TY  - JOUR
A1  - Lozada Gobilard, Sissi Donna
A1  - Stang, Susanne
A1  - Pirhofer-Walzl, Karin
A1  - Kalettka, Thomas
A1  - Heinken, Thilo
A1  - Schröder, Boris
A1  - Eccard, Jana
A1  - Joshi, Jasmin Radha
T1  - Environmental filtering predicts plant-community trait distribution and diversity
BT  - Kettle holes as models of meta-community systems
JF  - Ecology and evolution
N2  - Meta-communities of habitat islands may be essential to maintain biodiversity in anthropogenic landscapes allowing rescue effects in local habitat patches. To understand the species-assembly mechanisms and dynamics of such ecosystems, it is important to test how local plant-community diversity and composition is affected by spatial isolation and hence by dispersal limitation and local environmental conditions acting as filters for local species sorting.We used a system of 46 small wetlands (kettle holes)natural small-scale freshwater habitats rarely considered in nature conservation policiesembedded in an intensively managed agricultural matrix in northern Germany. We compared two types of kettle holes with distinct topographies (flat-sloped, ephemeral, frequently plowed kettle holes vs. steep-sloped, more permanent ones) and determined 254 vascular plant species within these ecosystems, as well as plant functional traits and nearest neighbor distances to other kettle holes.Differences in alpha and beta diversity between steep permanent compared with ephemeral flat kettle holes were mainly explained by species sorting and niche processes and mass effect processes in ephemeral flat kettle holes. The plant-community composition as well as the community trait distribution in terms of life span, breeding system, dispersal ability, and longevity of seed banks significantly differed between the two habitat types. Flat ephemeral kettle holes held a higher percentage of non-perennial plants with a more persistent seed bank, less obligate outbreeders and more species with seed dispersal abilities via animal vectors compared with steep-sloped, more permanent kettle holes that had a higher percentage of wind-dispersed species. In the flat kettle holes, plant-species richness was negatively correlated with the degree of isolation, whereas no such pattern was found for the permanent kettle holes.Synthesis: Environment acts as filter shaping plant diversity (alpha and beta) and plant-community trait distribution between steep permanent compared with ephemeral flat kettle holes supporting species sorting and niche mechanisms as expected, but we identified a mass effect in ephemeral kettle holes only. Flat ephemeral kettle holes can be regarded as meta-ecosystems that strongly depend on seed dispersal and recruitment from a seed bank, whereas neighboring permanent kettle holes have a more stable local species diversity.
KW  - biodiversity
KW  - dispersal
KW  - disturbance
KW  - landscape diversity
KW  - life-history traits
KW  - plant diversity
KW  - seed bank
KW  - species assembly
KW  - wetland vegetation
Y1  - 2019
U6  - https://doi.org/10.1002/ece3.4883
SN  - 2045-7758
VL  - 9
IS  - 4
SP  - 1898
EP  - 1910
PB  - Wiley
CY  - Hoboken
ER  - 
TY  - GEN
A1  - Jeltsch, Florian
A1  - Grimm, Volker
A1  - Reeg, Jette
A1  - Schlägel, Ulrike E.
T1  - Give chance a chance
BT  - from coexistence to coviability in biodiversity theory
T2  - Postprints der Universität Potsdam Mathematisch-Naturwissenschaftliche Reihe
N2  - A large part of biodiversity theory is driven by the basic question of what allows species to coexist in spite of a confined number of niches. A substantial theoretical background to this question is provided by modern coexistence theory (MCT), which rests on mathematical approaches of invasion analysis to categorize underlying mechanisms into factors that reduce either niche overlap (stabilizing mechanisms) or the average fitness differences of species (equalizing mechanisms). While MCT has inspired biodiversity theory in the search for these underlying mechanisms, we feel that the strong focus on coexistence causes a bias toward the most abundant species and neglects the plethora of species that are less abundant and often show high local turnover. Given the more stochastic nature of their occurrence, we advocate a complementary cross-level approach that links individuals, small populations, and communities and explicitly takes into account (1) a more complete inclusion of environmental and demographic stochasticity affecting small populations, (2) intraspecific trait variation and behavioral plasticity, and (3) local heterogeneities, interactions, and feedbacks. Focusing on mechanisms that drive the temporary coviability of species rather than infinite coexistence, we suggest a new approach that could be dubbed coviability analysis (CVA). From a modeling perspective, CVA builds on the merged approaches of individual-based modeling and population viability analysis but extends them to the community level. From an empirical viewpoint, CVA calls for a stronger integration of spatiotemporal data on variability and noise, changing drivers, and interactions at the level of individuals. The resulting large volumes of data from multiple sources could be strongly supported by novel techniques tailored to the discovery of complex patterns in high-dimensional data. By complementing MCT through a stronger focus on the coviability of less common species, this approach can help make modern biodiversity theory more comprehensive, predictive, and relevant for applications.