Tree diversity increases robustness of multi-trophic interactions

Multi-trophic interactions maintain critical ecosystem functions. Biodiversity is declining globally, while responses of trophic interactions to biodiversity change are largely unclear. Thus, studying responses of multi-trophic interaction robustness to biodiversity change is crucial for understanding ecosystem functioning and persistence. We investigate plant–Hemiptera (antagonism) and Hemiptera–ant (mutualism) interaction networks in response to experimental manipulation of tree diversity. We show increased diversity at both higher trophic levels (Hemiptera and ants) and increased robustness through redundancy of lower level species of multi-trophic interactions when tree diversity increased. Hemiptera and ant diversity increased with tree diversity through non-additive diversity effects. Network analyses identified that tree diversity also increased the number of tree and Hemiptera species used by Hemiptera and ant species, and decreased the specialization on lower trophic level species in both mutualistic and antagonist interactions. Our results demonstrate that bottom-up effects of tree diversity ascend through trophic levels regardless of interaction type. Thus, local tree diversity is a key driver of multi-trophic community diversity and interaction robustness in forests.

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Tree Diversity Reduces Fungal Endophyte Richness and Diversity in a Large-Scale Temperate Forest Experiment

Diversity ◽

10.3390/d11120234 ◽

2019 ◽

Vol 11 (12) ◽

pp. 234 ◽

Cited By ~ 2

Author(s):

Eric A. Griffin ◽

Joshua G. Harrison ◽

Melissa K. McCormick ◽

Karin T. Burghardt ◽

John D. Parker

Keyword(s):

Phylogenetic Diversity ◽

Large Scale ◽

High Throughput Sequencing ◽

Spatial Scales ◽

Fungal Endophytes ◽

Fungal Endophyte ◽

Tree Diversity ◽

Trophic Levels ◽

Community Diversity ◽

And Function

Although decades of research have typically demonstrated a positive correlation between biodiversity of primary producers and associated trophic levels, the ecological drivers of this association are poorly understood. Recent evidence suggests that the plant microbiome, or the fungi and bacteria found on and inside plant hosts, may be cryptic yet important drivers of important processes, including primary production and trophic interactions. Here, using high-throughput sequencing, we characterized foliar fungal community diversity, composition, and function from 15 broadleaved tree species (N = 545) in a recently established, large-scale temperate tree diversity experiment using over 17,000 seedlings. Specifically, we tested whether increases in tree richness and phylogenetic diversity would increase fungal endophyte diversity (the “Diversity Begets Diversity” hypothesis), as well as alter community composition (the “Tree Diversity–Endophyte Community” hypothesis) and function (the “Tree Diversity–Endophyte Function” hypothesis) at different spatial scales. We demonstrated that increasing tree richness and phylogenetic diversity decreased fungal species and functional guild richness and diversity, including pathogens, saprotrophs, and parasites, within the first three years of a forest diversity experiment. These patterns were consistent at the neighborhood and tree plot scale. Our results suggest that fungal endophytes, unlike other trophic levels (e.g., herbivores as well as epiphytic bacteria), respond negatively to increasing plant diversity.

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Biotic interactions, community assembly, and eco-evolutionary dynamics as drivers of long-term biodiversity–ecosystem functioning relationships

Research Ideas and Outcomes ◽

10.3897/rio.5.e47042 ◽

2019 ◽

Vol 5 ◽

Cited By ~ 2

Author(s):

Nico Eisenhauer ◽

Michael Bonkowski ◽

Ulrich Brose ◽

Francois Buscot ◽

Walter Durka ◽

...

Keyword(s):

