TY  - JOUR
A1  - Ehrlich, Elias
A1  - Kath, Nadja Jeanette
A1  - Gaedke, Ursula
T1  - The shape of a defense-growth trade-off governs seasonal trait dynamics in natural phytoplankton
JF  - The ISME journal
N2  - Theory predicts that trade-offs, quantifying costs of functional trait adjustments, crucially affect community trait adaptation to altered environmental conditions, but empirical verification is scarce. We evaluated trait dynamics (antipredator defense, maximum growth rate, and phosphate affinity) of a lake phytoplankton community in a seasonally changing environment, using literature trait data and 21 years of species-resolved high-frequency biomass measurements. The trait data indicated a concave defense-growth trade-off, promoting fast-growing species with intermediate defense. With seasonally increasing grazing pressure, the community shifted toward higher defense levels at the cost of lower growth rates along the trade-off curve, while phosphate affinity explained some deviations from it. We discuss how low fitness differences of species, inferred from model simulations, in concert with stabilizing mechanisms, e.g., arising from further trait dimensions, may lead to the observed phytoplankton diversity. In conclusion, quantifying trade-offs is key for predictions of community trait adaptation and biodiversity under environmental change.
KW  - coexistence
KW  - community ecology
KW  - diversity
KW  - evolution
KW  - fitness
KW  - functional traits
KW  - lake
KW  - maintenance
KW  - mechanisms
KW  - plankton
Y1  - 2020
U6  - https://doi.org/10.1038/s41396-020-0619-1
SN  - 1751-7362
SN  - 1751-7370
VL  - 14
IS  - 6
SP  - 1451
EP  - 1462
PB  - Nature Publishing Group
CY  - London
ER  - 
TY  - GEN
A1  - Ehrlich, Elias
A1  - Kath, Nadja Jeanette
A1  - Gaedke, Ursula
T1  - The shape of a defense-growth trade-off governs seasonal trait dynamics in natural phytoplankton
T2  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2  - Theory predicts that trade-offs, quantifying costs of functional trait adjustments, crucially affect community trait adaptation to altered environmental conditions, but empirical verification is scarce. We evaluated trait dynamics (antipredator defense, maximum growth rate, and phosphate affinity) of a lake phytoplankton community in a seasonally changing environment, using literature trait data and 21 years of species-resolved high-frequency biomass measurements. The trait data indicated a concave defense-growth trade-off, promoting fast-growing species with intermediate defense. With seasonally increasing grazing pressure, the community shifted toward higher defense levels at the cost of lower growth rates along the trade-off curve, while phosphate affinity explained some deviations from it. We discuss how low fitness differences of species, inferred from model simulations, in concert with stabilizing mechanisms, e.g., arising from further trait dimensions, may lead to the observed phytoplankton diversity. In conclusion, quantifying trade-offs is key for predictions of community trait adaptation and biodiversity under environmental change.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 1390 
KW  - functional traits
KW  - community ecology
KW  - evolution
KW  - lake
KW  - mechanisms
KW  - diversity
KW  - plankton
KW  - fitness
KW  - maintenance
KW  - coexistence
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-513956
SN  - 1866-8372
IS  - 6
ER  - 
TY  - JOUR
A1  - Kath, Nadja Jeanette
A1  - Gaedke, Ursula
A1  - van Velzen, Ellen
T1  - The double-edged sword of inducible defences: costs and benefits of maladaptive switching from the individual to the community level
JF  - Scientific Reports
N2  - Phenotypic plasticity can increase individual fitness when environmental conditions change over time. Inducible defences are a striking example, allowing species to react to fluctuating predation pressure by only expressing their costly defended phenotype under high predation risk. Previous theoretical investigations have focused on how this affects predator–prey dynamics, but the impact on competitive outcomes and broader community dynamics has received less attention. Here we use a small food web model, consisting of two competing plastic autotrophic species exploited by a shared consumer, to study how the speed of inducible defences across three trade-off constellations affects autotroph coexistence, biomasses across trophic levels, and temporal variability. Contrary to the intuitive idea that faster adaptation increases autotroph fitness, we found that higher switching rates reduced individual fitness as it consistently provoked more maladaptive switching towards undefended phenotypes under high predation pressure. This had an unexpected positive impact on the consumer, increasing consumer biomass and lowering total autotroph biomass. Additionally, maladaptive switching strongly reduced autotroph coexistence through an emerging source-sink dynamic between defended and undefended phenotypes. The striking impact of maladaptive switching on species and food web dynamics indicates that this mechanism may be of more critical importance than previously recognized.
