Functional diversity and redundancy across fish gut, sediment and water bacterial communities.

This article explores the functional diversity and redundancy in a bacterial metacommunity constituted of three habitats (sediment, water column and fish gut) in a coastal lagoon under anthropogenic pressure. Comprehensive functional gene arrays covering a wide range of ecological processes and stress resistance genes to estimate the functional potential of bacterial communities were used. Then, diversity partitioning was used to characterize functional diversity and redundancy within (α), between (β) and across (γ) habitats. It was showed that all local communities exhibit a highly diversified potential for the realization of key ecological processes and resistance to various environmental conditions, supporting the growing evidence that macro-organisms microbiomes harbour a high functional potential and are integral components of functional gene dynamics in aquatic bacterial metacommunities. Several levels of functional redundancy at different scales of the bacterial metacommunity were observed (within local communities, within habitats and at the metacommunity level). The results suggested a high potential for the realization of spatial ecological insurance within this ecosystem, that is, the functional compensation among microorganisms for the realization and maintenance of key ecological processes, within and across habitats. Finally, the role of macro-organisms as dispersal vectors of microbes and their potential influence on marine metacommunity dynamics were discussed

Unpacking ecosystem service bundles: towards predictive mapping of synergies and trade-offs between ecosystem services

Multiple ecosystem services (ES) can respond similarly to social and ecological factors to form bundles. Identifying key social-ecological variables and understanding how they co-vary to produce these consistent sets of ES may ultimately allow the prediction and modelling of ES bundles, and thus, help us understand critical synergies and trade-offs across landscapes. Such an understanding is essential for informing better management of multi-functional landscapes and minimising costly trade-offs. However, the relative importance of different social and biophysical drivers of ES bundles in different types of social-ecological systems remains unclear. As such, a bottom-up understanding of the determinants of ES bundles is a critical research gap in ES and sustainability science. Here, we evaluate the current methods used in ES bundle science and synthesize these into four steps that capture the plurality of methods used to examine predictors of ES bundles. We then apply these four steps to a cross-study comparison (North and South French Alps) of relationships between social-ecological variables and ES bundles, as it is widely advocated that cross-study comparisons are necessary for achieving a general understanding of predictors of ES associations. We use the results of this case study to assess the strengths and limitations of current approaches for understanding distributions of ES bundles. We conclude that inconsistency of spatial scale remains the primary barrier for understanding and predicting ES bundles. We suggest a hypothesis-driven approach is required to predict relationships between ES, and we outline the research required for such an understanding to emerge

Functional structure of fish assemblages along environmental gradients (Patos-Mirim lagoon complex, Brazil)

