Your search keyword '"Ozersky, T."' showing total 16 results

1. Recent changes in the spring microplankton of Lake Baikal, Russia

Author

Bondarenko, N.A., Ozersky, T., Obolkina, L.A., Tikhonova, I.V., Sorokovikova, E.G., Sakirko, M.V., Potapov, S.A., Blinov, V.V., Zhdanov, A.A., and Belykh, O.I.

Published

2019

2. The Lake Ice Continuum Concept: Influence of Winter Conditions on Energy and Ecosystem Dynamics

Author

Cavaliere, E., primary, Fournier, I. B., additional, Hazuková, V., additional, Rue, G. P., additional, Sadro, S., additional, Berger, S. A., additional, Cotner, J. B., additional, Dugan, H. A., additional, Hampton, S. E., additional, Lottig, N. R., additional, McMeans, B. C., additional, Ozersky, T., additional, Powers, S. M., additional, Rautio, M., additional, and O'Reilly, C. M., additional

Published

2021

3. Taxonomic and functional differences between winter and summer crustacean zooplankton communities in lakes across a trophic gradient

Author

Shchapov, K, primary, Wilburn, P, additional, Bramburger, A J, additional, Silsbe, G M, additional, Olmanson, L, additional, Crawford, C J, additional, Litchman, E, additional, and Ozersky, T, additional

Published

2021

4. Heating up a cold subject: prospects for under-ice plankton research in lakes

Author

Hampton, S. E., primary, Moore, M. V., additional, Ozersky, T., additional, Stanley, E. H., additional, Polashenski, C. M., additional, and Galloway, A. W. E., additional

Published

2015

5. The state of Lake Simcoe (Ontario, Canada) : the effects of multiple stressors on phosphorus and oxygen dynamics

Author

North, R. L., Barton, D., Crowe, A. S., Dillon, P. J., Dolson, R. M. L., Evans, D. O., Ginn, B. K., Håkanson, Lars, Hawryshyn, J., Jarjanazi, H., King, J. W., La Rose, J. K. L., Leon, L., Lewis, C. F. M., Liddle, G. E., Lin, Z. H., Longstaffe, F. J., Macdonald, R. A., Molot, L., Ozersky, T., Palmer, M. E., Quinlan, R., Rennie, M. D., Robillard, M. M., Rode, D., Rühland, K. M., Schwalb, A., Smol, J. P., Stainsby, E., Trumpickas, J. J., Winter, J. G., Young, J. D., North, R. L., Barton, D., Crowe, A. S., Dillon, P. J., Dolson, R. M. L., Evans, D. O., Ginn, B. K., Håkanson, Lars, Hawryshyn, J., Jarjanazi, H., King, J. W., La Rose, J. K. L., Leon, L., Lewis, C. F. M., Liddle, G. E., Lin, Z. H., Longstaffe, F. J., Macdonald, R. A., Molot, L., Ozersky, T., Palmer, M. E., Quinlan, R., Rennie, M. D., Robillard, M. M., Rode, D., Rühland, K. M., Schwalb, A., Smol, J. P., Stainsby, E., Trumpickas, J. J., Winter, J. G., and Young, J. D.

