Riparian forests shape trophic interactions in detrital stream food webs
Data files
Jul 31, 2024 version files 1.01 MB
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dat.all.csv
84.89 KB
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dat.all.txt
106 KB
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dat.erg.csv
44.45 KB
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dat.erg.txt
57.77 KB
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dat.tot.csv
300.80 KB
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dat.tot.txt
410.92 KB
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README.md
2.82 KB
Abstract
Freshwater and terrestrial biodiversity are linked through spatial resource flows. Key examples are detrital subsidies from the riparian vegetation that form the base of food webs in small streams. Despite the central role of detritivores in these food webs, the consequences of altered riparian vegetation type and resource availability on their trophic strategies are less known. Therefore, we experimentally tested the direct and indirect effects of riparian vegetation type (i.e., riparian forests present vs. absent) on trophic interactions and dietary imbalances of aquatic detritivores. To characterize trophic strategies, we used stoichiometric and isotopic differences between consumers and resources as functional measures of trophic link strength in leaf litter bags naturally colonised by stream decomposers and detritivores. Our results show that an absence of riparian forests affected stoichiometric and isotopic properties in stream detrital food webs. Where local riparian forests were absent, leaf litter showed lower C:N ratios, which only trichopteran detritivores mirrored, whereas plecopteran and crustacean detritivores showed differences in their isotopic signatures. Diverging patterns between resources and consumers could lead to a rewiring of energy flow paths and weaken the coupling between aquatic detritivores and terrestrial detritus. Consequently, our findings demonstrate that riparian forests are essential for aquatic food webs by not only influencing organisms themselves but also their trophic interactions and energy flow paths. Aquatic detritivores depending on terrestrial subsidies can be highly sensitive to local changes in their resource environment. Therefore, functionally divergent patterns between resources and consumers in recipient systems highlight how habitat properties of the donor system can affect food webs connected across ecosystem boundaries.
https://doi.org/10.5061/dryad.8pk0p2nv9
Description of the data and file structure
The three datasets used for this study include identifiers, treatments, measurements of stoichiometry, and stable isotopes of leaf litter and macroinvertebrate consumers, as well as fungal biomass, and also some information on the local macroinvertebrate community composition.
dat.erg: Data on resources including fungal biomass, stoichiometry, and stable isotopes
dat.all: Data on resources and consumers (shredders), stoichiometry, and stable isotopes
dat.tot: Taxalist of all animals found in the experimental units
Identifiers:
- "Sample_ID": shared identifier
- "Site": study site identifier (combination between stream and vegetation)
- "Stream": stream site identifier (within each region, four streams)
- "Region": regional site identifier (two regions corresponding to the two Swiss cantons)
Treatments:
- "LeafLeafLeaf": leaf species
- "Vegetation": forested or non-forested riparian vegetation
- "MonoMix": one or two species of leaf litter in the experimental bags
- "Shredder": if the specimen is a shredder: "Y"; otherwise "N"
- "T": timepoint either "T0" (before stream incubation) or "sample" (after stream incubation)
- "Species_All_1": Taxon used
Values:
- "Delta13_C_VPDB_corr": d13C stable isotope values
- "Delta13_C_VPDB_corr_corr": d13C isotope values with correction factor
- "Delta15_C_Air_corr": d15N stable isotope values
- "log_molar_CN": C:N ratio as logged molar ratio values
- "EA_C_Percent_corr": %C values
- "EA_N_Percent_corr": %N values
- "Fungal_Biom_Leaf_mgg_noRR": fungal biomass per leaf in mg/g
Macroinvertebrate community:
- "Order": order-level identification
- "Family": family-level identification
- "Genus": genus-level identification (or sp.)
- "Species": species-level identification
- "Taxon": the lowest taxonomic level determined
- "Total": number of individuals per leaf litter bag
- "DryMass": average dry weight of this taxon in this leaf litter bag based on taxon-specific length-weight regressions in mg
- "TotalDryMass": the total dry mass of all these taxa in this leaf litter bag in mg
Sharing/Access information
Sample_ID in all three files is the common identifier linking the three data frames.
Please note that opening the data.all.txt file in Excel shifts the data so the last column does not have the correct header. CSV files with the correct format are included. Note that these are semicolon-delimited.
Code/Software
We performed all calculations and statistical analyses in R (version 4.1.2; R Development Core Team, 2020). All code that was used to analyze this data can be found on GitHub (link in Related Works section).
- Oester, Rebecca; Altermatt, Florian; Bruder, Andreas (2024), Riparian forests shape trophic interactions in detrital stream food webs, , Article, https://doi.org/10.5281/zenodo.10070138
- Oester, Rebecca; Altermatt, Florian; Bruder, Andreas (2024), Riparian forests shape trophic interactions in detrital stream food webs, , Article, https://doi.org/10.5281/zenodo.10070139
- Oester, Rebecca; Altermatt, Florian; Bruder, Andreas (2023), Riparian forests shape trophic interactions in detrital stream food webs, [], Posted-content, https://doi.org/10.1101/2023.10.31.564911
- Oester, Rebecca; Altermatt, Florian; Bruder, Andreas (2024), Riparian forests shape trophic interactions in detrital stream food webs, Functional Ecology, Journal-article, https://doi.org/10.1111/1365-2435.14639