TY  - JOUR
A1  - Kath, Nadja J.
A1  - Boit, Alice
A1  - Guill, Christian
A1  - Gaedke, Ursula
T1  - Accounting for activity respiration results in realistic trophic transfer efficiencies in allometric trophic network (ATN) models
JF  - Theoretical ecology
N2  - Allometric trophic network (ATN) models offer high flexibility and scalability while minimizing the number of parameters and have been successfully applied to investigate complex food web dynamics and their influence on food web diversity and stability. However, the realism of ATN model energetics has never been assessed in detail, despite their critical influence on dynamic biomass and production patterns. Here, we compare the energetics of the currently established original ATN model, considering only biomass-dependent basal respiration, to an extended ATN model version, considering both basal and assimilation-dependent activity respiration. The latter is crucial in particular for unicellular and invertebrate organisms which dominate the metabolism of pelagic and soil food webs. Based on metabolic scaling laws, we show that the extended ATN version reflects the energy transfer through a chain of four trophic levels of unicellular and invertebrate organisms more realistically than the original ATN version. Depending on the strength of top-down control, the original ATN model yields trophic transfer efficiencies up to 71% at either the third or the fourth trophic level, which considerably exceeds any realistic values. In contrast, the extended ATN version yields realistic trophic transfer efficiencies 30% at all trophic levels, in accordance with both physiological considerations and empirical evidence from pelagic systems. Our results imply that accounting for activity respiration is essential for consistently implementing the metabolic theory of ecology in ATN models and for improving their quantitative predictions, which makes them more powerful tools for investigating the dynamics of complex natural communities.
KW  - Food web
KW  - Trophic transfer efficiency
KW  - Allometric trophic network model
KW  - Allometry
KW  - Energy transfer
KW  - Activity respiration
Y1  - 2018
U6  - https://doi.org/10.1007/s12080-018-0378-z
SN  - 1874-1738
SN  - 1874-1746
VL  - 11
IS  - 4
SP  - 453
EP  - 463
PB  - Springer
CY  - Heidelberg
ER  - 
TY  - GEN
A1  - Ceulemans, Ruben
A1  - Gaedke, Ursula
A1  - Klauschies, Toni
A1  - Guill, Christian
T1  - The effects of functional diversity on biomass production, variability, and resilience of ecosystem functions in a tritrophic system
T2  - Postprints der Universität Potsdam Mathematisch-Naturwissenschaftliche Reihe
N2  - Diverse communities can adjust their trait composition to altered environmental conditions, which may strongly influence their dynamics. Previous studies of trait-based models mainly considered only one or two trophic levels, whereas most natural system are at least tritrophic. Therefore, we investigated how the addition of trait variation to each trophic level influences population and community dynamics in a tritrophic model. Examining the phase relationships between species of adjacent trophic levels informs about the strength of top-down or bottom-up control in non-steadystate situations. Phase relationships within a trophic level highlight compensatory dynamical patterns between functionally different species, which are responsible for dampening the community temporal variability. Furthermore, even without trait variation, our tritrophic model always exhibits regions with two alternative states with either weak or strong nutrient exploitation, and correspondingly low or high biomass production at the top level. However, adding trait variation increased the basin of attraction of the high-production state, and decreased the likelihood of a critical transition from the high- to the lowproduction state with no apparent early warning signals. Hence, our study shows that trait variation enhances resource use efficiency, production, stability, and resilience of entire food webs.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 744 
KW  - early-warning signals
KW  - top-down control
KW  - community ecology
KW  - regime shifts
KW  - food webs
KW  - compensatory dynamics
KW  - consumer diversity
KW  - metabolic theory
KW  - rapid evolution
KW  - stable states
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-435439
SN  - 1866-8372
IS  - 744
ER  - 
TY  - JOUR
A1  - Ceulemans, Ruben
A1  - Guill, Christian
A1  - Gaedke, Ursula
T1  - Top predators govern multitrophic diversity effects in tritrophic food webs
JF  - Ecology : a publication of the Ecological Society of America
