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Expired projects
Flower-bacteria-pollinator interactions (FWF, Gerard)
Effects of flower bacteria on floral scent and pollination
The overall aim of this project is to improve our knowledge about the ecological functions of microorganisms related to plant-pollinator communication and pollination. Microorganisms such as bacteria and fungi grow on floral structures in considerable amounts and they have a great potential to affect some floral traits that play a relevant role in pollinator attraction. The specific objectives of this project are:
1) To measure the effects of bacterial microbiota on floral scents and on pollinator attraction to flowers.
2) To shed light on the processes and agents that affect the dispersal of bacteria among flowers.
PIs: Gerard Farré-Armengol, Robert R. Junker
funded by FWF
Functional Diversity (FWF, GG)
Functional responses of plant communities and plant-pollinator interactions to altitudinal gradients and climate change
The year 2014 was globally the warmest since records started and thus represents the (provisional) peak of the general trend of global warming that is expected to continue, which has severe negative effects on biodiversity and ecosystem processes. In order to understand the causes and predict or even mitigate consequences of these impacts, it is mandatory to study present patterns of biodiversity and to quantify ecological responses of communities to environmental changes such as increasing temperatures. Spatial gradients such as those along mountain slopes as well as re-visitations of sites where historical vegetation surveys had been conducted represent powerful long-term and large-scale study systems to estimate effects of climate change on ecosystems. The diversity, characteristics, distribution, and relative abundance of functional plant traits in communities reveal information on community assembly and ecosystem functioning. In contrast to vegetative and life-history traits, such information remains largely unknown for flower traits despite their essential roles for important ecological processes such as sexual reproduction of plants and pollinator diversity. In the proposed study, the advantages of the altitudinal gradient of the Austrian Alps as well as historical vegetation surveys will be exploited to fill that important gap. The plant species present in communities located between 1500 and 2600 m a.s.l. will be phenotyped by a large set of vegetative but most importantly floral functional traits including the morphology, phenology, scent emissions and color. Additionally, the phylogenetic composition of the communities as well as the flower-visitor interactions will be considered. This extensive and comprehensive dataset will allow testing hypotheses on community assembly, the link between functional plant diversity and flower visitor diversity, and the functional responses of plant communities and interaction patterns to altitude and climate change. The anticipated results and conclusions will therefore provide a novel perspective on community ecology and assembly with implications for climate change and the vulnerability of natural ecosystems and the conservation of the alpine flora and fauna.
PI: Robert R. Junker
Team: Martin Lechleitner
funded by FWF