Community Assembly ◽

Ecosystem Functioning ◽

Biotic Interactions ◽

Research Unit ◽

Ecosystem Functions ◽

Feedback Effects ◽

Biodiversity Change ◽

Diversity Effects ◽

The Jena Experiment

The functioning and service provisioning of ecosystems in the face of anthropogenic environmental and biodiversity change is a cornerstone of ecological research. The last three decades of biodiversity–ecosystem functioning (BEF) research have provided compelling evidence for the significant positive role of biodiversity in the functioning of many ecosystems. Despite broad consensus of this relationship, the underlying ecological and evolutionary mechanisms have not been well understood. This complicates the transition from a description of patterns to a predictive science. The proposed Research Unit aims at filling this gap of knowledge by applying novel experimental and analytical approaches in one of the longest-running biodiversity experiments in the world: the Jena Experiment. The central aim of the Research Unit is to uncover the mechanisms that determine BEF relationships in the short- and in the long-term. Increasing BEF relationships with time in long-term experiments do not only call for a paradigm shift in the appreciation of the relevance of biodiversity change, they likely are key to understanding the mechanisms of BEF relationships in general. The subprojects of the proposed Research Unit fall into two tightly linked main categories with two research areas each that aim at exploring variation in community assembly processes and resulting differences in biotic interactions as determinants of the long-term BEF relationship. Subprojects under “Microbial community assembly” and “Assembly and functions of animal communities” mostly focus on plant diversity effects on the assembly of communities and their feedback effects on biotic interactions and ecosystem functions. Subprojects under “Mediators of plant-biotic interactions” and “Intraspecific diversity and micro-evolutionary changes” mostly focus on plant diversity effects on plant trait expression and micro-evolutionary adaptation, and subsequent feedback effects on biotic interactions and ecosystem functions. This unification of evolutionary and ecosystem processes requires collaboration across the proposed subprojects in targeted plant and soil history experiments using cutting-edge technology and will produce significant synergies and novel mechanistic insights into BEF relationships. The Research Unit of the Jena Experiment is uniquely positioned in this context by taking an interdisciplinary and integrative approach to capture whole-ecosystem responses to changes in biodiversity and to advance a vibrant research field.

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Mesoscale variations in the assemblage structure and trophodynamics of mesozooplankton communities of the Adriatic basin (Mediterranean Sea)

10.5194/bg-2021-240 ◽

2021 ◽

Author(s):

Emanuela Fanelli ◽

Samuele Menicucci ◽

Sara Malavolti ◽

Andrea De Felice ◽

Iole Leonori

Keyword(s):

Food Web ◽

Food Webs ◽

Mediterranean Sea ◽

Environmental Variables ◽

Complex Structure ◽

Assemblage Structure ◽

Trophic Levels ◽

Ecosystem Functions ◽

Food Web Structure ◽

Adriatic Basin

Abstract. Zooplankton are critical to the functioning of ocean food webs because of their utter abundance and vital ecosystem roles. Zooplankton communities are highly diverse and thus perform a variety of ecosystem functions, thus changes in their community or food web structure may provide evidence of ecosystem alteration. Assemblage structure and trophodynamics of mesozooplantkon communities were examined across the Adriatic basin, the northernmost and most productive basin of the Mediterranean Sea. Samples were collected in June–July 2019 along coast-offshore transects covering the whole western Adriatic side, consistently environmental variables were also recorded. Results showed a clear separation between samples from the northern-central Adriatic and the southern ones, with a further segregation, although less clear, of inshore vs. off-shore stations, the latter mostly dominated in the central and southern stations by gelatinous plankton. Such patterns were mainly driven by chlorophyll-a concentration (as a proxy of primary production) for northern-central stations, i.e. closer to the Po river input, and by temperature and salinity, for southern ones, with the DistLM model explaining 46 % of total variance. The analysis of stable isotopes of nitrogen and carbon allowed to identify a complex food web characterized by 3 trophic levels from herbivores to carnivores, passing through the mixed feeding behavior of omnivores, shifting from phytoplankton/detritus ingestion to microzooplankton. Trophic structure also spatially varied according to sub-area, with the northern-central sub-areas differing from each other and from the southern stations. Our results highlighted the importance of environmental variables as drivers of zooplanktonic communities and the complex structure of their food webs. Disentangling and considering such complexity is crucial to generate realistic predictions on the functioning of aquatic ecosystems, especially in high productive and, at the same time, overexploited area such as the Adriatic Sea.

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‘Taking Fishers’ Knowledge to the Lab’: An Interdisciplinary Approach to Understand Fish Trophic Relationships in the Brazilian Amazon

Frontiers in Ecology and Evolution ◽

10.3389/fevo.2021.723026 ◽

2021 ◽

Vol 9 ◽

Author(s):

Paula Evelyn Rubira Pereyra ◽

Gustavo Hallwass ◽

Mark Poesch ◽

Renato Azevedo Matias Silvano

Keyword(s):

