Your search keyword '"Rojo, Naiara"' showing total 5 results

1. Loss of Key Riparian Plant Species Impacts Stream Ecosystem Functioning

Author

Alonso, Alberto, Pérez, Javier, Monroy, Silvia, López-Rojo, Naiara, Basaguren, Ana, Bosch, Jaime, and Boyero, Luz

Published

2021

2. Shifts in Key Leaf Litter Traits Can Predict Effects of Plant Diversity Loss on Decomposition in Streams

Author

López-Rojo, Naiara, Pérez, Javier, Pozo, Jesús, Basaguren, Ana, Apodaka-Etxebarria, Unai, Correa-Araneda, Francisco, and Boyero, Luz

Published

2021

3. Litter decomposition can be reduced by pesticide effects on detritivores and decomposers: Implications for tropical stream functioning.

Author

Cornejo, Aydeé, Pérez, Javier, López-Rojo, Naiara, García, Gabriela, Pérez, Edgar, Guerra, Alisson, Nieto, Carlos, and Boyero, Luz

Subjects

STREAM function, PESTICIDES, FOREST litter, ECOSYSTEMS, INSECTICIDES, PLANT litter, BIOLOGICAL extinction, CHLOROTHALONIL

Abstract

Understanding which factors affect the process of leaf litter decomposition is crucial if we are to predict changes in the functioning of stream ecosystems as a result of human activities. One major activity with known consequences on streams is agriculture, which is of particular concern in tropical regions, where forests are being rapidly replaced by crops. While pesticides are potential drivers of reduced decomposition rates observed in agricultural tropical streams, their specific effects on the performance of decomposers and detritivores are mostly unknown. We used a microcosm experiment to examine the individual and joint effects of an insecticide (chlorpyrifos) and a fungicide (chlorothalonil) on survival and growth of detritivores (Anchytarsus, Hyalella and Lepidostoma), aquatic hyphomycetes (AH) sporulation rate, taxon richness, assemblage structure, and leaf litter decomposition rates. Our results revealed detrimental effects on detritivore survival (which were mostly due to the insecticide and strongest for Hyalella), changes in AH assemblage structure, and reduced sporulation rate, taxon richness and microbial decomposition (mostly in response to the fungicide). Total decomposition was reduced especially when the pesticides were combined, suggesting that they operated differently and their effects were additive. Importantly, effects on decomposition were greater for single-species detritivore treatments than for the 3-species mixture, indicating that detritivore species loss may exacerbate the consequences of pesticides of stream ecosystem functioning. Pesticide side effects. [Display omitted] • Chlorpyrifos and chlorothalonil had detrimental effects on stream organisms and decomposition. • Detritivores died mostly due to the insecticide, with differences among species. • Aquatic hyphomycete assemblages and their activity were altered mainly by the fungicide. • Total decomposition was reduced, with additive effects of both pesticides. • Effects on decomposition were weaker when all 3 detritivores species were present. Pesticides reduced litter decomposition rates and altered the associated detritivore and fungal assemblages in microcosms simulating tropical streams. Effects were attenuated when detritivore assemblages had three species compared to one, suggesting a key role of diversity for the maintenance of ecosystem functioning in streams exposed to pesticides. [ABSTRACT FROM AUTHOR]

Published

2021

4. Microplastics have lethal and sublethal effects on stream invertebrates and affect stream ecosystem functioning.

Author

López-Rojo, Naiara, Pérez, Javier, Alonso, Alberto, Correa-Araneda, Francisco, and Boyero, Luz

Subjects

STREAM function, FOREST litter, AQUATIC invertebrates, ANIMAL litters, LEAF physiology, AQUATIC insects, WATER distribution, FRESH water