Les écosystèmes procurent de nombreux services essentiels aux sociétés humaines à travers les effets positifs de la biodiversité des communautés d'espèces. Par conséquent, identifier le rôle des organismes vivants et les facteurs influençant la diversité de leurs fonctions (ou diversité fonctionnelle), est indispensable pour prédire efficacement l'évolution des écosystèmes soumis aux pressions locales et globales.Cette thèse s'articule donc autour de deux axes: (i) établir un cadre méthodologique pour décrire la structure fonctionnelle locale et régionale des communautés, et (ii) améliorer la connaissance de l'impact des poissons sur la dégradation de la matière organique.Dans un premier temps, nous avons consolidé les outils méthodologiques permettant (i) d'améliorer la fiabilité des dendrogrammes fonctionnels, (ii) l'étude comparative des principaux indices de diversité fonctionnelle à l'échelle locale, et (iii) le développement d'une nouvelle décomposition de la diversité fonctionnelle en composantes locale (α), régionale (γ) et turnover (β). Appliqué aux communautés ichthyologiques échantillonnés le long d'un gradient de salinité, dans le système lagunaire de Patos-Mirim (Brésil), ce socle méthodologique nous a permis de révéler une structure fonctionnelle stable le long du gradient, en dépit d'une forte variabilité en composition d'espèces, ces communautés étant structurées majoritairement par un filtre environnemental agissant sur les capacités de locomotion des poissons.Dans un second temps, nous avons étudié l'impact des communautés ichthyologiques sur le cycle des nutriments. Plus précisément, nous avons estimé le potentiel de dégradation de la matière organique de plusieurs espèces de poissons, en étudiant la diversité fonctionnelle et génétique de leur flore bactérienne intestinale. Nous avons montré que les communautés ichthyologiques pouvaient influencer le recyclage des nutriments de façon non négligeable en raison d'un important potentiel de dégradation commun à la plupart des espèces étudiées, ce potentiel étant peu affecté par la diversité génétique ou les facteurs environnementaux.Ecosystems provide many services essential to Human societies through the positive effects of biodiversity exhibited by species communities. Therefore, identifying the role of living organisms and the factors influencing the diversity of their functions (i.e. functional diversity) is fundamental to accurately predict the evolution of ecosystems undergoing local and global pressures.This thesis is organized around two axes: (i) establishing a methodological framework to describe the functional structure of local and regional communities, and (ii) improving our knowledge of the impact of fish on the degradation of organic matter.First, we have consolidated the methodological tools through (i) the improvement of functional dendrograms reliability, (ii) the comparative study of the main indices estimating local functional diversity, and (iii) the development of a new decomposition of functional diversity into local (α) and regional (γ) components, and functional turnover (β). Applied to fish assemblages sampled along a salinity gradient in Patos-Mirim lagoons complex (Brazil), this methodological framework allowed us to reveal a steady functional structure, despite a high variability in species composition, these communities being primarily structured by environmental filtering acting on fish locomotion abilities.   In a second step, we studied the impact of fish communities on nutrient cycling. More specifically, we estimated degradation of organic matter potential of several fish species by studying the genetic and functional diversity of their intestinal bacterial flora. We showed that the fish community could significantly influence nutrient cycling through an important degradation potential, common to most species studied, which is weakly affected by genetic diversity or environmental factors

Changes in the spatial patterns of human appropriation of net primary production (HANPP) in Europe 1990–2006

<p>Changes in patterns of land use intesification (HANPP) in Europe between 1990 and 2006.</p> <p>Dataset used in Plutzar et al. (2015) Changes in the spatial patterns of human appropriation of net primary production (HANPP) in Europe 1990–2006. Regional Environmental Change.</p> <p>DOI 10.1007/s10113-015-0820-3</p> <p> </p> <p>The global dataset is available here: https://www.uni-klu.ac.at/socec/inhalt/1191.htm</p> <p> </p> <p> </p

Boreal and Lusitanian species display trophic niche variation in temperate waters

Abstract Climate change has non‐linear impacts on species distributions and abundance that have cascading effects on ecosystem structure and function. Among them are shifts in trophic interactions within communities. Sites found at the interface between two or more biogeographical regions, where species with diverse thermal preferenda are assembled, are areas of strong interest to study the impact of climate change on communities' interactions. This study examined variation in trophic structure in the Celtic Sea, a temperate environment that hosts a mixture of cold‐affiliated Boreal species and warm‐affiliated Lusitanian species. Using carbon and nitrogen stable isotope ratios, trophic niche area, width, and position were investigated for 10 abundant and commercially important demersal fish species across space and time. In general, the niches of Boreal species appear to be contracting while those of Lusitanian species expand, although there are some fluctuations among species. These results provide evidence that trophic niches can undergo rapid modifications over short time periods (study duration: 2014–2021) and that this process may be conditioned by species thermal preferenda. Boreal species displayed spatial variation in trophic niche width and seem to be facing increased competition with Lusitanian species for food resources. These findings underscore the need to utilize indicators related to species trophic ecology to track the ecosystem alterations induced by climate change. Such indicators could reveal that the vulnerability of temperate ecosystems is currently being underestimated

Linking inconsistencies in trophic level of marine fauna to fisheries discard consumption

peer reviewedDiscarding practices have become a serious source of concern for the perennation of marine resources, motivating discard bans implementation around the world. However, little is known about the fate of discards in marine environments. Discarding may provide food for various marine consumers, potentially affecting food web structure and stability. Yet, quantifying reliance upon discards is difficult because identity and frequency of discards may change according to multiple factors, and most previously used diet assessment techniques do not allow to assume consistency of feeding strategies over time. One currently untested hypothesis is that significant contribution of discards over time should reflect in an increased trophic level (TL), particularly in low TL consumers. Here, we test this hypothesis by modelling the TL and assimilated diet of consumers living in fishing grounds subject to important discarding using stable isotopes. We found that all sampled invertebrates, Chondrichthyes and some Actinopterygii depicted a higher than expected TL, which could be linked to potential discard consumption. We stress that understanding fisheries discards reintegration in marine food webs is crucial in the context of an ecosystem approach to fisheries management, to better understand the functioning of marine ecosystems subject to fishing and anticipate the potential impacts of discard bans

