Disruption of ecological networks in lakes by climate change and nutrient fluctuations

Merz, Ewa; Saberski, Erik; Gilarranz, Luis J.; Isles, Peter D. F.; Sugihara, George; Berger, C.; Pomati, Francesco

doi:10.1038/s41558-023-01615-6

Cited by 19 publications

(19 citation statements)

References 63 publications

(91 reference statements)

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“…Thus, for both lakes and streams, we expected warming to decrease top consumer occurrence (Ho et al, 2022;Merz et al, 2023), increase herbivory and omnivory (O'Connor, 2009;Wootton, 2017) and reduce mean trophic levels within food webs (Jackson et al, 2020;O'Gorman et al, 2019). As in freshwater ecosystems, top predators can be large consumers with wider niche breadth (Ho et al, 2022), we expected connectance to decrease with warming in lakes (Merz et al, 2023) and streams (Ho et al, 2022;O'Gorman et al, 2019).…”

Section: Introductionmentioning

confidence: 92%

“…Another difference is their geological history: lakes can have diverse origins and ages, while rivers are more uniform in their formation and evolution (Allan & Castillo, 2009;Wetzel, 2001). These differences have implications for the ecology and biodiversity of these systems and influence how communities respond to environmental changes (Ho et al, 2022;Merz et al, 2023;Rosset et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

“…We first tested the hypothesis that (H1) land use intensification favours generalist consumers in freshwater food webs due to ecosystem homogenization (Estes et al, 2011;Schürings et al, 2022). We expected a decrease in the number of top specialist consumers (Ho et al, 2022;Merz et al, 2023) and, consequently, an increase in herbivory and omnivory (Wootton, 2017), decrease in mean trophic levels and higher connectance values in both lake and streams, as generalists concentrate a higher number of links within few species (Riede et al, 2010;Tylianakis & Morris, 2017). However, (H2) the exclusion of top predators could also reduce connectance, as in cases where environmental changes caused the extinction of generalist top consumers with relatively broader diets in lakes (Merz et al, 2023) and streams (Ho et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

“…Regarding temperature change, we tested the following hypothesis: (H3) warming increases the demand for food resources, selecting against large top predators and favouring omnivores and species at lower trophic levels (Jackson et al, 2020;Wootton, 2017). Thus, for both lakes and streams, we expected warming to decrease top consumer occurrence (Ho et al, 2022;Merz et al, 2023), increase herbivory and omnivory (O'Connor, 2009;Wootton, 2017) and reduce mean trophic levels within food webs (Jackson et al, 2020;O'Gorman et al, 2019). As in freshwater ecosystems, top predators can be large consumers with wider niche breadth (Ho et al, 2022), we expected connectance to decrease with warming in lakes (Merz et al, 2023) and streams (Ho et al, 2022;O'Gorman et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

“…Regarding precipitation change, we tested the following hypothesis: (H5) water limits the flux of biomass across trophic levels and regulate the loss of species and interactions (Ledger et al, 2013;Rosenblatt et al, 2017). Thus, we expected reduced precipitation to decrease top consumers, mean trophic level and connectance in lakes and streams (Ho et al, 2022;Merz et al, 2023). However, (H6) physical aspects of ecosystems govern how precipitation change influences freshwater communities (Rosset et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

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Direct and indirect relationships of climate and land use change with food webs in lakes and streams