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 742 
KW  - behavioral plasticity
KW  - biodiversity
KW  - coexistence
KW  - community theory
KW  - coviability analysis
KW  - demographic noise
KW  - environmental noise
KW  - heterogeneity
KW  - individual-based modeling
KW  - intraspecific trait variation
KW  - modern coexistence theory
KW  - population viability analysis
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-435320
SN  - 1866-8372
IS  - 742
ER  - 
TY  - JOUR
A1  - Jeltsch, Florian
A1  - Grimm, Volker
A1  - Reeg, Jette
A1  - Schlägel, Ulrike E.
T1  - Give chance a chance
BT  - from coexistence to coviability in biodiversity theory
JF  - Ecosphere
N2  - A large part of biodiversity theory is driven by the basic question of what allows species to coexist in spite of a confined number of niches. A substantial theoretical background to this question is provided by modern coexistence theory (MCT), which rests on mathematical approaches of invasion analysis to categorize underlying mechanisms into factors that reduce either niche overlap (stabilizing mechanisms) or the average fitness differences of species (equalizing mechanisms). While MCT has inspired biodiversity theory in the search for these underlying mechanisms, we feel that the strong focus on coexistence causes a bias toward the most abundant species and neglects the plethora of species that are less abundant and often show high local turnover. Given the more stochastic nature of their occurrence, we advocate a complementary cross-level approach that links individuals, small populations, and communities and explicitly takes into account (1) a more complete inclusion of environmental and demographic stochasticity affecting small populations, (2) intraspecific trait variation and behavioral plasticity, and (3) local heterogeneities, interactions, and feedbacks. Focusing on mechanisms that drive the temporary coviability of species rather than infinite coexistence, we suggest a new approach that could be dubbed coviability analysis (CVA). From a modeling perspective, CVA builds on the merged approaches of individual-based modeling and population viability analysis but extends them to the community level. From an empirical viewpoint, CVA calls for a stronger integration of spatiotemporal data on variability and noise, changing drivers, and interactions at the level of individuals. The resulting large volumes of data from multiple sources could be strongly supported by novel techniques tailored to the discovery of complex patterns in high-dimensional data. By complementing MCT through a stronger focus on the coviability of less common species, this approach can help make modern biodiversity theory more comprehensive, predictive, and relevant for applications.
KW  - behavioral plasticity
KW  - biodiversity
KW  - coexistence
KW  - community theory
KW  - coviability analysis
KW  - demographic noise
KW  - environmental noise
KW  - heterogeneity
KW  - individual-based modeling
KW  - intraspecific trait variation
KW  - modern coexistence theory
KW  - population viability analysis
Y1  - 2019
U6  - https://doi.org/10.1002/ecs2.2700
SN  - 2150-8925
VL  - 10
IS  - 5
PB  - ESA
CY  - Ithaca, NY
ER  - 
TY  - THES
A1  - Teckentrup, Lisa
T1  - Understanding predator-prey interactions
T1  - Verstehen von Räuber-Beute-Interaktionen
BT  - the role of fear in structuring prey communities
BT  - die Rolle der Angst bei der Strukturierung von Beutetiergemeinschaften
N2  - Predators can have numerical and behavioral effects on prey animals. While numerical effects are well explored, the impact of behavioral effects is unclear. Furthermore, behavioral effects are generally either analyzed with a focus on single individuals or with a focus on consequences for other trophic levels. Thereby, the impact of fear on the level of prey communities is overlooked, despite potential consequences for conservation and nature management. In order to improve our understanding of predator-prey interactions, an assessment of the consequences of fear in shaping prey community structures is crucial.