Abstract

Lake Simcoe, the largest lake in southern Ontario outside of the Laurentian Great Lakes, is affected by numerous stressors including eutrophication resulting from total phosphorus (TP) loading, climate change, and invasions of exotic species. We synthesized the long-term responses of Lake Simcoe to these stressors by assessing trends in water quality and biological composition over multiple trophic levels. Evidence for climate change included increasing thermal stability of the lake and changes in subfossil diatom communities over time. Although the deep water dissolved oxygen (O-2) minimum has increased significantly since TP load reductions, it is still below estimated historical values and the Lake Simcoe Protection Plan end-of-summer target level of 7 mg O-2 L-1. Low deep water O-2 concentrations corresponded with a decline in coldwater fish abundance. Since 1980, some nutrient concentrations have decreased (spring TP) while others have increased (silica), but many show no obvious changes (ice-free TP, nitrate, ammonium). Increases in water clarity, combined with declines in chlorophyll a and phytoplankton biovolumes in Cook's Bay, were temporally consistent with declines in TP loading and the lake-wide establishment of dreissenid mussels as a major component of the Lake Simcoe ecosystem. Using an investigative tool, we identified 2 periods when abrupt shifts potentially occurred in multiple parameters: 1986 and 1995-1997. Additional ecosystem level changes such as declines in zooplankton, declines in offshore benthic invertebrate abundance, and increased nearshore invertebrate abundance likely reflect the effects of invasive species. The interaction of these multiple stressors have significantly altered the Lake Simcoe ecosystem.

Published

2013

6. Nearshore–offshore differences in planktonic chlorophyll and phytoplankton nutrient status after dreissenid establishment in a large shallow lake

Author

Guildford, S. J., Depew, D. C., Ozersky, T., Hecky, R. E., and Smith, R. E. H.

Abstract

AbstractIn Lake Simcoe, a large lake in southern Ontario, Canada, with more than 50% of its surface area <15 m deep, dreissenid mussels are abundant in the extensive nearshore zone but not offshore. We hypothesized that mussel grazing would depress chlorophyll a(Chl-a) concentrations in the nearshore compared to the offshore while alleviating nearshore phosphorus (P) deficiency through nutrient regeneration. During both years of our study Chl-aconcentration and other indicators of phytoplankton biomass, including particulate carbon (C), nitrogen, P, and silicon, were lower in the nearshore areas of Lake Simcoe where the exotic invader Dreissenia polymorphawas in contact with overlying epilimnetic water. In the first year of our study, grazing and associated nutrient regeneration activity seemed to reduce P deficiency in phytoplankton in the dreissenid-impacted shallow locations. In the second year, however, phytoplankton in the nearshore dreissenid-affected areas remained as strongly P deficient as phytoplankton in offshore waters physically separated from dreissenid grazing. Photoacclimation in the nearshore phytoplankton was evident in higher particulate C:Chl-aratios and higher effective absorptive cross section of photosystem II (σPS II)throughout the stratified sampling season compared to offshore phytoplankton. A multiple linear regression utilizing the mean light intensity in the mixed layer as well as total P (TP) resulted in better predictions of Chl-athan TP alone. We conclude that, in shallow lakes where transparency is strongly impacted by dreissenid grazing, the comparison of Chl-a–TP relationships over time will require accounting for the effect of changing transparency.

Published

2013

7. The state of Lake Simcoe (Ontario, Canada): the effects of multiple stressors on phosphorus and oxygen dynamics

Author

North, R.L., Barton, D., Crowe, A.S., Dillon, P.J., Dolson, R.M.L., Evans, D.O., Ginn, B.K., Håkanson, L., Hawryshyn, J., Jarjanazi, H., King, J.W., La Rose, J.K.L, León, L., Lewis, C.F.M., Liddle, G.E., Lin, Z.H., Longstaffe, F.J, Macdonald, R.A., Molot, L., Ozersky, T., Palmer, M.E., Quinlan, R., Rennie, M.D., Robillard, M.M., Rodé, D., Rühland, K.M., Schwalb, A., Smol, J.P., Stainsby, E., Trumpickas, J.J., Winter, J.G., and Young, J.D.