Barbosa,

Siqueira

2023

Global Ecol Biogeogr

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AimClimate and land use change can independently affect food web structure. However, their direct and indirect relationships with food webs are not well‐understood. This is particularly relevant for freshwater ecosystems, which are strongly affected by global threats and differ substantially in attributes and functioning. Here, we investigated direct and indirect relationships between climate and land use changes and freshwater food web structure, while considering the differences between lakes and streams.LocationMulticontinental.Time periodCurrent.Major taxa studiedFreshwater taxa.MethodsWe compiled 51 food webs, spanning 12 countries and six continents to investigate the direct and indirect relationships between land use intensity, changes in air temperature and precipitation and food web structure, using structural equation modelling (SEM). We further tested how lake and stream food webs differ in their responses to environmental change by applying a multigroup analysis to our SEM.ResultsWe found that connectance was positively related to both land use intensity and increases in air temperature and precipitation in stream food webs, whereas in lakes, it was only related to temperature. These findings suggest a dominance of generalists where conversion to agriculture and urbanization has been intensified, and temperature has increased. Food web vertical structure was negatively related to land use and increases in air temperature and precipitation, but climatic predictors were only linked to network structure through a negative relationship with the fraction of top consumers.Main conclusionsWhile land use intensity was directly related to food web structure, complex relationships between changes in climate and network topology were mediated by the fraction of top consumers. Also, as food webs in lakes and streams responded differently to land use and climate change, we suggest that their intrinsic characteristics must be explicitly considered to fully understand the effects of global changes on freshwater biodiversity.

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Section: Introductionmentioning

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Direct and indirect relationships of climate and land use change with food webs in lakes and streams

Barbosa,

Siqueira

2023

Global Ecol Biogeogr

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The dependence of forecasts on sampling frequency as a guide to optimizing monitoring in community ecology

Daugaard,

Merkli,

Merz

et al. 2024

Ecosphere

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Facing climate change and biodiversity loss, it is critical that ecology advances so that processes, such as species interactions and dynamics, can be correctly estimated and skillfully forecasted. As different processes occur on different time scales, the sampling frequency used to record them should intuitively match these scales. Yet, the effect of data sampling frequency on ecological forecasting accuracy is understudied. Using a simple simulated dataset as a baseline and a more complex high‐frequency plankton dataset, we tested how different sampling frequencies impacted abundance forecasts of different plankton classes and the estimation of their interactions. We then investigated whether plankton growth rates and body sizes could be used to select the most appropriate sampling frequency. The simple simulated dataset showed that the optimal sampling frequency scaled positively with growth rate. This finding was not repeated in the analyses of the plankton time series, however. There, we found that a reduction in sampling frequency worsened forecasts and led us to both over‐ and underestimate plankton interactions. This suggests that forecasting can be used to determine the ideal sampling frequency in scientific and monitoring programs. A better study design will improve theoretical understanding of ecology and advance policy measures dealing with current global challenges.

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Spring and autumn rotifer community structure differentiates shallow water bodies in two European ecoregions: Poland and Croatia

Kuczyńska-Kippen,

Špoljar,

Pronin

et al. 2024

Hydrobiologia

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Rotifer structure may serve as predictor of environmental features, including temperate subclimates between water bodies. The difference in latitude between two temperate regions (Poland vs. Croatia) affects the identification of particular environmental factors that subsequently influence the taxon-related indices of rotifers. A study on 10 water bodies found that taxon-trait indices were sensitive in identifying latitude differences, even though extreme weather conditions were not considered, and only two seasons (spring and autumn) were examined. A variable rotifer community, with a high share of rare species, was obtained. We found a distinctiveness of abiotic factors between both countries, indicating a higher trophic state in Poland. Although habitat conditions were more similar in spring compared to the autumn, the percentage of rotifer common taxa was alike in both seasons but variation in distinct species community was clear. Trophic state increase in Poland was reflected in the structure of dominant and distinct species, with a wide range of eutrophy indicators. Comparing how rotifer species respond to environmental conditions is important for developing methods to assess trophic state changes due to climate change. Single species, distinct or rare species, are often the first sign of changes.

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Disruption of ecological networks in lakes by climate change and nutrient fluctuations

Cited by 19 publications

References 63 publications

Direct and indirect relationships of climate and land use change with food webs in lakes and streams

Direct and indirect relationships of climate and land use change with food webs in lakes and streams

The dependence of forecasts on sampling frequency as a guide to optimizing monitoring in community ecology

Spring and autumn rotifer community structure differentiates shallow water bodies in two European ecoregions: Poland and Croatia

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