In this thesis, I evaluated how fear alters prey space use, community structure and composition, focusing on terrestrial mammals. By integrating landscapes of fear in an existing individual-based and spatially-explicit model, I simulated community assembly of prey animals via individual home range formation. The model comprises multiple hierarchical levels from individual home range behavior to patterns of prey community structure and composition. The mechanistic approach of the model allowed for the identiﬁcation of underlying mechanism driving prey community responses under fear.

My results show that fear modiﬁed prey space use and community patterns. Under fear, prey animals shifted their home ranges towards safer areas of the landscape. Furthermore, fear decreased the total biomass and the diversity of the prey community and reinforced shifts in community composition towards smaller animals. These effects could be mediated by an increasing availability of refuges in the landscape. Under landscape changes, such as habitat loss and fragmentation, fear intensiﬁed negative effects on prey communities. Prey communities in risky environments were subject to a non-proportional diversity loss of up to 30% if fear was taken into account. Regarding habitat properties, I found that well-connected, large safe patches can reduce the negative consequences of habitat loss and fragmentation on prey communities. Including variation in risk perception between prey animals had consequences on prey space use. Animals with a high risk perception predominantly used safe areas of the landscape, while animals with a low risk perception preferred areas with a high food availability. On the community level, prey diversity was higher in heterogeneous landscapes of fear if individuals varied in their risk perception compared to scenarios in which all individuals had the same risk perception.

Overall, my ﬁndings give a ﬁrst, comprehensive assessment of the role of fear in shaping prey communities. The linkage between individual home range behavior and patterns at the community level allows for a mechanistic understanding of the underlying processes. My results underline the importance of the structure of the landscape of fear as a key driver of prey community responses, especially if the habitat is threatened by landscape changes. Furthermore, I show that individual landscapes of fear can improve our understanding of the consequences of trait variation on community structures. Regarding conservation and nature management, my results support calls for modern conservation approaches that go beyond single species and address the protection of biotic interactions.
N2  - Raubtiere beeinﬂussen ihre Beute durch die Verringerung der Anzahl (numerische Effekte) und durch das Hervorrufen von Verhaltensänderungen (Verhaltenseffekte). Während die Auswirkungen von numerischen Effekten gut erforscht sind, sind die Auswirkungen von Verhaltenseffekten unklar. Außerdem werden bei Verhaltensänderungen selten die Auswirkungen auf die Beutetiergemeinschaft betrachtet, sondern nur die Effekte auf einzelne Individuen bzw. Arten oder auf andere Stufen der Nahrungskette. Eine Betrachtung auf der Stufe der Beutetiergemeinschaft ist jedoch sehr wichtig, da nur so ein umfassendes Verständnis von Räuber-Beute-Gemeinschaften möglich ist.

In der vorliegenden Arbeit habe ich die Auswirkungen von Verhaltenseffekten auf die Raumnutzung und die Struktur von Beutetiergemeinschaften untersucht. Dazu habe ich ein räumliches Modell benutzt, welches die Bildung von Beutetiergemeinschaften über den individuellen Aufbau von Aktionsräumen der Beutetiere simuliert. Die Einrichtung von Aktionsräumen basiert dabei auf der Nahrungsverfügbarkeit in der Landschaft und auf dem vom Beutetier wahrgenommenen Risiko von einem Räuber gefressen zu werden. Die räumliche Verteilung des wahrgenommenen Risikos wird auch als Landschaft der Angst bezeichnet.

Meine Ergebnisse zeigen, dass sich die Raumnutzung und die Struktur der Beutetiergemeinschaft durch Verhaltenseffekte verändern. Unter dem Einﬂuss von Angst haben die Beutetiere ihre Aktionsräume in sicherere Bereiche der Landschaft verlegt. Außerdem hat sich in risikoreichen Landschaften die Vielfalt der Beutetiere verringert und die Zusammensetzung zu Arten mit einem geringen Körpergewicht verschoben. Wenn die Beutetiergemeinschaft Landschaftsveränderungen wie z.B. dem Verlust oder der Zerschneidung von Lebensraum ausgesetzt war, haben sich die Auswirkungen von Verhaltenseffekten weiter verstärkt. Durch eine Erhöhung der Größe und Anzahl von Rückzugsräumen, die nicht von Räubern erreicht werden können, sowie deren Verbindung in der Landschaft, kann die Stärke dieser Effekte jedoch begrenzt werden. In einem weiteren Schritt habe ich die Auswirkungen von Unterschieden in der Risikowahrnehmung zwischen Individuen untersucht. Diese Unterschiede haben dazu geführt, dass Tiere mit einer hohen Risikowahrnehmung sich ihren Aktionsraum vornehmlich in sicheren Bereichen gesucht haben, während Tiere mit einer geringen Risikowahrnehmung Bereiche mit einer hohen Nahrungsverfügbarkeit genutzt haben. Dadurch konnten sich in Landschaften mit unterschiedlichen Risiken, vielfältigere Beutetiergemeinschaften etablieren, als in Landschaften mit gleichmäßigem Risiko.