N2  - It is well known that functional diversity strongly affects ecosystem functioning. However, even in rather simple model communities consisting of only two or, at best, three trophic levels, the relationship between multitrophic functional diversity and ecosystem functioning appears difficult to generalize, because of its high contextuality. In this study, we considered several differently structured tritrophic food webs, in which the amount of functional diversity was varied independently on each trophic level. To achieve generalizable results, largely independent of parametrization, we examined the outcomes of 128,000 parameter combinations sampled from ecologically plausible intervals, with each tested for 200 randomly sampled initial conditions. Analysis of our data was done by training a random forest model. This method enables the identification of complex patterns in the data through partial dependence graphs, and the comparison of the relative influence of model parameters, including the degree of diversity, on food-web properties. We found that bottom-up and top-down effects cascade simultaneously throughout the food web, intimately linking the effects of functional diversity of any trophic level to the amount of diversity of other trophic levels, which may explain the difficulty in unifying results from previous studies. Strikingly, only with high diversity throughout the whole food web, different interactions synergize to ensure efficient exploitation of the available nutrients and efficient biomass transfer to higher trophic levels, ultimately leading to a high biomass and production on the top level. The temporal variation of biomass showed a more complex pattern with increasing multitrophic diversity: while the system initially became less variable, eventually the temporal variation rose again because of the increasingly complex dynamical patterns. Importantly, top predator diversity and food-web parameters affecting the top trophic level were of highest importance to determine the biomass and temporal variability of any trophic level. Overall, our study reveals that the mechanisms by which diversity influences ecosystem functioning are affected by every part of the food web, hampering the extrapolation of insights from simple monotrophic or bitrophic systems to complex natural food webs.
KW  - food-web efficiency
KW  - functional diversity
KW  - machine learning
KW  - nutrient
KW  - exploitation
KW  - production
KW  - random forest
KW  - temporal variability
KW  - top
KW  - predator
KW  - trait diversity
Y1  - 2021
U6  - https://doi.org/10.1002/ecy.3379
SN  - 0012-9658
SN  - 1939-9170
VL  - 102
IS  - 7
PB  - Wiley
CY  - Hoboken
ER  - 
TY  - JOUR
A1  - Ceulemans, Ruben
A1  - Gaedke, Ursula
A1  - Klauschies, Toni
A1  - Guill, Christian
T1  - The effects of functional diversity on biomass production, variability, and resilience of ecosystem functions in a tritrophic system
JF  - Scientific Reports
N2  - Diverse communities can adjust their trait composition to altered environmental conditions, which may strongly influence their dynamics. Previous studies of trait-based models mainly considered only one or two trophic levels, whereas most natural system are at least tritrophic. Therefore, we investigated how the addition of trait variation to each trophic level influences population and community dynamics in a tritrophic model. Examining the phase relationships between species of adjacent trophic levels informs about the strength of top-down or bottom-up control in non-steadystate situations. Phase relationships within a trophic level highlight compensatory dynamical patterns between functionally different species, which are responsible for dampening the community temporal variability. Furthermore, even without trait variation, our tritrophic model always exhibits regions with two alternative states with either weak or strong nutrient exploitation, and correspondingly low or high biomass production at the top level. However, adding trait variation increased the basin of attraction of the high-production state, and decreased the likelihood of a critical transition from the high- to the lowproduction state with no apparent early warning signals. Hence, our study shows that trait variation enhances resource use efficiency, production, stability, and resilience of entire food webs.
KW  - early-warning signals
KW  - top-down control
KW  - community ecology
KW  - regime shifts
KW  - food webs
KW  - compensatory dynamics
KW  - consumer diversity
KW  - metabolic theory
KW  - rapid evolution
KW  - stable states
Y1  - 2019
U6  - https://doi.org/10.1038/s41598-019-43974-1
SN  - 2045-2322
VL  - 9
PB  - Macmillan Publishers Limited
CY  - London
ER  -