Assessing the diet and trophic level of marine fauna in a fishing ground subject to discarding activity using stable isotopes.

peer reviewedDiscarding practices have become a source of concern for the perennation of marine resources, prompting efforts of discard reduction around the globe. However, little is known about the fate of discards in marine environments. Discarding may provide food for various marine consumers, potentially affecting food web structure and stability. Yet, quantifying reliance upon discards is difficult because identity and frequency of discards may change according to multiple factors, and most previously used diet assessment techniques do not allow to assume consistency of feeding strategies over time. One currently untested hypothesis is that significant contribution of discards over time should reflect in increased trophic level (TL) of marine fauna, particularly in low TL consumers. Here, we explored this hypothesis by modeling the TL and assimilated diet of consumers living in fishing grounds subject to important discarding activity using stable isotope analysis. We found indications that benthic invertebrates and Chondrichthyes may depict a higher than expected TL, while other fish tend to depict similar to lower TL compared to global averages from the literature. Based on prior knowledge of discard consumption in the same area, stable isotope mixing models congruently revealed that discards may represent substantial portions of the assimilated diet of most benthic invertebrate macrofauna, cephalopods and Chondrichthyes. We highlight limitations and challenges of currently used diet assessment techniques to study discard consumption and stress that understanding their reintegration in marine food webs is crucial in the context of an ecosystem approach to fisheries management and to better understand the functioning of marine ecosystems subject to fishing

Gut content metabarcoding reveals potential importance of fisheries discards consumption in marine fauna

peer reviewedFisheries discards have become a source of concern for the perennation of marine resources. To reduce discards, the European Union adopted a Landing Obligation under the reform of its Common Fisheries Policy. However, food web consequences of reducing discards remain uncertain since their degree and pathway of reintegration are understudied. We used multi-marker DNA metabarcoding of gut contents and an ecological network approach to quantify marine fauna reliance on discarded fish and functional importance of discard consumers in coastal fishing grounds. We show that potential discard consumption is widespread across fish and invertebrates, but particularly important for decapods, which were also pinpointed as functionally important. Potential discard consumption may represent up to 66% of all interactions involving fish prey in the reconstructed network. We highlight that discard reliance may be more important than previously assessed in some fishing areas and support functionally important taxa. While reducing discarding remains a conservation priority, it is crucial to understand discards reintegration in marine food webs to anticipate changes in the context of an ecosystem approach to fisheries management

Assessing the diet and trophic level of marine fauna in a fishing ground subject to discarding activity using stable isotopes

Discarding practices have become a source of concern for the perennation of marine resources, prompting efforts of discard reduction around the globe. However, little is known about the fate of discards in marine environments. Discarding may provide food for various marine consumers, potentially affecting food web structure and stability. Yet, quantifying reliance upon discards is difficult because identity and frequency of discards may change according to multiple factors, and most previously used diet assessment techniques do not allow to assume consistency of feeding strategies over time. One currently untested hypothesis is that significant contribution of discards over time should reflect in increased trophic level (TL) of marine fauna, particularly in low TL consumers. Here, we explored this hypothesis by modeling the TL and assimilated diet of consumers living in fishing grounds subject to important discarding activity using stable isotope analysis. We found indications that benthic invertebrates and Chondrichthyes may depict a higher than expected TL, while other fish tend to depict similar to lower TL compared to global averages from the literature. Based on prior knowledge of discard consumption in the same area, stable isotope mixing models congruently revealed that discards may represent substantial portions of the assimilated diet of most benthic invertebrate macrofauna, cephalopods and Chondrichthyes. We highlight limitations and challenges of currently used diet assessment techniques to study discard consumption and stress that understanding their reintegration in marine food webs is crucial in the context of an ecosystem approach to fisheries management and to better understand the functioning of marine ecosystems subject to fishing