Insgesamt geben meine Ergebnisse einen guten Überblick über die Auswirkungen von Verhaltenseffekten auf Beutetiergemeinschaften. Die Verknüpfung von individuellem Verhalten mit Mustern auf der Gemeinschaftsebene erlaubt es die zugrundeliegenden Mechanismen zu identiﬁzieren und zu verstehen. In Bezug auf den Naturschutz unterstützen meine Ergebnisse den Ruf nach modernen Schutzmaßnahmen, die über den Erhalt von einzelnen Arten hinausgehen und den Schutz von Beziehungen zwischen Arten einbeziehen.
KW  - ecology
KW  - landscape of fear
KW  - predator-prey
KW  - movement
KW  - biodiversity
KW  - Ökologie
KW  - Landschaft der Angst
KW  - Räuber-Beute
KW  - Bewegung
KW  - Biodiversität
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-431624
ER  - 
TY  - THES
A1  - Raatz, Michael
T1  - Strategies within predator-prey interactions – from individuals to ecosystems
T1  - Strategien in Räuber-Beute Interaktionen – vom Individuum bis zum Ökosystem
N2  - Predator-prey interactions provide central links in food webs. These interaction are directly or indirectly impacted by a number of factors. These factors range from physiological characteristics of individual organisms, over specifics of their interaction to impacts of the environment. They may generate the potential for the application of different strategies by predators and prey. Within this thesis, I modelled predator-prey interactions and investigated a broad range of different factors driving the application of certain strategies, that affect the individuals or their populations. In doing so, I focused on phytoplankton-zooplankton systems as established model systems of predator-prey interactions.

At the level of predator physiology I proposed, and partly confirmed, adaptations to fluctuating availability of co-limiting nutrients as beneficial strategies. These may allow to store ingested nutrients or to regulate the effort put into nutrient assimilation. We found that these two strategies are beneficial at different fluctuation frequencies of the nutrients, but may positively interact at intermediate frequencies. The corresponding experiments supported our model results. We found that the temporal structure of nutrient fluctuations indeed has strong effects on the juvenile somatic growth rate of {\itshape Daphnia}. 

Predator colimitation by energy and essential biochemical nutrients gave rise to another physiological strategy. High-quality prey species may render themselves indispensable in a scenario of predator-mediated coexistence by being the only source of essential biochemical nutrients, such as cholesterol. Thereby, the high-quality prey may even compensate for a lacking defense and ensure its persistence in competition with other more defended prey species. 

We found a similar effect in a model where algae and bacteria compete for nutrients. Now, being the only source of a compound that is required by the competitor (bacteria) prevented the competitive exclusion of the algae. In this case, the essential compounds were the organic carbon provided by the algae. Here again, being indispensable served as a prey strategy that ensured its coexistence. 

The latter scenario also gave rise to the application of the two metabolic strategies of autotrophy and heterotrophy by algae and bacteria, respectively. We found that their coexistence allowed the recycling of resources in a microbial loop that would otherwise be lost. Instead, these resources were made available to higher trophic levels, increasing the trophic transfer efficiency in food webs.

The predation process comprises the next higher level of factors shaping the predator-prey interaction, besides these factors that originated from the functioning or composition of individuals. Here, I focused on defensive mechanisms and investigated multiple scenarios of static or adaptive combinations of prey defense and predator offense. I confirmed and extended earlier reports on the coexistence-promoting effects of partially lower palatability of the prey community. When bacteria and algae are coexisting, a higher palatability of bacteria may increase the average predator biomass, with the side effect of making the population dynamics more regular. This may facilitate experimental investigations and interpretations. If defense and offense are adaptive, this allows organisms to maximize their growth rate. Besides this fitness-enhancing effect, I found that co-adaptation may provide the predator-prey system with the flexibility to buffer external perturbations.

