Rising water temperature in rivers: Ecological impacts and future resilience

Johnson, Matthew F.; Albertson, Lindsey K.; Algar, Adam C.; Dugdale, Stephen J.; Edwards, Patrick; England, Judy; Gibbins, Christopher; Kazama, So; Komori, Daisuke; MacColl, Andrew D. C.; Scholl, Eric A.; Wilby, Robert L.; de Oliveira Roque, Fabio; Wood, Paul J.

doi:10.1002/wat2.1724

Cited by 9 publications

(2 citation statements)

References 253 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…To investigate the extent of the microbial self-recycling and to test the hypotheses about multiple stressor increase and release, we used the outdoor experimental set-up “ ExStream ”, in which natural river water flows through multiple mesocosms filled with river sediment and larger river substrates, allowing for a replicated experimental design (Madge Pimentel et al, 2024; Piggott et al, 2015). We thereby focussed on the stressors temperature increase and salinization, as these are particularly threatening river ecosystem functioning worldwide (Berger et al, 2018; Canedo-Arguelles et al, 2013; Johnson et al, 2024). To test the effects of multiple stressors and release of stressors, river water flowing through the mesocosm was first left untreated to allow for acclimation of the communities.…”

Section: Introductionmentioning

confidence: 99%

Effects of temperature and salinity on microbial degradation of bacterial necromass in urban river sediments in outdoor mesocosm experiments

Hadžiomerović,

Baikova,

Madge Pimentel

et al. 2024

Preprint

View full text Add to dashboard Cite

Microorganisms play a key role in the functioning of healthy river ecosystems because they consume carbon and nutrients from dead biomass derived from algae and other higher organisms, or “necromass”, to feed it back into the food web. This so-called microbial loop is known to be substantial in aquatic systems, but it is so far unknown to which extent microorganisms perform self-recycling, i.e. recycling of necromass derived from microorganisms, and how this process is affected by multiple stressors such as increased temperature and salinity. In this study, we investigated microbial self-recycling in the sediment of the urban river Boye within a food-web context before, during, and after a period of increased temperature and salinity using the outdoor flow-through mesocosm system “ExStream”. Rates of self-recycling were measured in additional microcosms with sediment and water from ExStream as an increase in13CO2-concentration over time resulting from the microbial degradation of13C-labelled microbial necromass, which was offered either in the form of intact but deadEscherichia colicells, or lysedE. colicells. The results showed that microbial self-recycling was highest in the first days of incubation suggesting that microbial necromass is an easily biodegradable carbon source. Increased salinity had no effect, but increased temperature or temperature and salinity strongly increased the rate of whole cell-necromass recycling compared to the unstressed control, while it had no effect on lysed cell-necromass recycling. After stressor removal, rates of self-recycling were not distinguishable from the unstressed control, showing the resilience of this community function. The compositions of the necromass-degrading communities were highly similar and little affected by stressor increase or release but changed during the course of the experiment. This indicated that both necromass types stimulated growth of the same organisms and that stressor levels were rather low for microorganisms and dominated by the effects of the seasonal variation in the Boye. The study suggests that microbial communities in urban rivers exposed to moderate levels of multiple anthropogenic stressors will be rather stressor-resistant and show fast recovery of community functioning.

show abstract

Section: Introductionmentioning

confidence: 99%

Effects of temperature and salinity on microbial degradation of bacterial necromass in urban river sediments in outdoor mesocosm experiments

Hadžiomerović,

Baikova,

Madge Pimentel

et al. 2024

Preprint

View full text Add to dashboard Cite

show abstract

“…and habitats, including terrestrial (Lancaster & Humphreys, 2020), freshwater (Johnson et al, 2024) and marine (Oliver et al, 2018) systems. Moreover, thermal threats to populations may reflect not only long-term climate trends but also localised or more immediate fluctuations in temperature reflecting acute heatwaves or impacts of microhabitat alteration (e.g.…”

mentioning

confidence: 99%

Determining critical periods for thermal acclimatisation using a distributed lag non‐linear modelling approach

Redana,

Gibbins,

Lancaster

2024

Ecology and Evolution

View full text Add to dashboard Cite

Rapid changes in thermal environments are threatening many species worldwide. Thermal acclimatisation may partially buffer species from the impacts of these changes, but currently, the knowledge about the temporal dynamics of acclimatisation remains limited. Moreover, acclimatisation phenotypes are typically determined in laboratory conditions that lack the variability and stochasticity that characterise the natural environment. Through a distributed lag non‐linear model (DLNM), we use field data to assess how the timing and magnitude of past thermal exposures influence thermal tolerance. We apply the model to two Scottish freshwater Ephemeroptera species living in natural thermal conditions. Model results provide evidence that rapid heat hardening effects are dramatic and reflect high rates of change in temperatures experienced over recent hours to days. In contrast, temperature change magnitude impacted acclimatisation over the course of weeks but had no impact on short‐term responses. Our results also indicate that individuals may de‐acclimatise their heat tolerance in response to cooler environments. Based on the novel insights provided by this powerful modelling approach, we recommend its wider uptake among thermal physiologists to facilitate more nuanced insights in natural contexts, with the additional benefit of providing evidence needed to improve the design of laboratory experiments.

show abstract

The effects of drought on biodiversity in UK river ecosystems: Drying rivers in a wet country

Stubbington,

England,

Sarremejane

et al. 2024

WIREs Water

View full text Add to dashboard Cite

Climate change is interacting with water resource pressures to alter the frequency, severity and spatial extent of drought, which can thus no longer be considered a purely natural hazard. Although particularly severe ecological impacts of drought have occurred in drylands, its effects on temperate ecosystems, including rivers, are also considerable. Extensive research spanning a diverse range of UK rivers offers an opportunity to place the effects of past drought in the context of intensifying climate change and to examine the likely effects of future drought in a typically cool, wet country. Here, drought manifests instream as deficits in surface water, modified flow velocities, and—increasingly—partial or complete drying of previously perennial and naturally non‐perennial reaches. As a result, drought causes declines in the taxonomic and functional biodiversity of freshwater communities including microorganisms, algae, plants, invertebrates and fish, altering ecological processes and associated benefits to people. Although freshwater communities have typically recovered quickly after previous UK droughts, an increase in drought extremity may compromise recovery following future events. The risk of droughts that push ecosystems beyond thresholds to persistent, species‐poor, functionally simplified states is increasing. Research and monitoring are needed to enable timely identification of rivers approaching such thresholds and thus to inform interventions that pull these ecosystems back from the brink. Management actions that support natural flow regimes and promote natural processes that diversify instream habitats, including drought refuges, are also crucial to support biodiversity within functional river ecosystems as they adapt to a changing world.This article is categorized under: Water and Life > Nature of Freshwater Ecosystems Water and Life > Stresses and Pressures on Ecosystems Water and Life > Conservation, Management, and Awareness

show abstract

Rising water temperature in rivers: Ecological impacts and future resilience

Cited by 9 publications

References 253 publications

Effects of temperature and salinity on microbial degradation of bacterial necromass in urban river sediments in outdoor mesocosm experiments

Effects of temperature and salinity on microbial degradation of bacterial necromass in urban river sediments in outdoor mesocosm experiments

Determining critical periods for thermal acclimatisation using a distributed lag non‐linear modelling approach

The effects of drought on biodiversity in UK river ecosystems: Drying rivers in a wet country

Contact Info

Product

Resources

About