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The Amazon River basins present distinct natural and anthropogenic characteristics that influence the structure of stream habitats and their associated biota. The influence of these characteristics can be evaluated through different spatial scales. We aimed to assess the influence (with and without the effect of spatial-geographical factors) of local, macroscale, and land-use variables in the structure of stream fish assemblages of Amazonian catchments with different deforestation levels. A partial redundancy analysis and a reduced metrics model were used to assess these influences. With geographic-spatial effects, we verified that the macroscale and local variables explained the variation in fish composition, and, without the effects, land use also explained the variation in this composition. In the forested catchments, the biota was associated with streams with natural characteristics (e.g., leaf banks). In the deforested catchments, it was associated with land use, sandy catchments with higher soil density (higher capacity of degradation), and less complex streams (fewer leaf banks, more sand). The associated fish have life features linked to these characteristics (e.g., Gymnorhamphichthys rondoni associated with sand). This configuration seems to be a result of both the impact of land use in the catchment (i.e., increased erosion, increased sedimentation) and the naturally sandy constitution of the catchment as well, reflecting the sandy substrate.

A Amazônia apresenta bacias hidrográficas com características naturais e antrópicas que estão presentes em distintas escalas espaciais da paisagem e que influenciam a estrutura do habitat de riachos e sua biota associada. Nosso objetivo foi verificar a influência (com e sem o efeito de fatores espaciais e geográficos) de variáveis locais, de macroescala e uso da terra na estrutura de assembleias de peixes de riachos de microbacias amazônicas com diferentes níveis de desmatamento. A análise de redundância parcial e modelo reduzido de métricas foram realizadas para verificar essas influências. Com os efeitos geográfico-espaciais, verificou-se que as variáveis de macroescala e locais explicavam a variação da composição dos peixes, e sem os efeitos, os usos da terra também explicaram. Nas microbacias florestadas, a biota foi associada a riachos com características naturais (e.g., bancos de folhas). Nas microbacias desmatadas, foi associada a usos da terra, a microbacias arenosas com maior densidade do solo (maior capacidade de degradação) e a riachos menos complexos (menos bancos de folhas e mais areia). Os peixes associados a essas microbacias desmatadas possuem aspectos de vida atrelados a essas características (e.g., Gymnorhamphichthys rondoni associado a areia). Essa configuração parece ser um reflexo tanto do impacto do uso da terra na microbacia (i.e., maior erosão, maior sedimentação) quanto da própria constituição natural arenosa da microbacia, refletindo o substrato arenoso.

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This study uses species distribution modeling and physiological and functional traits to predict the impacts of climate change on native freshwater fish in the Murray-Darling Basin, Australia. We modelled future changes in taxonomic and functional diversity in 2050 and 2080 for two scenarios of carbon emissions, identifying areas of great interest for conservation. Climatic-environmental variables were used to model the range of 23 species of native fish under each scenario. The consensus model, followed by the physiological filter of lethal temperature was retained for interpretation. Our study predicts a severe negative impact of climate change on both taxonomic and functional components of ichthyofauna of the Murray-Darling Basin. There was a predicted marked contraction of species ranges under both scenarios. The predictions showed loss of climatically suitable areas, species and functional characters. There was a decrease in areas with high values of functional richness, dispersion and uniqueness. Some traits are predicted to be extirpated, especially in the most pessimistic scenario. The climatic refuges for fish fauna are predicted to be in the southern portion of the basin, in the upper Murray catchment. Incorporating future predictions about the distribution of ichthyofauna in conservation management planning will enhance resilience to climate change.

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Biotic communities are shaped by adaptations from generations of exposure to selective pressures by recurrent and often infrequent events. In large rivers, floods can act as significant agents of change, causing considerable physical and biotic disturbance while often enhancing productivity and diversity. We show that the relative balance between these seemingly divergent outcomes can be explained by the rhythmicity, or predictability of the timing and magnitude, of flood events. By analyzing biological data for large rivers that span a gradient of rhythmicity in the Neotropics and tropical Australia, we find that systems with rhythmic annual floods have higher-fish species richness, more stable avian populations, and elevated rates of riparian forest production compared with those with arrhythmic flood pulses. Intensification of the hydrological cycle driven by climate change, coupled with reductions in runoff due to water extractions for human use and altered discharge from impoundments, is expected to alter the hydrologic rhythmicity of floodplain rivers with significant consequences for both biodiversity and productivity.

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