Abstract

AbstractLake Simcoe, the largest lake in southern Ontario outside of the Laurentian Great Lakes, is affected by numerous stressors including eutrophication resulting from total phosphorus (TP) loading, climate change, and invasions of exotic species. We synthesized the long-term responses of Lake Simcoe to these stressors by assessing trends in water quality and biological composition over multiple trophic levels. Evidence for climate change included increasing thermal stability of the lake and changes in subfossil diatom communities over time. Although the deep water dissolved oxygen (O2) minimum has increased significantly since TP load reductions, it is still below estimated historical values and the Lake Simcoe Protection Plan end-of-summer target level of 7 mg O2L-1. Low deep water O2 concentrations corresponded with a decline in coldwater fish abundance. Since 1980, some nutrient concentrations have decreased (spring TP) while others have increased (silica), but many show no obvious changes (ice-free TP, nitrate, ammonium). Increases in water clarity, combined with declines in chlorophyll a and phytoplankton biovolumes in Cook’s Bay, were temporally consistent with declines in TP loading and the lake-wide establishment of dreissenid mussels as a major component of the Lake Simcoe ecosystem. Using an investigative tool, we identified 2 periods when abrupt shifts potentially occurred in multiple parameters: 1986 and 1995-1997. Additional ecosystem level changes such as declines in zooplankton, declines in offshore benthic invertebrate abundance, and increased nearshore invertebrate abundance likely reflect the effects of invasive species. The interaction of these multiple stressors have significantly altered the Lake Simcoe ecosystem.

Published

2013

8. Environmental and societal consequences of winter ice loss from lakes.

Author

Hampton SE, Powers SM, Dugan HA, Knoll LB, McMeans BC, Meyer MF, O'Reilly CM, Ozersky T, Sharma S, Barrett DC, Chandra S, Jansen J, McClure RP, Rautio M, Weyhenmeyer GA, and Yang X

Subjects

Biodiversity, Food Chain, Humans, Fisheries, Animals, Water Quality, Greenhouse Gases, Ice, Lakes, Seasons, Climate Change, Ice Cover

Abstract

Climate change is reducing winter ice cover on lakes; yet, the full societal and environmental consequences of this ice loss are poorly understood. The socioeconomic implications of declining ice include diminished access to ice-based cultural activities, safety concerns in traversing ice, changes in fisheries, increases in shoreline erosion, and declines in water storage. Longer ice-free seasons allow more time and capacity for water to warm, threatening water quality and biodiversity. Food webs likely will reorganize, with constrained availability of ice-associated and cold-water niches, and ice loss will affect the nature, magnitude, and timing of greenhouse gas emissions. Examining these rapidly emerging changes will generate more-complete models of lake dynamics, and transdisciplinary collaborations will facilitate translation to effective management and sustainability.

Published

2024

9. Blue Waters, Green Bottoms: Benthic Filamentous Algal Blooms Are an Emerging Threat to Clear Lakes Worldwide.

Author

Vadeboncoeur Y, Moore MV, Stewart SD, Chandra S, Atkins KS, Baron JS, Bouma-Gregson K, Brothers S, Francoeur SN, Genzoli L, Higgins SN, Hilt S, Katona LR, Kelly D, Oleksy IA, Ozersky T, Power ME, Roberts D, Smits AP, Timoshkin O, Tromboni F, Zanden MJV, Volkova EA, Waters S, Wood SA, and Yamamuro M

Abstract

Nearshore (littoral) habitats of clear lakes with high water quality are increasingly experiencing unexplained proliferations of filamentous algae that grow on submerged surfaces. These filamentous algal blooms (FABs) are sometimes associated with nutrient pollution in groundwater, but complex changes in climate, nutrient transport, lake hydrodynamics, and food web structure may also facilitate this emerging threat to clear lakes. A coordinated effort among members of the public, managers, and scientists is needed to document the occurrence of FABs, to standardize methods for measuring their severity, to adapt existing data collection networks to include nearshore habitats, and to mitigate and reverse this profound structural change in lake ecosystems. Current models of lake eutrophication do not explain this littoral greening. However, a cohesive response to it is essential for protecting some of the world's most valued lakes and the flora, fauna, and ecosystem services they sustain., (© The Author(s) 2021. Published by Oxford University Press on behalf of the American Institute of Biological Sciences.)

