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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? -
Dealing with bluegreen algae
Worldwide, excessive nutrient loads in lakes and reservoirs have led to the rapid increase of harmful cyanobacteria. Blooms of these algae block the use of surface water for drinking, irrigation and recreation. Climate change is expected to further increase the frequency, duration, and magnitude of cyanobacterial blooms. Aquatic ecologists from NIOO are busy gaining more detailed insights into cyanobacterial blooms across scales, in future climates and in respect to toxicity. -
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. -
The Galápagos Microbiome Project: voyage of discovery to an invisible world
How unique and diverse is the invisible life of the Galápagos Islands? That is the key question to which a team of international researchers, led by the Netherlands Institute of Ecology (NIOO-KNAW), is seeking answers. This year, they went on an expedition to the iconic islands to study the microbial life there. Insights from their research can contribute to the conservation of indigenous plant species and, in particular, Scalesia: the giant daisy. -
Inaugural lecture by Dedmer van de Waal
Op donderdag 6 juli houdt Dedmer van de Waal zijn oratie als bijzonder hoogleraar Aquatische Functionele Ecologie aan de Universiteit van Amsterdam. -
Expedition to uncover invisible life in Galápagos
An international research team led by the Netherlands Institute of Ecology (NIOO-KNAW) is to search for invisible life in the Galápagos Islands. -
Galapagos Microbiome Project
An international research team led by the Netherlands Institute of Ecology (NIOO-KNAW) is to search for invisible life in the Galápagos Islands. The diversity of bacteria and other microscopic organisms may not be evident to the naked eye, but it is essential to nature. To the islands' giant daisies, for instance: unique endemic plants that are currently under threat. -
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.