65 research outputs found
Composition of prokaryotic and eukaryotic microbial communities in waters around the Florida reef tract
The Florida Keys, a delicate archipelago of sub-tropical islands extending from the southeastern tip of Florida, host the vast majority of the only coral barrier reef in the continental United States. Abiotic as well as microbial components of the surrounding waters are pivotal for the health of reef habitats, and thus could play an important role in understanding the development and transmission of coral diseases in Florida. In this study, we analyzed microbial community structure and abiotic factors in waters around the Florida Reef Tract. Both bacterial and eukaryotic community structure were significantly linked with variations in temperature, dissolved oxygen, and total organic carbon values. High abundances of copiotrophic bacteria as well as several potentially harmful microbes, including coral pathogens, fish parasites and taxa that have been previously associated with Red Tide and shellfish poisoning were present in our datasets and may have a pivotal impact on reef health in this ecosystem
An estimation of diel metabolic rates of eight limnological archetypes from Estonia using high-frequency measurements
We employed a Bayesian model to assess the metabolic state of 8 Estonian lakes representing the 8 lake types according to the European Union Water Framework Directive. We hypothesized that long-term averages of light-related variables would be better predictors of lake metabolism than nutrient-related variables. Model input parameters were in situ high-frequency measurements of dissolved oxygen, temperature, and irradiance. Model simulations were conducted for several (5–12) diel cycles for each lake during the summer season. Accounting for uncertainty, the results from the Bayesian model revealed that 2 lakes were autotrophic for the duration of the experiment, 1 was heterotrophic, and 5 were balanced or had an ambiguous metabolic state. Cross-comparison with a traditional bookkeeping model showed that the majority of lakes were in metabolic balance. A strong coupling between primary production and respiration was observed, with the share of autochthonous primary production respired by consumers increasing with light extinction and nutrient-related variables. Unlike gross primary production, community respiration was strongly related to light extinction, dissolved organic carbon (DOC) and total phosphorus. These findings suggest that a drastic decrease in light-limited primary production along the DOC gradient counter-balanced nutrient supply in the darker lakes and thus blurred the relationship between primary production and nutrients. Thus, contrary to our hypothesis, both light and nutrient-related variables seemed to be good predictors of lake respiration and its coupling to lake primary production
How warming and other stressors affect zooplankton abundance, biomass and community composition in shallow eutrophic lakes
We aimed to investigate the influence of environmental factors and predict zooplankton
biomass and abundance in shallow eutrophic lakes. We employed time series of zoo-
plankton and environmental parameters that were measured monthly during 38 years in a
large, shallow eutrophic lake in Estonia to build estimates of zooplankton community
metrics (cladocerans, copepods, rotifers, ciliates). The analysis of historical time series
revealed that air temperature was by far the most important variable for explaining
zooplankton biomass and abundance, followed, in decreasing order of importance, by
pH, phytoplankton biomass and nitrate concentration. Models constructed with the best
predicting variables explained up to 71% of zooplankton biomass variance. Most of the
predictive variables had opposing or antagonistic interactions, often mitigating the effect
of temperature. In the second part of the study, three future climate scenarios were
developed following different Intergovernmental Panel on Climate Change (IPCC) tem-
perature projections and entered into an empirical model. Simulation results showed that
only a scenario in which air temperature stabilizes would curb total metazooplankton
biomass and abundance. In other scenarios, metazooplankton biomass and abundance
would likely exceed historical ranges whereas ciliates would not expand. Within the
metazooplankton community, copepods would increase in biomass and abundance,
whereas cladocerans would lose in biomass but not in abundance. These changes in the
zooplankton community will have important consequences for lake trophic structure and
ecosystem functioning.This research was supported by the Estonian Research Council Grants PSG32, PRG709 and institutional research funding IUT 21-2 of the Estonian Ministry of Education and Research.This research was supported by the Estonian Research Council Grants PSG32, PRG709
and institutional research funding IUT 21-2 of the Estonian Ministry of Education and Research
Predicting multiple stressor effect on zooplankton abundance, biomass and community composition in two large eutrophic lakes : [presentation]
Presentation at the BIOGEOMON 2022, 10th International Symposium on Ecosystem Behavior, June 26–30, 2022, Tartu, Estonia.We are grateful to Tartu Environmental Research Ltd (Estonia) for water chemistry data and to the Estonian Environment Board
for providing long-term air temperature data and supporting lake monitoring. This research was financed by Estonian Research
Council Grant PRG709, PRG1167, and institutional research funding P210160PKKH of the Estonian Ministry of Education and
Research. This project has received funding from the European Union’s Horizon 2020 research and innovation programme
under grant agreement No 951963. Data collection within the frames of the state monitoring programme were supported by
the Estonian Ministry of the Environment
Summer greenhouse gas fluxes in different types of hemiboreal lakes
Lakes are considered important regulators of atmospheric greenhouse gases (GHG). We estimated late summer open
water GHG fluxes in nine hemiboreal lakes in Estonia classified under different lake types according to the
European Water Framework Directive (WFD). We also used the WFD typology to provide an improved estimate of
the total GHG emission from all Estonian lakes with a gross surface area of 2204 km2 representing 45,227 km2 of