Published

2021

10. Benthic invaders control the phosphorus cycle in the world's largest freshwater ecosystem.

Author

Li J, Ianaiev V, Huff A, Zalusky J, Ozersky T, and Katsev S

Subjects

Animals, Bivalvia metabolism, Environmental Monitoring, Models, Biological, Time Factors, Ecosystem, Fresh Water, Introduced Species, Phosphorus metabolism

Abstract

The productivity of aquatic ecosystems depends on the supply of limiting nutrients. The invasion of the Laurentian Great Lakes, the world's largest freshwater ecosystem, by dreissenid (zebra and quagga) mussels has dramatically altered the ecology of these lakes. A key open question is how dreissenids affect the cycling of phosphorus (P), the nutrient that limits productivity in the Great Lakes. We show that a single species, the quagga mussel, is now the primary regulator of P cycling in the lower four Great Lakes. By virtue of their enormous biomass, quagga mussels sequester large quantities of P in their tissues and dramatically intensify benthic P exchanges. Mass balance analysis reveals a previously unrecognized sensitivity of the Great Lakes ecosystem, where P availability is now regulated by the dynamics of mussel populations while the role of the external inputs of phosphorus is suppressed. Our results show that a single invasive species can have dramatic consequences for geochemical cycles even in the world's largest aquatic ecosystems. The ongoing spread of dreissenids across a multitude of lakes in North America and Europe is likely to affect carbon and nutrient cycling in these systems for many decades, with important implications for water quality management., Competing Interests: The authors declare no competing interest.

Published

2021

11. Past and present mercury accumulation in the Lake Baikal seal: Temporal trends, effects of life history, and toxicological implications.

Author

Poste AE, Pastukhov MV, Braaten HFV, Ozersky T, and Moore M

Subjects

Animals, Biota, Carbon Isotopes analysis, Diet, Female, Linear Models, Nitrogen Isotopes analysis, Russia, Time Factors, Tissue Distribution, Tooth metabolism, Water Pollutants, Chemical analysis, Environmental Monitoring, Lakes, Mercury analysis, Mercury toxicity, Seals, Earless metabolism

Abstract

Despite global efforts to reduce anthropogenic mercury (Hg) emissions, the timescale and degree to which Hg concentrations in the environment and biota respond to decreased emissions remain challenging to assess or predict. In the present study we characterize long-term trends and life-history patterns in Hg accumulation and toxicological implications of Hg contamination for a freshwater seal from one of the world's largest lakes (Lake Baikal, Siberia, Russia) using contemporary tissues and archival teeth. Stable isotope analysis and Hg analyses of soft tissues (muscle, liver, kidney, blood, brain, heart) and teeth from 22 contemporary seals revealed rapid changes in diet and Hg accumulation in the first year of life with a stable diet and increase in tissue Hg throughout the rest of life. Although maternal transfer of Hg was an important source of Hg to seal pups, reproduction and lactation by female seals did not appear to result in sex-related differences in Hg concentrations or age-related accumulation in adult seals. Based on Hg analysis of archival teeth (n = 114) and reconstructed values for soft tissues, we also assessed temporal trends in seal Hg between the years 1960 and 2013. Seal Hg concentrations in hard (teeth) and soft (e.g., muscle, liver) tissues were highest in the 1960s and 1970s, followed by a decrease. The decline in seal Hg concentrations in recent decades was most likely driven by a reduction in Hg inputs to the lake, suggesting that global and regional efforts to reduce Hg emissions have been successful at reducing ecosystem and human health risks posed by Hg in Lake Baikal. Environ Toxicol Chem 2018;37:1476-1486. © 2018 SETAC., (© 2018 SETAC.)