Y1  - 2022
U6  - https://doi.org/10.1038/s41598-022-13895-7
SN  - 2045-2322
VL  - 12
SP  - 1
EP  - 14
PB  - Springer Nature
CY  - London
ER  - 
TY  - JOUR
A1  - Kath, Nadja Jeanette
A1  - Gaedke, Ursula
A1  - van Velzen, Ellen
T1  - The double-edged sword of inducible defences: costs and benefits of maladaptive switching from the individual to the community level
JF  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2  - Phenotypic plasticity can increase individual fitness when environmental conditions change over time. Inducible defences are a striking example, allowing species to react to fluctuating predation pressure by only expressing their costly defended phenotype under high predation risk. Previous theoretical investigations have focused on how this affects predator–prey dynamics, but the impact on competitive outcomes and broader community dynamics has received less attention. Here we use a small food web model, consisting of two competing plastic autotrophic species exploited by a shared consumer, to study how the speed of inducible defences across three trade-off constellations affects autotroph coexistence, biomasses across trophic levels, and temporal variability. Contrary to the intuitive idea that faster adaptation increases autotroph fitness, we found that higher switching rates reduced individual fitness as it consistently provoked more maladaptive switching towards undefended phenotypes under high predation pressure. This had an unexpected positive impact on the consumer, increasing consumer biomass and lowering total autotroph biomass. Additionally, maladaptive switching strongly reduced autotroph coexistence through an emerging source-sink dynamic between defended and undefended phenotypes. The striking impact of maladaptive switching on species and food web dynamics indicates that this mechanism may be of more critical importance than previously recognized.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 1288 
Y1  - 2022
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-572006
SN  - 1866-8372
IS  - 1288
ER  - 
TY  - THES
A1  - Kath, Nadja Jeanette
T1  - Functional traits determine biomass dynamics, coexistence and energetics in plankton food webs
N2  - Plankton food webs are the basis of marine and limnetic ecosystems. Especially aquatic ecosystems of high biodiversity provide important ecosystem services for humankind as providers of food, coastal protection, climate regulation, and tourism. Understanding the dynamics of biomass and coexistence in these food webs is a first step to understanding the ecosystems. It also lays the foundation for the development of management strategies for the maintenance of the marine and freshwater biodiversity despite anthropogenic influences.
Natural food webs are highly complex, and thus often equally complex methods are needed to analyse and understand them well. Models can help to do so as they depict simplified parts of reality. In the attempt to get a broader understanding of the complex food webs, diverse methods are used to investigate different questions.
In my first project, we compared the energetics of a food chain in two versions of an allometric trophic network model. In particular, we solved the problem of unrealistically high trophic transfer efficiencies (up to 70%) by accounting for both basal respiration and activity respiration, which decreased the trophic transfer efficiency to realistic values of ≤30%. Next in my second project I turned to plankton food webs and especially phytoplankton traits. Investigating a long-term data set from Lake Constance we found evidence for a trade-off between defence and growth rate in this natural phytoplankton community. I continued working with this data set in my third project focusing on ciliates, the main grazer of phytoplankton in spring. Boosted regression trees revealed that temperature and predators have the highest influence on net growth rates of ciliates. We finally investigated in my fourth project a food web model inspired by ciliates to explore the coexistence of plastic competitors and to study the new concept of maladaptive switching, which revealed some drawbacks of plasticity: faster adaptation led to higher maladaptive switching towards undefended phenotypes which reduced autotroph biomass and coexistence and increased consumer biomass.
