in a changing climate Predicting algal bloom dynamics in a changing climate R.J. Sorichetti, S. Sharma, A.M. Paterson, J.A. Rusak, H. Yao York University and Ontario Ministry of the Environment and Climate Change [email protected] R.J. Sorichetti, S. Sharma, A.M. Paterson, J.A. Rusak, H. Yao York University and Ontario Ministry of the Environment and Climate Change [email protected] Benthic Algae Attached Pelagic Phytoplankton Free-Floating Chrysophytes fmp.conncoll.edu Cyanobacteria Diatoms www.micromagus.net Chlorophytes www.rolfsbild.se microbewiki.kenyon.edu protist.i.hosei.ac.jp Cryptophytes Dinoflagellates tolweb.org www.biologycorner.com Euglena www.lakesuperiorstreams.org www.studyblue.com Aquatic Ecosystem Trophic Food Web www.alchemistclub.wikispaces.com Increased occurrence of algal blooms • Previous: large basins, eutrophic systems (Downing et al., 2001) • Recent: small basins, oligotrophic systems (Carey et al., 2008) • Increased occurrence over last decade in: o Laurentian Great Lakes Basin (Brittain et al., 2000; Molot et al., 2010; Watson et al., 2004; Winter et al., 2011) o Globally (Berger et al., 2008; Figueredo et al., 2007) No longer strictly associated with eutrophication Gordon Campbell, Dean Lake Concerned citizen, Twin Lakes Ecosystem health implications • Bloom forming o Cyanotoxins, noxious (T&O) compounds • Microcystin (MC), anatoxin, saxitoxin, nodularin, 2-MIB, geosmin • Laurentian Great Lakes Basin o Microcystis spp. MC (Hotto et al., 2007) Gordon Campbell, Dean Lake Chemical determinants of algae • Phosphorus Schindler, Downing • Nitrogen Paerl, Bergström, Herrero • N:P Smith, Havens • Iron (Fe) Trick, Molot, Wilhelm o Photosynthesis, Chl-α synthesis, N-fixation o Organic ligands (catecholate and hydroxamate) Climate is changing Increasing blooms in Ontario No. algal bloom reports 50 other golden-brown algae green algae 40 blue-green algae 30 20 10 0 1994 1996 1998 2000 2002 2004 2006 2008 2010 2012 2014 (Winter et al., 2011; Updated by OMOECC Algae Laboratory, Toronto, Canada) Blooms increases in all parts of the Province (Winter et al., 2011; Updated by OMOECC Algae Laboratory, Toronto, Canada) Blooms occurring later in the year December 320 300 280 260 240 220 2012 2010 2008 2006 2004 2002 2000 1998 1996 200 1994 Last day of the year blooms reported 340 (Winter et al., 2011; Updated by OMOECC Algae Laboratory, Toronto, Canada) Active community involvement 10 Revisit climate – algal dynamics relationship Common questions asked in 20th and 21st century: • • • • • • Where do we see blooms and why? Can we identify lakes with highest bloom risk? Which algal groups bloom where? Why do algae produce bioactive compounds? What are the human and ecosystem health implications? Can blooming lakes be remediated or recovered? Will answers to these questions support new effective legislation? Framing a context for algal blooms in lakes • Linkages between algal blooms and climate change • Lake physical and chemical attributes – not one size fits all! Climate Need for a lake typology Physical basis for investigation Physical Structure • • • • Chemical Structure • • • Nutrients Oxygen Trophic status Temperature Thermocline Wind patterns Mixing regime Biological Structure • • • Algae Fish Microbial loop A lake typology from first principles Phytoplankton Group Vertical Distribution Common Bloom Season Diatoms Epilimnion – Metalimnion (cool, dense) Spring and fall mixis Chrysophytes Epilimnion – Metalimnion (some motile) End of spring, early summer Cyanobacteria Epilimnion – Metalimnion (some motile) End of summer Greens Epilimnion (some motile) Early summer Browns Epilimnion – Metalimnion (some motile) End of spring, early summer Lake Type Greatest Response to Climate Change Response Season(s) Deep Stratified Later fall mixis, higher internal loading Fall Shallow Non-Stratified Increased lake water temperatures Summer High DOC Reduced/warmer epilimnion, cooler at depths Summer Low DOC Increased lake water temperatures and stability Summer and Fall How will lake typology help identify the lakes most at-risk from the effects of climate change on algal dynamics? York University and OMOECC partnership Dr. Sapna Sharma Dr. Andrew Paterson York U OMOECC Dr. Jim Rusak OMOECC Dr. Huaxia Yao OMOECC Thomas Van Zuiden York U Research Questions: 1. What are the linkages between algal blooms and climate change? 2. Which lakes are at highest risk for algal blooms under climate change scenarios? Modeling algal dynamics in a changing climate • LTER site data across Ontario (ELA, Algoma, Muskoka, Algonquin) • Lake physical parameters, water chemistry, biology (algal group biomass), meteorological and climate data • Identify lake characteristics at highest risk of algal blooms • Predict future algal dynamics in lakes in 2050 and 2070 under 126 scenarios of climate change: Present 2050 2070 (Van Zuiden et al., 2016) DESC inland waters monitoring program 9 lakes (monthly to bi-weekly) 1981-present 25 streams (weekly; 14 gauged) 4 climate stations (automatic, real-time) 2 lake buoys (automatic, real-time) climate station lake buoy Algal trends in Dorset A lakes Year 2012 2009 2006 2003 2000 1997 1994 1991 1988 1985 1982 2.5 2.0 1.5 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 1979 1981-2013 = No change 1981-1999 = Increasing biomass 2000-2013 = Decreasing biomass Relative Biomass (z-scores) Plastic Lake Dinoflagellate Biomass Group-level changes in relative biomass 1981-1999 2000-2013 Increasing chrysophytes Decreasing diatoms Decreasing chrysophytes Increasing diatoms Warmer and longer Ontario summers in 2070 20 Mean summer temp increase Later ice-on Earlier ice-off Earlier stratification onset Later fall mixis 15 Temperature (C) 25 • • • • • 1950−2000 temp RCP 2.6 RCP 4.5 RCP 6.0 RCP 8.5 Climate Change Scenar io (S. Sharma Unpubl. Data, 2016) (Crossman et al., 2016) Climate change has affected thermal properties of Dorset lakes Lake warming driven by increased autumn air temperature Decreasing mixing depths (climate-driven increases in lake DOC) Delayed autumn mixing Synchronous changes among lakes points to regional driver (climate?) How has changing lake physics influenced algal dynamics? Summary • Climate and algal dynamics are changing • Climate lake physical structure (temperature/mixing) lake chemistry and biology • Must first understand how climate affects lake physics and in turn, biology (algal dynamics) • Understanding effects of climate change = national water strategy Thank you!