Stable Isotopes ◽

Food Webs ◽

Fish Species ◽

Trophic Interactions ◽

Brazilian Amazon ◽

Trophic Levels ◽

Trophic Relationships ◽

Ecological Knowledge ◽

Data Limitations ◽

Combining Data

Trophic levels can be applied to describe the ecological role of organisms in food webs and assess changes in ecosystems. Stable isotopes analysis can assist in the understanding of trophic interactions and use of food resources by aquatic organisms. The local ecological knowledge (LEK) of fishers can be an alternative to advance understanding about fish trophic interactions and to construct aquatic food webs, especially in regions lacking research capacity. The objectives of this study are: to calculate the trophic levels of six fish species important to fishing by combining data from stable isotopes analysis and fishers’ LEK in two clear water rivers (Tapajós and Tocantins) in the Brazilian Amazon; to compare the trophic levels of these fish between the two methods (stable isotopes analysis and LEK) and the two rivers; and to develop diagrams representing the trophic webs of the main fish prey and predators based on fisher’s LEK. The fish species studied were Pescada (Plagioscion squamosissimus), Tucunaré (Cichla pinima), Piranha (Serrasalmus rhombeus), Aracu (Leporinus fasciatus), Charuto (Hemiodus unimaculatus), and Jaraqui (Semaprochilodus spp.). A total of 98 interviews and 63 samples for stable isotopes analysis were carried out in both rivers. The average fish trophic levels did not differ between the stable isotopes analysis and the LEK in the Tapajós, nor in the Tocantins Rivers. The overall trophic level of the studied fish species obtained through the LEK did not differ from data obtained through the stable isotopes analysis in both rivers, except for the Aracu in the Tapajós River. The main food items consumed by the fish according to fishers’ LEK did agree with fish diets as described in the biological literature. Fishers provided useful information on fish predators and feeding habits of endangered species, such as river dolphin and river otter. Collaboration with fishers through LEK studies can be a viable approach to produce reliable data on fish trophic ecology to improve fisheries management and species conservation in tropical freshwater environments and other regions with data limitations.

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Soil microbial communities in microaggregates are less affected by top-down effects of collembolans than those in macroaggregates

10.5194/egusphere-egu21-10345 ◽

2021 ◽

Author(s):

Amandine Erktan ◽

MD Ekramul Haque ◽

Jérôme Cortet ◽

Paul Henning Krogh ◽

Stefan Scheu

Keyword(s):

Microbial Community ◽

Microbial Communities ◽

Community Composition ◽

Trophic Interactions ◽

Phospholipid Fatty Acid ◽

Microbial Community Composition ◽

Soil Microbial Communities ◽

Trophic Levels ◽

Soil Matrix ◽

Fungal Abundance

<p>Trophic regulation of microbial communities is receiving growing interest in soil ecology. Most studies investigated the effect of higher trophic levels on microbial communities at the bulk soil level. However, microbes are not equally accessible to consumers. They may be hidden in small pores and thus protected from consumers, suggesting that trophic regulation may depend on the localization of microbes within the soil matrix. As microaggregates (< 250 &#181;m) usually are more stable than macroaggregates (> 250 &#181;m) and embedded in the latter, we posit that they will be less affected by trophic regulations than larger aggregates. We quantified the effect of four contrasting species of collembolans (Ceratophysella denticulata, Protaphorura fimata, Folsomia candida, Sinella curviseta) on the microbial community composition in macro- (250 &#181;m &#8211; 2mm) and microaggregates (50 &#8211; 250 &#181;m). To do so, we re-built consumer-prey systems comprising remaining microbial background (post-autoclaving), fungal prey (Chaetomium globosum), and collembolan species (added as single species or combined). After three months, we quantified microbial community composition using phospholipid fatty acid markers (PLFAs). We found that the microbial communities in macroaggregates were more affected by the addition of collembolans than the communities in microaggregates. In particular, the fungal-to-bacterial (F:B) ratio significantly decreased in soil macroaggregates in the presence of collembolans. In the microaggregates, the F:B ratio remained lower and unaffected by collembolan inoculation. Presumably, fungal hyphae were more abundant in macroaggregates because they offered more habitat space for them, and the collembolans reduced fungal abundance because they consumed them. On the contrary, microaggregates presumably contained microbial communities protected from consumers. In addition, collembolans increased the formation of macroaggregates but did not influence their stability, despite their negative effect on fungal abundance, a well-known stabilizing agent. Overall, we show that trophic interactions between microbial communities and collembolans depend on the aggregate size class considered and, in return, soil macroaggregation is affected by these trophic interactions.</p>

