Hydro-écologie des communautés d'invertébrés aquatiques dans les rivières glaciaires équatoriennes

In mountainous glacierized catchments, stream biodiversity is strongly influenced by physicochemical habitat heterogeneity linked to the spatio-temporal dynamics of water source contributions from snowmelt, ice-melt and groundwater. One impact of climate change is the rapid shrinking of glaciers, resulting in a reduction in glacial meltwater contribution to river flow in glacierized catchments. These modifications in water regimes are expected to affect the aquatic biodiversity. Thus it is of critical importance to understand the effect of glacial influence on aquatic communities in glacierized catchments to be able to predict the impact of glacier retreat on the aquatic biodiversity. In this study, we investigated the effects of the glacial influence on aquatic macroinvertebrates. The study was conducted in 51 stream sites in a glacierized catchment in the equatorial Andes (Antisana, Ecuador), where glacial floods occur all year round due to the lack of thermal seasonality. Our main objectives were to determine the glacial influence at each stream site; to characterize the impact of the glacial influence on the macroinvertebrate communities; and to anticipate the aquatic macroinvertebrates response to glacier retreat. In order to meet these objectives, we quantified the glacial influence using different methods and test its effects on macroinvertebrates at different scales from the stream reach to the entire catchment. These analyses allowed us to better understand the mechanisms governing macroinvertebrates distribution, and to determine the potential risk of species loss with the diminution of glacial meltwater contribution.Dans les bassins versants montagneux englacés la biodiversité des rivières est fortement influencée par l'hétérogénéité physico-chimique des habitats due aux dynamiques spatio-temporelles des contributions des différentes sources d'eau: la fonte des neiges, de la glace et les eaux souterraines. Un des effets du réchauffement climatique est l'accélération de la fonte des glaciers entraînant la réduction de la contribution en eaux de fonte. Cette modification du régime des eaux va probablement affecter la biodiversité aquatique. Ainsi il est primordial d'identifier les effets de l'influence glaciaire sur les communautés aquatiques afin de pouvoir prévoir l'impact du retrait glaciaire sur la biodiversité aquatique. Dans cette étude nous avons examiné l'effet de l'influence glaciaire sur les macroinvertébrés aquatiques. L'étude a été menée dans 51 sites dans un bassin versant englacé dans les Andes équatoriennes (Antisana, Équateur) où les crues glaciaires ont lieu toute l'année dû au manque de saison. Nos principaux objectifs étaient de déterminer l'influence glaciaire à chaque site, caractériser l'impact de l'influence glaciaire sur les communautés de macroinvertébrés et anticiper la réponse des macroinvertébrés aquatiques face au retrait des glaciers. Pour répondre à ces objectifs, nous avons quantifié l'influence glaciaire à partir de différentes méthodes et testé son effet sur les macroinvertébrés à plusieurs échelles: du cours d'eau au bassin versant. Cette étude nous a permis de mieux comprendre les mécanismes dirigeant la distribution des macroinvertébrés et de déterminer le potentiel risque d'extinction d'espèces due la diminution de la contribution en eau glaciaire

Ecological responses to experimental glacier-runoff reduction in alpine rivers

International audienceGlacier retreat is a worldwide phenomenon with important consequences for the hydrological cycle and downstream ecosystem structure and functioning. To determine the effects of glacier retreat on aquatic communities, we conducted a 4-year flow manipulation in a tropical glacier-fed stream. Compared with an adjacent reference stream, meltwater flow reduction induces significant changes in benthic fauna community composition in less than 2 weeks. Also, both algal and herbivore biomass significantly increase in the manipulated stream as a response to flow reduction. After the flow reduction ceased, the system requires 14-16 months to return to its pre-perturbation state. These results are supported by a multi-stream survey of sites varying in glacial influence, showing an abrupt increase in algal and herbivore biomass below 11% glacier cover in the catchment. This study shows that flow reduction strongly affects glacier-fed stream biota, prefiguring profound ecological effects of ongoing glacier retreat on aquatic systems

Fungal decomposition of river organic matter accelerated by decreasing glacier cover

