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Seasonal timing
Species can adapt over the course of time. As the lives of species are altered by climate change, a different seasonal timing could make them adapt to an early spring, for example. How does this work, and what are the limits to such adaptations? -
Adaptation of species
During recent centuries, human activities have dramatically changed the habitats of wild animals, plants and micro-organisms. Ecologists at NIOO are interested in how species can adapt to these rapid changes, for example through (micro)evolution. The ability of organisms to do this has a major impact on biodiversity and the functioning of ecosystems. -
Greenhouse gases
Climate change is amplified by greenhouse gas emissions. At NIOO, we work on the fundamental understanding of how gases such as methane, carbon dioxide and nitrogen dioxide influence ecosystems. Our knowledge of carbon and nitrogen cycles provides insight into the potential of greenhouse mitigation tools. In a Dutch freshwater lake or the soil of a tropical rain forest. -
How do nutrients and temperature affect cyanobacterial bloom toxicity?
Toxic cyanobacterial blooms threaten freshwater quality, made worse by climate change and eutrophication. The toxicity of these blooms depends not only on cyanobacteria quantity but also on the presence potentially toxin-producing species and genotypes, and their varied toxin production. -
Climate change impacts on harmful algal blooms
Harmful cyanobacterial blooms produce toxins that are a major threat to water quality and human health. Blooms increase with eutrophication and are expected to be amplified by climate change. Yet, we lack a mechanistic understanding on the toxicity of blooms, and their response to the complex interplay of multiple global change factors. Bloom toxicity is determined by a combination of mechanisms acting at different ecological scales, ranging from cyanobacterial biomass accumulation in the ecosystem, to the dominance of toxic species in the community, contribution of toxic genotypes in the population, and the amounts of toxins in cells. -
Enhancing Soil Biodiversity
At NIOO, we are on a mission to explore the strange world beneath our feet, to seek out new soil-borne life, uncover new miniature civilisations, and to boldly take humankind where it could not go before. -
Soil biodiversity analysis for sustainable production systems (SoilProS)
SoilProS will interpret big data on soil biodiversity, soil chemical and physical characteristics with respect to current and desired soil functions, and how to use this information in order to help farmers predicting which crop varieties, seed mixtures, (organic) fertilizers, soil inocula, and organic substrates enhance the environmental sustainability of their activities. -
Spotlight on living soil at COP15 biodiversity conference
The UN Biodiversity Conference in Montreal (COP15) is discussing global action to reverse biodiversity loss. Healthy, living soil is of key importance. -
Discovering methane eating mycobacterium
Join the Pint of Science lecture where Paul Bodelier and Chrats Melkonian tell us all about their recent discovery of Mycobacterium (a type of immobile, rod-shaped bacteria) that live on eating methane. Hear what we can learn from these microbes and how we can use that to tackle the issues facing methane in our atmosphere today. -
New greenhouse gas-eating bacteria found in highly acidic sulphur cave
A team of ecologists and microbiologists that includes NIOO's Paul Bodelier has identified a unique organism in samples from a Romanian cave nicknamed 'Stinky Mountain'. The novel bacteria can grow on methane, an important greenhouse gas that contributes to global warming.