Multiple stressors affect function rather than taxonomic structure of freshwater microbial communities.

Microbial community responses to environmental stressors are often characterised by assessing changes in taxonomic structure, but such changes, or lack thereof, may not reflect functional changes that are critical to ecosystem processes. We investigated the individual and combined effects of nutrient enrichment ( + 10 mg/L N, + 1 mg/L P) and salinisation ( + 15 g/L NaCl)-key stressors in freshwater systems-on the taxonomic structure and metabolic function of benthic microbial communities using 1000 L open freshwater ponds established >10 years ago in the field. Combined stressors drove strong decreases in maximum and mean total carbon metabolic rates and shifted carbon metabolic profiles compared to either stressor individually and compared to ambient conditions.

Metabolic plasticity drives mismatches in physiological traits between prey and predator.

Metabolic rate, the rate of energy use, underpins key ecological traits of organisms, from development and locomotion to interaction rates between individuals. In a warming world, the temperature-dependence of metabolic rate is anticipated to shift predator-prey dynamics. Yet, there is little real-world evidence on the effects of warming on trophic interactions.

Microalgae colonization of different microplastic polymers in experimental mesocosms across an environmental gradient.

A variety of organisms can colonize microplastic surfaces through biofouling processes. Heterotrophic bacteria tend to be the focus of plastisphere research; however, the presence of epiplastic microalgae within the biofilm has been repeatedly documented. Despite the relevance of biofouling in determining the fate and effects of microplastics in aquatic systems, data about this process are still scarce, especially for freshwater ecosystems.

Climate change facilitated the early colonization of the Azores Archipelago during medieval times.

Humans have made such dramatic and permanent changes to Earth's landscapes that much of it is now substantially and irreversibly altered from its preanthropogenic state. Remote islands, until recently isolated from humans, offer insights into how these landscapes evolved in response to human-induced perturbations. However, little is known about when and how remote systems were colonized because archaeological data and historical records are scarce and incomplete.

Correction: Community structure informs species geographic distributions.

[This corrects the article DOI: 10.1371/journal.pone.

The interplay between habitat structure and chemical contaminants on biotic responses of benthic organisms.

Habitat structure influences the diversity and distribution of organisms, potentially affecting their response to disturbances by either affecting their 'susceptibility' or through the provision of resources that can mitigate impacts of disturbances. Chemical disturbances due to contamination are associated with decreases in diversity and functioning of systems and are also likely to increase due to coastal urbanisation. Understanding how habitat structure interacts with contaminants is essential to predict and therefore manage such effects, minimising their consequences to marine systems.

Macroalgal Composition Determines the Structure of Benthic Assemblages Colonizing Fragmented Habitats.

Understanding the consequences of fragmentation of coastal habitats is an important topic of discussion in marine ecology. Research on the effects of fragmentation has revealed complex and context-dependent biotic responses, which prevent generalizations across different habitats or study organisms. The effects of fragmentation in marine environments have been rarely investigated across heterogeneous habitats, since most studies have focused on a single type of habitat or patch.

Inferring biotic interactions from proxies.

Inferring biotic interactions from functional, phylogenetic and geographical proxies remains one great challenge in ecology. We propose a conceptual framework to infer the backbone of biotic interaction networks within regional species pools. First, interacting groups are identified to order links and remove forbidden interactions between species.

Macrofaunal responses to edges are independent of habitat-heterogeneity in experimental landscapes.

Despite edges being common features of many natural habitats, there is little general understanding of the ways assemblages respond to them. Every edge between two contrasting habitats has characteristics governed by the composition of adjoining habitats and/or by the nature of any transitions between them. To develop better explanatory theory, we examined the extent to which edges act independently of the composition of the surrounding landscape and to which transitions between different types of habitats affect assemblages.

Independent effects of patch size and structural complexity on diversity of benthic macroinvertebrates.

Despite a long history of work on relationships between area and number of species, the details of mechanisms causing patterns have eluded ecologists. The general principle that the number of species increases with the area sampled is often attributed to a sampling artifact due to larger areas containing greater numbers of individuals. We manipulated the patch size and surface area of experimental mimics of macro-algae to test several models that can explain the relationship between abundance and species richness of assemblages colonizing different habitats.

Interactions of components of habitats alter composition and variability of assemblages.

1. The nature and resources supplied by different components of habitats influence species, creating variability from place to place within a habitat. 2.