Climate change is altering the structure and functioning of river ecosystems worldwide. In mountain rivers, glacier retreat has been shown to result in systematic changes in aquatic invertebrate biodiversity, but the effects of ice loss on other biological taxa and on whole-ecosystem functions are less well understood. Using data from mountain rivers spanning six countries on four continents, we show that decreasing glacier cover leads to consistent fungal-driven increases in the decomposition rate of cellulose, the world’s most abundant organic polymer. Cellulose decomposition rates were associated with greater abundance of aquatic fungi and the fungal cellulose-degrading Cellobiohydrolase I (cbhI) gene, illustrating the potential for predicting ecosystem-level functions from gene-level data. Clear associations between fungal genes, populations and communities and ecosystem functioning in mountain rivers indicate that ongoing global decreases in glacier cover can be expected to change vital ecosystem functions, including carbon cycle processes

Simulating rewetting events in intermittent rivers and ephemeral streams: A global analysis of leached nutrients and organic matter

Climate change and human pressures are changing the global distribution and the ex‐ tent of intermittent rivers and ephemeral streams (IRES), which comprise half of the global river network area. IRES are characterized by periods of flow cessation, during which channel substrates accumulate and undergo physico‐chemical changes (precon‐ ditioning), and periods of flow resumption, when these substrates are rewetted and release pulses of dissolved nutrients and organic matter (OM). However, there are no estimates of the amounts and quality of leached substances, nor is there information on the underlying environmental constraints operating at the global scale. We experi‐ mentally simulated, under standard laboratory conditions, rewetting of leaves, river‐ bed sediments, and epilithic biofilms collected during the dry phase across 205 IRES from five major climate zones. We determined the amounts and qualitative character‐ istics of the leached nutrients and OM, and estimated their areal fluxes from riverbeds. In addition, we evaluated the variance in leachate characteristics in relation to selected environmental variables and substrate characteristics. We found that sediments, due to their large quantities within riverbeds, contribute most to the overall flux of dis‐ solved substances during rewetting events (56%–98%), and that flux rates distinctly differ among climate zones. Dissolved organic carbon, phenolics, and nitrate contrib‐ uted most to the areal fluxes. The largest amounts of leached substances were found in the continental climate zone, coinciding with the lowest potential bioavailability of the leached OM. The opposite pattern was found in the arid zone. Environmental vari‐ ables expected to be modified under climate change (i.e. potential evapotranspiration, aridity, dry period duration, land use) were correlated with the amount of leached sub‐ stances, with the strongest relationship found for sediments. These results show that the role of IRES should be accounted for in global biogeochemical cycles, especially because prevalence of IRES will increase due to increasing severity of drying event

Biodiversity response to glacier retreat: from glacier foreland to the ice ecosystem

International audienc

Hydroecology of invertebrate communities in equatorial glacier-fed streams

Dans les bassins versants montagneux englacés la biodiversité des rivières est fortement influencée par l'hétérogénéité physico-chimique des habitats due aux dynamiques spatio-temporelles des contributions des différentes sources d'eau: la fonte des neiges, de la glace et les eaux souterraines. Un des effets du réchauffement climatique est l'accélération de la fonte des glaciers entraînant la réduction de la contribution en eaux de fonte. Cette modification du régime des eaux va probablement affecter la biodiversité aquatique. Ainsi il est primordial d'identifier les effets de l'influence glaciaire sur les communautés aquatiques afin de pouvoir prévoir l'impact du retrait glaciaire sur la biodiversité aquatique. Dans cette étude nous avons examiné l'effet de l'influence glaciaire sur les macroinvertébrés aquatiques. L'étude a été menée dans 51 sites dans un bassin versant englacé dans les Andes équatoriennes (Antisana, Équateur) où les crues glaciaires ont lieu toute l'année dû au manque de saison. Nos principaux objectifs étaient de déterminer l'influence glaciaire à chaque site, caractériser l'impact de l'influence glaciaire sur les communautés de macroinvertébrés et anticiper la réponse des macroinvertébrés aquatiques face au retrait des glaciers. Pour répondre à ces objectifs, nous avons quantifié l'influence glaciaire à partir de différentes méthodes et testé son effet sur les macroinvertébrés à plusieurs échelles: du cours d'eau au bassin versant. Cette étude nous a permis de mieux comprendre les mécanismes dirigeant la distribution des macroinvertébrés et de déterminer le potentiel risque d'extinction d'espèces due la diminution de la contribution en eau glaciaire.In mountainous glacierized catchments, stream biodiversity is strongly influenced by physicochemical habitat heterogeneity linked to the spatio-temporal dynamics of water source contributions from snowmelt, ice-melt and groundwater. One impact of climate change is the rapid shrinking of glaciers, resulting in a reduction in glacial meltwater contribution to river flow in glacierized catchments. These modifications in water regimes are expected to affect the aquatic biodiversity. Thus it is of critical importance to understand the effect of glacial influence on aquatic communities in glacierized catchments to be able to predict the impact of glacier retreat on the aquatic biodiversity. In this study, we investigated the effects of the glacial influence on aquatic macroinvertebrates. The study was conducted in 51 stream sites in a glacierized catchment in the equatorial Andes (Antisana, Ecuador), where glacial floods occur all year round due to the lack of thermal seasonality. Our main objectives were to determine the glacial influence at each stream site; to characterize the impact of the glacial influence on the macroinvertebrate communities; and to anticipate the aquatic macroinvertebrates response to glacier retreat. In order to meet these objectives, we quantified the glacial influence using different methods and test its effects on macroinvertebrates at different scales from the stream reach to the entire catchment. These analyses allowed us to better understand the mechanisms governing macroinvertebrates distribution, and to determine the potential risk of species loss with the diminution of glacial meltwater contribution