It became obvious that even well-established models should be critically questioned as it is important not to forget reality on the way to a simplistic model. The results showed furthermore that long-term data sets are necessary as they can help to disentangle complex natural processes. Last, one should keep in mind that the interplay between models and experiments/ field data can deliver fruitful insights about our complex world.
N2  - Plankton-Nahrungsnetze sind die Grundlage mariner und limnischer Ökosysteme. Besonders die aquatischen Ökosysteme mit hoher Biodiversität erbringen wichtige Ökosystemdienstleistungen für uns Menschen wie beispielsweise die Bereitstellung von Nahrung, Küstenschutz, Klimaregulation sowie Tourismus. Die Dynamiken und die Koexistenz der Arten in diesen Ökosystemen zu verstehen, ist ein erster Schritt für die Entwicklung von Möglichkeiten zum Schutz ihrer Biodiversität.
Aufgrund der hohen Komplexität natürlicher Nahrungsnetze braucht es oft ebenso komplexe Methoden um sie zu analysieren und zu verstehen. Modelle können dabei unterstützen, da sie Teile der Realität vereinfacht abbilden. In meiner Dissertation arbeitete ich mit verschiedenen Nahrungsnetzmodellen, um die Dynamiken in Nahrungsnetzen zu verstehen.
In meinem ersten Projekt haben wir die Energieflüsse einer Nahrungskette in zwei Versionen eines allometrisch skalierten Nahrungsnetzmodells untersucht. Wenn nur die klassische basale Respiration einbezogen wird, steigt die trophische Transfereffizienz auf bis zu unrealistische 70 %. Durch die Einbeziehung der aktivitätsbezogenen Respiration sank die trophische Transfereffizienz auf realistische Werte von maximal 30 %. Danach wandte ich mich in meinem zweiten Projekt Plankton-Nahrungsnetzen und den Eigenschaften des Phytoplanktons zu. Bei der Untersuchung eines Langzeitdatensatzes von 21 Jahren aus dem Bodensee fanden wir einen Beweis für einen Trade-off zwischen Verteidigung und Wachstumsrate in einer natürlichen Phytoplankton-gemeinschaft. In diesem Datensatz konzentrierte ich mich anschließend in meinem dritten Projket auf Ciliaten, welche die wichtigsten Fraßfeinde von Phytoplankton im Frühjahr darstellen. Die Methode der boosted regression trees zeigte, dass Temperatur und Räuber den größten Einfluss auf die Nettowachstumsraten der Ciliaten haben. Schließlich nutzten wir in meinem vierten Projekt ein von Ciliaten inspiriertes Nahrungsnetzmodell, um die Koexistenz von Konkurrenten mit veränderlichen Eigenschaften und das neue Konzept des maladaptive switching zu untersuchen, welches Nachteile der Plastizität zeigt: höhere Wechselraten zwischen den Phänotypen führten zu höherem maladaptive switching in Richtung der unverteidigten Phänotypen, was die Biomasse und Koexistenz der Autotrophen reduziert und die Biomasse des Konsumenten erhöht.
Es wurde offensichtlich, dass auch etablierte Modelle kritisch hinterfragt werden müssen, da es wichtig ist, die Realität auf dem Weg zu einem einfachen Modell nicht zu vergessen. Meine Ergebnisse zeigten des Weiteren, wie wichtig Langzeitdatensätze sind, da sie helfen können, komplexe natürliche Prozesse zu beleuchten. Dieses Wechselspiel zwischen Modellen und Daten aus Experimenten oder Felduntersuchungen kann fruchtbare Ergebnisse liefern und zu einem größeren Verständnis unserer komplexen Welt beitragen.
KW  - functional traits
KW  - plankton food web
KW  - coexistence
KW  - modelling
KW  - Modellierung
KW  - Planktonnahrungsnetz
KW  - Koexistenz
Y1  - 2022
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-551239
ER  -