Abstract

Microplastics (MPs) are contaminants of increasing concern due to their abundance, ubiquity and persistence over time. However, knowledge about MP distribution in fresh waters and their effects on freshwater organisms is still scarce, and there is virtually no information about their potential influence on ecosystem functioning. We used a microcosm experiment to examine the effects of MPs (fluorescent, 10-μm polystyrene microspheres) at different concentrations (from 0 to 103 particles mL−1) on leaf litter decomposition (a key process in stream ecosystems) and associated organisms (the caddisfly detritivore Sericostoma pyrenaicum), and the extent to which MPs were attached to leaf litter and ingested and egested by detritivores, thus assessing mechanisms of MP trophic transfer. We found that MPs caused detritivore mortality (which increased 9-fold at the highest concentration) but did not affect their growth. Analysis of fluorescence in samples suggested that MPs were rapidly ingested (most likely through ingestion of particles attached to leaf litter) and egested. Leaf litter decomposition was reduced as a result of increasing MP concentrations; the relationship was significant only in the presence of detritivores, but microbially-mediated decomposition showed a similar trend. Our findings provide novel evidence of harmful effects of MPs on aquatic insects and stream ecosystem functioning, and highlight the need for the standardization of methods in future experiments with MPs in order to allow comparisons and generalizations. Image 1 • We examined microplastic (MP) effects on leaf litter decomposition and detritrivore growth. • Detritivore mortality increased with MP concentration (0–1800 part. mL−1). • MPs reduced leaf litter decomposition, affecting ecosystem functioning. • MPs were found in detritivore faeces indicating ingestion and egestion. • MP adherence to leaf litter suggested they were ingested while feeding. [ABSTRACT FROM AUTHOR]

Published

2020

5. A common fungicide impairs stream ecosystem functioning through effects on aquatic hyphomycetes and detritivorous caddisflies.

Author

Cornejo, Aydeé, Pérez, Javier, Alonso, Alberto, López-Rojo, Naiara, Monroy, Silvia, and Boyero, Luz

Subjects

*AQUATIC invertebrates, *FUNGICIDES, *STREAM function, *HYPHOMYCETES, *PLANT diversity, *INSECT larvae, *FOREST litter, *AQUATIC ecology

Abstract

Fungicides can reach streams through runoff or adhered to leaf litter, and have the potential to adversely affect processes such as litter decomposition and associated communities. This study investigated the effects of chlorothalonil, a widely used fungicide, on litter decomposition, detritivorous invertebrates (larvae of the insect Sericostoma pyrenaicum) and aquatic hyphomycetes (AHs), using stream microcosms. We considered the single and combined effects of two exposure modes: waterborne fungicide (at two concentrations: 0.125 μg L−1 and 1.25 μg L−1) and litter previously sprayed with the fungicide (i.e., pre-treated litter, using the application dose concentration of 1250 μg L−1). We also assessed whether fungicide effects on invertebrates, AHs and decomposition varied among litter types (i.e., different plant species), and whether plant diversity mitigated any of those effects. Invertebrate survival and AH sporulation rate and taxon richness were strongly reduced by most combinations of fungicide exposure modes; however, invertebrates were not affected by the low waterborne concentration, whereas AHs suffered the highest reduction at this concentration. Total decomposition was slowed down by both exposure modes, and microbial decomposition was reduced by litter pre-treatment, while the waterborne fungicide had different effects depending on plant species. In general, with the exception of microbial decomposition, responses varied little among litter types. Moreover, and contrary to our expectation, plant diversity did not modulate the fungicide effects. Our results highlight the severity of fungicide inputs to streams through effects on invertebrate and microbial communities and ecosystem functioning, even in streams with well-preserved, diverse riparian vegetation. • Chlorothalonil risk assessment on stream communities and ecological processes. • Microcosm assay to test single and combined effects of two different exposure modes. • Litter pretreatment and waterborne fungicide impaired decomposers and detritivores. • Litter diversity failed to mitigate any of the observed harmful fungicide effects. • Fungicide management should consider their effects on aquatic ecosystems. [ABSTRACT FROM AUTHOR]

Published

2020