Research groups of the Organismal and Evolutionary Biology Research Programme
Below are the introductions of the research groups that operate partly or wholly at the research programme in alphabetical order.
Ancient genes of North-Eastern Europe
The SUGRIGE project aims at getting a whole-genome picture of ancient and contemporary Finns and Finno-Ugrians. We sequence ancient human remains from the regions where Finno-Ugrians live or used to live, in collaboration with Max Planck Institute for the Science of human history, Jena.
Canopy Spectral Ecology and Ecophysiology
CanSEE studies how plants respond to changes in spectral composition, how these cues are processed and received by leaves and by the whole plant. We place this research in context, considering how the spectral irradiance perceived by plants changes depending on their environment.
Global Change and Conservation
The Global Change and Conservation lab conducts research covering ecological and social aspects of conservation. We investigate conservation successes and failures, and assess conservation strategies. With an interdisciplinary approach we focus on policy relevant science of societal impact.
Life-History Evolution research group focuses on understanding how organisms cope with environmental variation in nature, such as habitat fragmentation or environmental stress. Our main study system is the Glanville fritillary butterfly (Melitaea cinxia) metapopulation in the Åland Islands.
Research in this group is directed to oxidative stress tolerance of plants and to lignin biosynthesis in xylem of trees.
Parasitoid Ecology Group
We study the behavioral ecology, population and community ecology of interacting species in fragmented landscapes. We mainly use the biotic community associated with the Glanville fritillary butterfly in Finland.
Research on snow and winter ecology in northern ecosystems.
Our research focus is to understand the function of receptor proteins, specifically receptor-like protein kinases, and their role in mediating the effects of reactive oxygen species (ROS).
Plant Stress Natural Variation
Plant growth is limited by growth conditions. In our group we focus on identification of molecular mechanisms activated by reactive oxygen species that contribute to defense signaling, ultimately leading to adaptation to abiotic stress.
By fully utilising long-term series of nature observations, we can understand environmental change and its impact on communities of organisms and the ecosystem services they provide.
Sensory and Physiological Ecology of Plants
We are elucidating the role of information in plant fitness. Plants sense their environment. They perceive signals and cues, using acquired information to adjust growth, morphology and development. Plants also emit informational signals. Acclimation that relies on information can be anticipatory.