Data from: Trophic niches of Collembola communities change with elevation but also with body size and life form

Name: Trophic niches of Collembola communities change with elevation but also with body size and life form
Creator: Johannes Lux

Lux, Johannes, University of Göttingen, https://orcid.org/0000-0002-6052-7678

johannesmichel.lux@uni-goettingen.de

Research facility: Johann Friedrich Blumenbach Institute for Zoology and Anthropology*

Published May 03, 2024 on Dryad. https://doi.org/10.5061/dryad.8pk0p2nt1

Cite this dataset

Lux, Johannes (2024). Data from: Trophic niches of Collembola communities change with elevation but also with body size and life form [Dataset]. Dryad. https://doi.org/10.5061/dryad.8pk0p2nt1

Abstract

Climate change increases habitat loss of endemic tree species and drives forest conversion in mountainous forests. Elevational gradients provide the opportunity to predict possible consequences of such changes. While species compositions of various taxa have been investigated along elevational gradients, data on trophic changes in soil-dwelling organisms is scarce. Here, we analyze trophic changes of the Collembola community along the northern slope of Changbai Mountain, China. We sampled seven elevations (800-1700 m asl) with 150 m elevational difference along a primary forest gradient. At eight subplots per elevation, we categorized Collembola species into life forms, measured individual body lengths and bulk stable isotopes. Mean and minimum Δ¹⁵N and mean Δ¹³C increased with increasing elevation, while the range of Δ¹⁵N decreased. Maximum and minimum of Δ¹³C differed between elevations but showed no linear response. Isotopic uniqueness increased with elevation. Δ¹⁵N values of Collembola species occurring across all elevations increased with elevation. Changes in Δ¹⁵N with elevation were most pronounced in hemiedaphic species. Δ¹⁵N values increased with decreasing body size in hemiedaphic and euedaphic species. Δ¹³C increased strongest with elevation in euedaphic species. Overall, the results suggest that Collembola species functioning as primary decomposers shift towards functioning as secondary decomposers at higher elevations. Further, access to alternative food resources may depend on Collembola life form and body size, this relationship, however, likely varies between ecosystems. Collembola functioning as secondary decomposers in coniferous forests may function as primary decomposers under climate driven forest conversion as species boundaries of tree species of lower elevations expand.

README: Data for the article "Trophic niches of Collembola communities change with elevation but also with body size and life form"

https://doi.org/10.5061/dryad.8pk0p2nt1

Description of the data and file structure

Creators: Johannes Lux, Zhijing Xie, Xin Sun, Donghui Wu, Stefan Scheu
Date of issue: 2023-04-18
Corresponding author: Johannes Lux
E-mail: johannesmichel.lux@uni-goettingen.de
Address: Untere Karspüle 2, Tierökologie, 37073 Göttingen, Lower Saxony, Germany

Funding: This work was supported by the National Natural Science Foundation of China (NSFC; No. 31861133006-42071059) and the German Science Foundation (DFG; SCHE/376/42-1) in the framework of the Sino-German agreement between the DFG and the NSFC.

Dataset Metadata:
Date of data collection: 09-2019
Sampling Location: The northern slope of Changbai Mountain (42°8’25.4004”N, 128°7’36.2352”E), Jilin Province, China
Laboratory work was conducted in the J.-F. Blumenbach Institute of Zoology and Anthropology, University of Göttingen, Göttingen, Germany
For details of sample handling and measurement please see the respective publication.

Filelist:

"Iso_metric_env_factors.CSV"
"Iso_BS.CSV"

Filename: "Iso_metric.CSV"
Variables:
elevation: sampled elevation
subplot: replicate (per elevation)
min_D13C: minimum weighted Delta 13C value [‰]
min_D15N: minimum weighted Delta 15N value [‰]
max_D13C: maximum weighted Delta 13C [‰]
max_D15N: maximum weighted Delta 15N [‰]
range_D13C: range of weighted Delta 13C values [‰]
range_D15N: range of weighted Delta 15N values [‰]
IPos_D13C: weighted mean Delta 13C values [‰]
IPos_D15N: weighted mean Delta 15N values [‰]
IRic: Isotopic richness, see Details [dimensionless]
IDiv: Isotopic divergence, see Details [dimensionless]
IDis: Isotopic dispersion, see Details [dimensionless]
IEve: Isotopic evenness, see Details [dimensionless]
IUni: Isotopic uniqueness, see Details [dimensionless]

Details:
Contains stable isotope metrics of the Collembola community at the northern slope of Changbai Mountain, Jilin, China. Values are calculated from raw data of "Iso_BS.CSV" as proposed by Cucherousset and Villéger (2015)[1]. NA indicate that values could not be calculated, due to insufficient number of species for calculating Isotopic metrics (three plots); These were excluded from analyses.

[1] Cucherousset J, Villéger S (2015) Quantifying the multiple facets of isotopic diversity: New metrics for stable isotope ecology. Ecological Indicators 56: 152-160 doi: https://doi.org/10.1016/j.ecolind.2015.03.032

Multidimensional Isotopic metrics:
Isotopic richness (IRic) representing the convex hull area spanning the total isotopic space of species; IRic was not weighted by abundance.

Isotopic divergence (IDiv) which approaches 1 if Collembola species with extreme diverging isotopic signatures are abundant and approaches 0 if they are rare.

Isotopic dispersion (IDis) which approaches 1 if abundant species have diverging isotopic signatures, whereas it approaches 0 if abundant species have similar isotopic signatures.

Isotopic evenness (IEve) which approaches 1 if species are evenly distributed in the isotopic space, whereas it approaches 0 if species cluster in a small area of the isotopic space.

Isotopic uniqueness (IUni) which approaches 1 if species occupy unique positions in the isotopic space, whereas it approaches 0 if species share similar isotopic niches.

This dataset represents The major results as reported in the Publication "Trophic niches of Collembola communities change with elevation but also with body size and life form". Data is calculated from raw data as presented in "Iso_BS.CSV"

---
Filename: "Iso_BS.CSV"
Variables:
elevation: sampled elevation
subplot: replicate (per elevation)
family: family of the respective Collembola species
species: Collembola species
genus: genus of the respective Collembola species
d15N: delta 15N measurements of Collembola [‰]
d13C: delta 13C measurements of Collembola [‰]
X15N: delta 15N measurements of litter material [‰]
X13C: delta 13C measurements of litter material [‰]
D15N: litter calibrated delta 15N of Collembola [‰]
D13C: litter calibrated delta 13C of Collembola [‰]
BS_mean:
abu_sub: abundance of species per subplot

Details:
Contains delta 13C and delta 15N values of Collembola bulk measurements, delta 13C and delta 15N measurements of intact litter material, as well as the normalised values expressed as capital Delta 13C and Delta 15N. Further it contains abundances of species per subplot as used for calculations of stable isotope metrics, reported in "Iso_metric.CSV". And mean body sizes of individuals of the respective isotope measurements. Delta values were calculated as (R sample - R standard)/(R standard)*1000. With R being the 15N/14N or 13C/12C ratio in the sample and standard.

"Vienna Pee Dee belemnite" was used as standard for 13C and atmospheric Nitrogen for 15N measurements.
The calculated delta values were calibrated using the delta values of litter from the respective elevation and subplot as baseline and are expressed as capital Delta. For details of measurement please see the respective publication.

This dataset represent the backbone of trophic analyses based on bulk stable isotopes in the respective publication.
This dataset is of interest for following up studies at Changbai Mountain China. Especially, if interested in the elevational gradient. Data is given per elevation, subplot and species.

Funding

Deutsche Forschungsgemeinschaft

National Natural Science Foundation of China