Published

2018

12. Long-Term and Ontogenetic Patterns of Heavy Metal Contamination in Lake Baikal Seals (Pusa sibirica).

Author

Ozersky T, Pastukhov MV, Poste AE, Deng XY, and Moore MV

Subjects

Animals, Environmental Pollutants, Europe, Lakes, Reproduction, Russia, Time Factors, Tissue Distribution, Metals, Heavy, Seals, Earless

Abstract

Little is known about the history of heavy metal pollution of Russia's Lake Baikal, one of the world's largest lakes and a home to numerous endemic species, including the Baikal Seal, Pusa sibirica. We investigated the history of heavy metal (V, Cu, Zn, Cd, Hg, Tl, Pb, U) pollution in Lake Baikal seals over the past 8 decades. C and N stable isotope analysis (SIA) and laser-ablation ICP-MS of seal teeth were used to examine changes in feeding ecology, heavy metal levels associated with life history events and long-term variation in metal exposure. SIA did not suggest large changes in the feeding ecology of Baikal seals over the past 80 years. LA-ICP-MS analyses revealed element-specific ontogenetic variability in metal concentrations, likely related to maternal transfer, changes in food sources and starvation. Hg and Cd levels in seals varied significantly across the time series, with concentrations peaking in the 1960s - 1970s but then declining to contemporary levels similar to those observed in the 1930s and 1940s. Trends in atmospheric emissions of Hg suggest that local sources as well as emissions from eastern Russia and Europe may be important contributors of Hg to Lake Baikal and that, despite the size of Lake Baikal, its food web appears to respond rapidly to changing inputs of contaminants.

Published

2017

13. Ecology under lake ice.

Author

Hampton SE, Galloway AW, Powers SM, Ozersky T, Woo KH, Batt RD, Labou SG, O'Reilly CM, Sharma S, Lottig NR, Stanley EH, North RL, Stockwell JD, Adrian R, Weyhenmeyer GA, Arvola L, Baulch HM, Bertani I, Bowman LL Jr, Carey CC, Catalan J, Colom-Montero W, Domine LM, Felip M, Granados I, Gries C, Grossart HP, Haberman J, Haldna M, Hayden B, Higgins SN, Jolley JC, Kahilainen KK, Kaup E, Kehoe MJ, MacIntyre S, Mackay AW, Mariash HL, McKay RM, Nixdorf B, Nõges P, Nõges T, Palmer M, Pierson DC, Post DM, Pruett MJ, Rautio M, Read JS, Roberts SL, Rücker J, Sadro S, Silow EA, Smith DE, Sterner RW, Swann GE, Timofeyev MA, Toro M, Twiss MR, Vogt RJ, Watson SB, Whiteford EJ, and Xenopoulos MA

Subjects

Seasons, Ecosystem, Ice Cover, Lakes, Plankton physiology

Abstract

Winter conditions are rapidly changing in temperate ecosystems, particularly for those that experience periods of snow and ice cover. Relatively little is known of winter ecology in these systems, due to a historical research focus on summer 'growing seasons'. We executed the first global quantitative synthesis on under-ice lake ecology, including 36 abiotic and biotic variables from 42 research groups and 101 lakes, examining seasonal differences and connections as well as how seasonal differences vary with geophysical factors. Plankton were more abundant under ice than expected; mean winter values were 43.2% of summer values for chlorophyll a, 15.8% of summer phytoplankton biovolume and 25.3% of summer zooplankton density. Dissolved nitrogen concentrations were typically higher during winter, and these differences were exaggerated in smaller lakes. Lake size also influenced winter-summer patterns for dissolved organic carbon (DOC), with higher winter DOC in smaller lakes. At coarse levels of taxonomic aggregation, phytoplankton and zooplankton community composition showed few systematic differences between seasons, although literature suggests that seasonal differences are frequently lake-specific, species-specific, or occur at the level of functional group. Within the subset of lakes that had longer time series, winter influenced the subsequent summer for some nutrient variables and zooplankton biomass., (© 2016 The Authors. Ecology Letters published by CNRS and John Wiley & Sons Ltd.)

Published

2017

14. The rise and fall of plankton: long-term changes in the vertical distribution of algae and grazers in Lake Baikal, Siberia.