On top of these rather internal factors, environmental drivers also affect predator-prey interactions. I showed that environmental nutrient fluctuations may create a spatio-temporal resource heterogeneity that selects for different predator strategies. I hypothesized that this might favour either storage or acclimation specialists, depending on the frequency of the environmental fluctuations.

We found that many of these factors promote the coexistence of different strategies and may therefore support and sustain biodiversity. Thus, they might be relevant for the maintenance of crucial ecosystem functions that also affect us humans. Besides this, the richness of factors that impact predator-prey interactions might explain why so many species, especially in the planktonic regime, are able to coexist.
N2  - Organismen interagieren miteinander und mit ihrer Umwelt. Innerhalb dieses Netzwerks von Interaktionen sind Fraßbeziehungen zwischen Räubern und ihrer Beute von zentraler Bedeutung. Sie werden auf verschiedenen Ebenen von unterschiedlichen Faktoren beeinflusst, was zur Ausprägung von diversen Strategien von Räuber oder Beute führen kann. Diese Faktoren und die Strategien die sie hervor bringen sind Gegenstand dieser Doktorarbeit. In mehreren Modellierungsstudien habe ich vielseitige Faktoren untersucht, die sich dem Aufbau einzelner Organismen, Verteidigungs- und Angriffsmechanismen sowie Umwelteinflüssen zuordnen lassen. Dabei konzentrierte ich mich auf ein etabliertes Modellsystem zur Erforschung von Räuber-Beute-Dynamiken und untersuchte die Fraßbeziehung zwischen Phytoplankton als Beute und Zooplankton als Räuber. Ich fand heraus, dass die Bereitstellung von essentiellen Ressourcen für Konkurrenten oder Räuber eine Strategie sein kann, mit der Beutearten sich vor dem Aussterben schützen können. Auch die direkte Verteidigung gegen den Räuber ist eine häufige Strategie zur Verringerung des Fraßdrucks und kann ebenfalls Koexistenz fördern. Für anpassungsfähige Verteidigung der Beute und Angriffsstärke des Räubers konnte ich zeigen, dass dies sowohl die Fitness erhöhen, als auch die Robustheit der Räuber-Beute-Dynamiken gegen äußere Störungen erhöhen kann. Weiterhin fand ich heraus, dass physiologische Anpassungsmechanismen wie Speicherung oder anpassungsfähige Aufnahme von Nährstoffen die Wachstumsrate des Räubers verbessern können, wenn die Qualität der verfügbaren Beute in der Umwelt des Räubers fluktuiert. Viele der Strategien, die ich in dieser Arbeit herausgestellt habe, können die Koexistenz von verschiedenen Arten fördern und damit zu erhöhter Biodiversität beitragen, welche wiederum entscheidend ist für die Stabilität von Ökosystemen und deren Nutzbarkeit.
KW  - predator-prey
KW  - biodiversity
KW  - modelling
KW  - Räuber-Beute
KW  - Biodiversität
KW  - Modellierung
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-426587
ER  - 
TY  - GEN
A1  - Lozada Gobilard, Sissi Donna
A1  - Stang, Susanne
A1  - Pirhofer-Walzl, Karin
A1  - Kalettka, Thomas
A1  - Heinken, Thilo
A1  - Schröder, Boris
A1  - Eccard, Jana
A1  - Jasmin Radha, Jasmin
T1  - Environmental filtering predicts plant‐community trait  distribution and diversity
BT  - Kettle holes as models of meta‐community systems
T2  - Postprints der Universität Potsdam Mathematisch-Naturwissenschaftliche Reihe
N2  - Meta‐communities of habitat islands may be essential to maintain biodiversity in anthropogenic landscapes allowing rescue effects in  local habitat patches. To understand the species‐assembly mechanisms  and dynamics of such ecosystems, it is important to  test how local plant‐community diversity and composition is affected by spatial isolation and hence by dispersal limitation and local environmental conditions acting as filters for local species sorting. We used a system of 46 small wetlands (kettle holes)—natural small‐scale freshwater habitats rarely considered in  nature conservation policies—embedded in an  intensively managed agricultural matrix in northern Germany. We compared two types of kettle holes with distinct topographies (flatsloped, ephemeral, frequently plowed kettle holes vs. steep‐sloped, more permanent ones) and determined 254 vascular plant species within these ecosystems, as well as plant functional traits and nearest neighbor distances to other kettle holes. Differences in alpha and beta diversity between steep permanent compared with ephemeral flat kettle holes were mainly explained by species sorting and niche processes and mass effect processes in ephemeral flat kettle holes. The plant‐community composition as well as the community trait distribution in terms