hemiboreal landscapes (the territory of Estonia). The results demonstrate largely variable CO2 fluxes among the lake
types with most active emissions from Alkalitrophic (Alk), Stratified Alkalitrophic (StratAlk), Dark Soft and with predominant binding in Coastal, Very Large, and Light Soft lakes. The CO2 fluxes correlated strongly with dissolved CO2
saturation (DCO2) values at the surface. Highest CH4 emissions were measured from the Coastal lake type, followed by
Light Soft, StratAlk, and Alk types; Coastal, Light Soft, and StratAlk were emitting CH4 partly as bubbles. The only emitter of N2O was the Alk type. We measured weak binding of N2O in Dark Soft and Coastal lakes, while in all other studied lake types, the N2O fluxes were too small to be quantified. Diversely from the common viewpoint of lakes as net
sources of both CO2 and CH4, it turns out from our results that at least in late summer, Estonian lakes are net sinks
of both CO2 alone and the sum of CO2 and CH4. This is mainly caused by the predominant CO2 sink function of
Lake Peipsi forming ¾ of the total lake area and showing negative net emissions even after considering the Global
Warming Potential (GWP) of other GHGs. Still, by converting CH4 data into CO2 equivalents, the combined emission
of all Estonian lakes (8 T C day−1
) is turned strongly positive: 2720 T CO2 equivalents per day.This research was inspired by GLEON (Global Lake Ecological Observatory Network) and was funded by Estonian Research Council (PSG32, PUT1598, PSG10, PRG709, PRG1167 and ETF8486), the European Union H2020 WIDESPREAD (TREICLAKE 951963) and the Swiss Program “Enhancing public environmental monitoring capacities”.This research was inspired by GLEON (Global Lake Ecological
Observatory Network) and was funded by Estonian Research Council
(PSG32, PUT1598, PSG10, PRG709, PRG1167 and ETF8486), the
European Union H2020 WIDESPREAD (TREICLAKE 951963) and the Swiss
Program “Enhancing public environmental monitoring capacities”
Generalist invasion in a complex lake food web
Invasive species constitute a threat not only to native populations but also to the structure and functioning of entire food webs. Despite being considered as a global problem, only a small number of studies have quantitatively predicted the food web-level consequences of invasions. Here, we use an allometric trophic network model parameterized using empirical data on species body masses and feeding interactions to predict the effects of a possible invasion of Amur sleeper (Perccottus glenii), on a well-studied lake ecosystem. We show that the modeled establishment of Amur sleeper decreased the biomasses o ftop predator fishes by about 10%–19%. These reductions were largely explained by increased larval competition for food and Amur sleeper predation on fish larvae. In contrast, biomasses of less valued fish of lower trophic positions increased by about 0.4%–9% owing to reduced predation pressure by top piscivores. The predicted impact of Amur sleeper establishment on the biomasses of native fish species vastly exceeded the impacts of current-dayfishing pressures.H2020 European Research Council, Grant/Award Number: COMPLEX-FISH770884; Academy of Finland, Grant/Award Numbers: 317495, 325107,340901; Natural Sciences and Engineering Research Council of Canada; Estonian Research Council, Grant/Award Numbers: PSG32, PRG1167, PRG709, MOBJD29; Estonian University of Life Sciences, Grant/Award Number: P190254PKKH; European Union's Horizon 2020 Research and Innovation Programme, Grant/Award Number: TREICLAKE 951963H2020 European Research Council, Grant/Award Number: COMPLEX-FISH770884; Academy of Finland, Grant/Award Numbers: 317495, 325107,340901; Natural Sciences and EngineeringResearch Council of Canada; EstonianResearch Council, Grant/Award Numbers: PSG32, PRG1167, PRG709, MOBJD29; Estonian University of Life Sciences, Grant/Award Number: P190254PKKH; European Union's Horizon 2020 Research and Innovation Programme, Grant/AwardNumber: TREICLAKE 95196
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Northern Hemisphere atmospheric stilling accelerates lake thermal responses to a warming world
Climate change, in particular the increase in air temperature, has been shown to influence
lake thermal dynamics, with climatic warming resulting in higher surface temperatures,
stronger stratification, and altered mixing regimes. Less-studied is the influence on lake
thermal dynamics of atmospheric stilling, the decrease in near-surface wind speed observed
in recent decades. Here we use a lake model to assess the influence of atmospheric stilling, on
lake thermal dynamics across the Northern Hemisphere. From 1980-2016, lake thermal
responses to warming have accelerated as a result of atmospheric stilling. Lake surface
temperatures and thermal stability have changed at respective rates of 0.33 and 0.38°C
decade-1, with atmospheric stilling contributing 15 and 27% of the calculated changes,
respectively. Atmospheric stilling also resulted in a lengthening of stratification, contributing
23% of the calculated changes. Our results demonstrate that atmospheric stilling has
influenced lake thermal responses to warming
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Atmospheric stilling leads to prolonged thermal stratification in a large shallow polymictic lake
To quantify the effects of recent and potential future decreases in surface wind speeds on lake thermal stratification, we apply the one-dimensional process-based model MyLake to a large, shallow, polymictic lake, Võrtsjärv. The model is validated for a 3-year period and run separately for 28 years using long-term daily atmospheric forcing data from a nearby meteorological station. Model simulations show exceptionally good agreement with observed surface and bottom water temperatures during the 3-year period. Similarly, simulated surface water temperatures for 28 years show remarkably good agreement with long-term in situ water temperatures. Sensitivity analysis demonstrates that decreasing wind speeds has resulted in substantial changes in stratification dynamics since 1982, while increasing air temperatures during the same period had a negligible effect. Atmospheric stilling is a phenomenon observed globally, and in addition to recent increases in surface air temperature, needs to be considered when evaluating the influence of climate change on lake ecosystems
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