Salinization of Alpine rivers during winter months

International audienceHuman-induced (i.e., secondary) salinization affects aquatic biodiversity and ecosystem functioning worldwide. While agriculture or resource extraction are the main drivers of secondary salinization in arid and semi-arid regions of the world, the application of deicing road salt in winter can be an important source of salts entering freshwaters in cold regions. Alpine rivers are probably affected by salinization, especially in highly populated mountain regions, although this remains to be explored. In this study, we analyzed multi-year conductance time series from four rivers in the European Alps and demonstrated that the application of deicing road salt is linked to peaking rivers’ salinity levels during late winter/early spring. Especially in small catchments with more urban surfaces close to the rivers, conductance increased during constant low-flow periods in late winter and was less correlated with discharge than in summer. Thus, our results suggest that small rivers highly connected to urban infrastructures are prone to considerable salinity peaks during late winter/early spring. Given the low natural level of salinities in Alpine rivers, the aquatic biodiversity might be significantly affected by the recorded changes in conductance, with potential consequences on ecosystem functioning. Thereby, we urge the research community to assess the impact of secondary salinization in Alpine rivers and call for an implementation of management practices to prevent the degradation of these pristine and valuable ecosystems

Macroinvertebrate hydraulic preference models: a tool for predicting and mitigating the impacts of water abstractions in mountain streams

International audienc

Living at the Edge: Increasing Stress for Plants 2–13 Years After the Retreat of a Tropical Glacier

International audienceRapid warming is a major threat for the alpine biodiversity but, at the same time, accelerated glacial retreat constitutes an opportunity for taxa and communities to escape range contraction or extinction. We explored the first steps of plant primary succession after accelerated glacial retreat under the assumption that the first few years are critical for the success of plant establishment. To this end, we examined plant succession along a very short post-glacial chronosequence in the tropical Andes of Ecuador (2–13 years after glacial retreat). We recorded the location of all plant individuals within an area of 4,200 m2 divided into plots of 1 m2. This sampling made it possible to measure theresponses of the microenvironment, plant diversity and plants traits to time since the glacial retreat. It also made it possible to produce species-area curves and to estimate positive interactions between species. Decreases in soil temperature, soil moisture, and soil macronutrients revealed increasing abiotic stress for plants between two and 13 years after glacial retreat. This increasing stress seemingly explained the lack of positive correlation between plant diversity and time since the glacial retreat. It might explain the decreasing performance of plants at both the population (lower plant height) and the community levels (lower species richness and lower accumulation of species perarea). Meanwhile, infrequent spatial associations among plants indicated a facilitation deficit and animal-dispersed plants were almost absent. Although the presence of 21 species on such a small sampled area seven years after glacial retreat could look like a colonization success in the first place, the increasing abiotic stress may partly erase this success, reducing species richness to 13 species after 13 years and increasing the frequency of patches without vegetation. This fine-grain distribution study sheds new light on nature’s responses to the effects of climate change in cold biomes, suggesting that faster glacial retreat would not necessarily result in accelerated plant colonization. Results are exploratory and require site replications for generalization