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Browsing by Person "Sheppard, Christine"

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    From alien to native Asteraceae : how effects of climate, functional traits, and biotic interactions on population growth change with residence time
    (2023) Brendel, Marco; Sheppard, Christine
    Biological invasions pose a major threat to native biodiversity and even drive native species to extinction. It is thus of utmost importance to gain a better understanding of limits to population growth and spread of invasive plants. Invasion success in the introduced area is determined by the combined effects of climatic mismatches between the area of origin and the introduced area as well as biotic resistance of resident native communities. Alien plants can respond to environmental selection via changes in functional traits and thereby adapt to novel abiotic conditions. Native community species are expected to adapt to the presence of the invader by gaining eco-evolutionary experience and build-up biotic resistance over time. The aim of this thesis is to investigate interactions of alien plants with the novel abiotic and biotic environment in their introduced range over eco-evolutionary timescales. To this end, I conducted common garden experiments based on an alien-native species continuum to cover a broad range of residence times in Germany (7 to 12,000 years before present). I followed the population growth of 47 annual Asteraceae (including neophytes, archaeophytes, and natives) over two years and measured their performance in intra- and interspecific competition to answer the following questions: 1) How are effects of climatic distances between the area of origin and the introduced area as well as functional traits on population dynamics of alien plants determined by residence time? 2) How is biotic resistance of native communities towards alien plants related to residence time? 3) How are competitive outcomes between single alien and native plants shaped by residence time and serve as a predictor of range sizes? For the first question, I followed population growth of the Asteraceae in monocultures. I calculated climatic distances between the area of origin and the introduced area and measured functional traits in terms of seed mass, maximum height, and specific leaf area. Firstly, I tested whether negative effects of climatic distances on population growth weaken with residence time. Secondly, I investigated trait-demography relationships and tested if functional traits converge towards values that increase population growth. I found a strong effect of seed mass and no effects climatic distances on population growth. A strong negative relationship between seed mass and population growth resulted in directional selection of seed mass towards low values with increasing residence time. For the second question, I measured population growth of the Asteraceae in a Central European grassland community. I tested if competitive effects of the community on the Asteraceae increase with residence time (i.e. co-existence time with the native community). I used a second community native to North American grasslands that never co-existed with the Asteraceae to disentangle competitive effects related to eco-evolutionary experience of the native community from inherent competitive abilities of the Asteraceae. I compared trait-demography relationships in both community types with monocultures and found very similar competitive effects of both communities on the Asteraceae and thus no evidence for a build-up of competition-induced biotic resistance over time. Instead, invasion success was determined by a strong seed-mass-mediated trade-off between population growth in low- vs. high-competition. For the third question, I tested if the response of biomass and seed production of native targets to competition with alien and native neighbours depends on residence time. I tested if competitive effects differ between invasion status groups and explain species’ range sizes in Germany. I generally did not find a higher tolerance of native Asteraceae to competition of neighbouring aliens and natives with increasing residence time. Both established neophytes and natives showed similar competitive abilities and species’ range sizes were not influenced by competitive effects. The detected trait-demography relationships and related directional selection as a mechanism of adaptation to novel abiotic conditions improve the understanding of constraints on population growth and spread of invaders. The lack of interspecific competitive superiority as a determinant of range sizes might indicate that other mechanisms are more important for invasion success. The functional trade-off between population growth in low vs. high competition reveals that invaders that are likely to escape this trade-off should be of highest management concern. By the combination of experimental macroecology with approaches of functional and community ecology used in my study, I strongly advanced the understanding of mechanisms of limits to population growth and spread of alien plants and provide a fundamental basis for future research in invasion ecology.
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    The performance of and interactions between multiple co-occurring alien and native plant species
    (2023) Ferenc, Viktoria; Sheppard, Christine
    This thesis focuses on investigating species interactions in the context of alien species establishment, which poses severe threats to species, communities, and ecosystems due to climate change and globalization. The study emphasizes the need to understand the effects of multiple co-occurring alien species and their potential explanations, such as niche or fitness differences. The outcome of competition can also be influenced by priority effects, where earlier emerging species affect later emerging species in a given environment. Positive interactions, like facilitation, are often overlooked but play a significant role in species interactions. Legumes, known for their ability to fix atmospheric nitrogen, can facilitate alien species, leading to both severe negative effects on natives and reduced resource competition. The research conducted three common garden pot experiments to address various aspects of alien species interactions. The first experiment examined pairwise combinations of 20 alien annual plant species in Germany to identify the mechanisms driving these interactions. It tested the prevalence of competition versus facilitation and assessed the effectiveness of individual traits, hierarchical or absolute trait distances, multivariate trait or phylogenetic distance, and trait plasticity in explaining plant performance. Results indicated that while interspecific competition was more common, interspecific facilitation occurred in 24% of cases. Hierarchical trait distances provided better explanations for interactions than phylogenetic or multivariate trait distances. Accounting for trait plasticity did not necessarily improve plant performance predictions. Notably, taller individuals with lower specific leaf area than their alien neighbours exhibited increased biomass and seed production when growing together. The second experiment focused on interactions between five pairs of alien and native species. It evaluated the impact of growing with one or two alien neighbour species on native plants and manipulated the arrival time of alien or native neighbours. Generally, native species performed worse when surrounded by two alien species compared to one, although the effect varied among species. Both native and alien species experienced significant performance decreases when arriving second in the pot, while alien species tended to benefit more from early arrival. However, further studies are required to generalize these findings across multiple alien and native plants regarding neighbour species and arrival time responses. The third experiment delved into legume facilitation in more detail. It involved growing 30 annual Asteraceae species (neophytes, archaeophytes, and natives) in communities with or without legume presence. The study measured functional traits, fitness, and nitrogen characteristics to understand how legume presence affected Asteraceae fitness and the relationship between traits, nitrogen concentration, and fitness. Using the δ15N natural abundance method, the research explored whether facilitation mechanisms differed among native phytometer, neophyte, and archaeophyte Asteraceae. Specific leaf area negatively affected aboveground biomass and seed production, with a stronger effect in the absence of legumes. Nitrogen concentration was positively correlated with biomass but did not significantly increase seed production. The results suggested direct legume facilitation for the native grass phytometer Festuca rupicola when growing alongside archaeophytes but not neophytes. This indicated varied mechanisms of competition for nitrogen between natives and alien species of different residence times and deepened understanding of altered facilitative leguminous effects in the presence of alien species. Overall, this research demonstrates the application of community ecology concepts and theories to investigate alien species interactions, particularly when multiple co-occurring alien species are involved. As the rate of alien species arrival in new habitats continues to increase, understanding their combined impact on native species, communities, and ecosystems becomes increasingly crucial.