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Tree diversity effects through a temporal lens: Implications for the abundance, diversity and stability of foraging birds

Journal of Animal Ecology ◽

10.1111/1365-2656.13245 ◽

2020 ◽

Vol 89 (8) ◽

pp. 1775-1787

Author(s):

Yanely May‐Uc ◽

Colleen S. Nell ◽

Víctor Parra‐Tabla ◽

Jorge Navarro ◽

Luis Abdala‐Roberts

Keyword(s):

Tree Diversity ◽

Diversity Effects

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Effects of genetic diversity of grass on insect species diversity at higher trophic levels are not due to cascading diversity effects

Oikos ◽

10.1111/j.1600-0706.2010.18957.x ◽

2011 ◽

Vol 120 (7) ◽

pp. 1031-1036 ◽

Cited By ~ 12

Author(s):

Thomas S. Jones ◽

Eric Allan ◽

Simone A. Härri ◽

Jochen Krauss ◽

Christine B. Müller ◽

...

Keyword(s):

Genetic Diversity ◽

Species Diversity ◽

Trophic Levels ◽

Insect Species ◽

Diversity Effects

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A tale of scale: Plot but not neighbourhood tree diversity increases leaf litter ant diversity

Journal of Animal Ecology ◽

10.1111/1365-2656.13115 ◽

2019 ◽

Vol 89 (2) ◽

pp. 299-308 ◽

Cited By ~ 3

Author(s):

Carl J. Skarbek ◽

Merle Noack ◽

Helge Bruelheide ◽

Werner Härdtle ◽

Goddert von Oheimb ◽

...

Keyword(s):

Leaf Litter ◽

Tree Diversity ◽

Ant Diversity

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Spatially mismatched trophic dynamics: cyclically outbreaking geometrids and their larval parasitoids

Biology Letters ◽

10.1098/rsbl.2009.1002 ◽

2010 ◽

Vol 6 (4) ◽

pp. 566-569 ◽

Cited By ~ 24

Author(s):

Snorre B. Hagen ◽

Jane U. Jepsen ◽

Tino Schott ◽

Rolf A. Ims

Keyword(s):

Trophic Interactions ◽

Travelling Waves ◽

Methodological Approach ◽

Spatial Dynamics ◽

Population Cycles ◽

Trophic Levels ◽

Trophic Dynamics ◽

Spatial Mismatch ◽

Larval Parasitoids ◽

Spatio Temporal

For trophic interactions to generate population cycles and complex spatio-temporal patterns, like travelling waves, the spatial dynamics must be matched across trophic levels. Here, we propose a spatial methodological approach for detecting such spatial match–mismatch and apply it to geometrid moths and their larval parasitoids in northern Norway, where outbreak cycles and travelling waves occur. We found clear evidence of spatial mismatch, suggesting that the spatially patterned moth cycles in this system are probably ruled by trophic interactions involving other agents than larval parasitoids.

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Genetics-based interactions of foundation species affect community diversity, stability and network structure

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2016.2703 ◽

2017 ◽

Vol 284 (1854) ◽

pp. 20162703 ◽

Cited By ~ 12

Author(s):

Arthur R. Keith ◽

Joseph K. Bailey ◽

Matthew K. Lau ◽

Thomas G. Whitham

Keyword(s):

Network Structure ◽

Experimental Manipulation ◽

Species Interaction ◽

Foundation Species ◽

Interaction Networks ◽

Community Diversity ◽

Arthropod Community ◽

Pemphigus Betae ◽

In The Wild ◽

The Stability

We examined the hypothesis that genetics-based interactions between strongly interacting foundation species, the tree Populus angustifolia and the aphid Pemphigus betae , affect arthropod community diversity, stability and species interaction networks of which little is known. In a 2-year experimental manipulation of the tree and its aphid herbivore four major findings emerged: (i) the interactions of these two species determined the composition of an arthropod community of 139 species; (ii) both tree genotype and aphid presence significantly predicted community diversity; (iii) the presence of aphids on genetically susceptible trees increased the stability of arthropod communities across years; and (iv) the experimental removal of aphids affected community network structure (network degree, modularity and tree genotype contribution to modularity). These findings demonstrate that the interactions of foundation species are genetically based, which in turn significantly contributes to community diversity, stability and species interaction networks. These experiments provide an important step in understanding the evolution of Darwin's ‘entangled bank’, a metaphor that characterizes the complexity and interconnectedness of communities in the wild.

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