Author

Hampton SE, Gray DK, Izmest'eva LR, Moore MV, and Ozersky T

Subjects

Animals, Ecosystem, Fresh Water, Lakes, Seasons, Siberia, Temperature, Phytoplankton physiology, Zooplankton physiology

Abstract

Both surface water temperatures and the intensity of thermal stratification have increased recently in large lakes throughout the world. Such physical changes can be accompanied by shifts in plankton community structure, including changes in relative abundances and depth distributions. Here we analyzed 45 years of data from Lake Baikal, the world's oldest, deepest, and most voluminous lake, to assess long-term trends in the depth distribution of pelagic phytoplankton and zooplankton. Surface water temperatures in Lake Baikal increased steadily between 1955 and 2000, resulting in a stronger thermal gradient within the top 50 m of the water column. In conjunction with these physical changes our analyses reveal significant shifts in the daytime depth distribution of important phytoplankton and zooplankton groups. The relatively heavy diatoms, which often rely on mixing to remain suspended in the photic zone, shifted downward in the water column by 1.90 m y(-1), while the depths of other phytoplankton groups did not change significantly. Over the same time span the density-weighted average depth of most major zooplankton groups, including cladocerans, rotifers, and immature copepods, exhibited rapid shifts toward shallower positions (0.57-0.75 m y(-1)). As a result of these depth changes the vertical overlap between herbivorous copepods (Epischura baikalensis) and their algal food appears to have increased through time while that for cladocerans decreased. We hypothesize that warming surface waters and reduced mixing caused these ecological changes. Future studies should examine how changes in the vertical distribution of plankton might impact energy flow in this lake and others.

Published

2014

15. Invasive dreissenid mussels and round gobies: a benthic pathway for the trophic transfer of microcystin.

Author

Poste AE and Ozersky T

Subjects

Animals, Bivalvia metabolism, Food Chain, Microcystins metabolism, Perciformes metabolism

Abstract

In the present preliminary study, the authors identify 2 pathways through which invasive dreissenid mussels can transfer microcystin to higher trophic levels: either directly, through consumption by benthivorous fish such as the round goby; or indirectly, through their biodeposits, which are an important food source for benthic invertebrates. The results suggest that dreissenid mussels represent a potentially important benthic pathway for the food web transfer of microcystin., (Copyright © 2013 SETAC.)

Published

2013

16. Invasive mussels alter the littoral food web of a large lake: stable isotopes reveal drastic shifts in sources and flow of energy.

Author

Ozersky T, Evans DO, and Barton DR

Subjects

Animals, Biomass, Isotopes chemistry, Isotopes metabolism, Models, Statistical, Aquatic Organisms metabolism, Bivalvia metabolism, Energy Metabolism, Food Chain, Introduced Species, Lakes

Abstract

We investigated how establishment of invasive dreissenid mussels impacted the structure and energy sources of the littoral benthic food web of a large temperate lake. We combined information about pre- and postdreissenid abundance, biomass, and secondary production of the littoral benthos with results of carbon and nitrogen stable isotope analysis of archival (predreissenid) and recent (postdreissenid) samples of all common benthic taxa. This approach enabled us to determine the importance of benthic and sestonic carbon to the littoral food web before, and more than a decade after dreissenid establishment. Long term dreissenid presence was associated with a 32-fold increase in abundance, 6-fold increase in biomass, and 14-fold increase in secondary production of the littoral benthos. Dreissenids comprised a large portion of the post-invasion benthos, making up 13, 38, and 56% of total abundance, biomass, and secondary production, respectively. The predreissenid food web was supported primarily by benthic primary production, while sestonic material was relatively more important to the postdreissenid food web. The absolute importance of both sestonic material and benthic primary production to the littoral benthos increased considerably following dreissenid establishment. Our results show drastic alterations to food web structure and suggest that dreissenid mussels redirect energy and material from the water column to the littoral benthos both through biodeposition of sestonic material as well as stimulation of benthic primary production.

Published

2012