of life span, breeding system, dispersal ability, and longevity of seed banks significantly differed between the two habitat types. Flat ephemeral kettle holes held a higher percentage of non‐perennial plants with a more persistent seed bank, less obligate outbreeders and more species with seed dispersal abilities via animal vectors compared with steep‐sloped, more permanent kettle holes that had a higher percentage of wind‐dispersed species. In the flat kettle holes, plant‐species richness was negatively correlated with the degree of isolation, whereas no such pattern was found for the permanent kettle holes. Synthesis: Environment acts as filter shaping plant diversity (alpha and beta) and plant‐community trait distribution between steep permanent compared with ephemeral flat kettle holes supporting species sorting and niche mechanisms as expected, but we identified a mass effect in ephemeral kettle holes only. Flat ephemeral kettle holes can be regarded as meta‐ecosystems that strongly depend on seed dispersal and recruitment from a seed bank, whereas neighboring permanent kettle holes have a more stable local species diversity.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 629 
KW  - biodiversity
KW  - dispersal
KW  - disturbance
KW  - landscape diversity
KW  - life‐history traits
KW  - plant diversity
KW  - seed bank
KW  - species assembly
KW  - wetland vegetation
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-424843
SN  - 1866-8372
IS  - 629
ER  - 
TY  - JOUR
A1  - Lozada Gobilard, Sissi Donna
A1  - Stang, Susanne
A1  - Pirhofer-Walzl, Karin
A1  - Kalettka, Thomas
A1  - Heinken, Thilo
A1  - Schröder, Boris
A1  - Eccard, Jana
A1  - Jasmin Radha, Jasmin
T1  - Environmental filtering predicts plant‐community trait distribution and diversity
BT  - Kettle holes as models of meta‐community systems
JF  - Ecology and Evolution
N2  - Meta‐communities of habitat islands may be essential to maintain biodiversity in anthropogenic landscapes allowing rescue effects in  local habitat patches. To understand the species‐assembly mechanisms  and dynamics of such ecosystems, it is important to  test how local plant‐community diversity and composition is affected by spatial isolation and hence by dispersal limitation and local environmental conditions acting as filters for local species sorting. We used a system of 46 small wetlands (kettle holes)—natural small‐scale freshwater habitats rarely considered in  nature conservation policies—embedded in an  intensively managed agricultural matrix in northern Germany. We compared two types of kettle holes with distinct topographies (flatsloped, ephemeral, frequently plowed kettle holes vs. steep‐sloped, more permanent ones) and determined 254 vascular plant species within these ecosystems, as well as plant functional traits and nearest neighbor distances to other kettle holes. Differences in alpha and beta diversity between steep permanent compared with ephemeral flat kettle holes were mainly explained by species sorting and niche processes and mass effect processes in ephemeral flat kettle holes. The plant‐community composition as well as the community trait distribution in terms of life span, breeding system, dispersal ability, and longevity of seed banks significantly differed between the two habitat types. Flat ephemeral kettle holes held a higher percentage of non‐perennial plants with a more persistent seed bank, less obligate outbreeders and more species with seed dispersal abilities via animal vectors compared with steep‐sloped, more permanent kettle holes that had a higher percentage of wind‐dispersed species. In the flat kettle holes, plant‐species richness was negatively correlated with the degree of isolation, whereas no such pattern was found for the permanent kettle holes. Synthesis: Environment acts as filter shaping plant diversity (alpha and beta) and plant‐community trait distribution between steep permanent compared with ephemeral flat kettle holes supporting species sorting and niche mechanisms as expected, but we identified a mass effect in ephemeral kettle holes only. Flat ephemeral kettle holes can be regarded as meta‐ecosystems that strongly depend on seed dispersal and recruitment from a seed bank, whereas neighboring permanent kettle holes have a more stable local species diversity.
KW  - biodiversity
KW  - dispersal
KW  - disturbance
KW  - landscape diversity
KW  - life‐history traits
KW  - plant diversity
KW  - seed bank
KW  - species assembly
KW  - wetland vegetation
Y1  - 2019
U6  - https://doi.org/10.1002/ece3.4883
SN  - 2045-7758
PB  - John Wiley & Sons, Inc.
CY  - Hoboken
ER  -