EU-China joint action to increase the development and adoption of IPM tools
The persistent threat of invasive agricultural pests and their chronic re-emergence underlines the importance of Integrated Pest Management (IPM) tools and their implementation. Pest management typically relies largely on chemical pesticides, increasing the risks to humans and wildlife. Despite European Union and Chinese policies promoting the use of IPM, widespread adoption by farmers is limited. This project will utilize existing knowledge and techniques to adapt and optimize future IPM tools and practices. The project will further develop high-potential IPM tools and design cost-effective, environmentally safe IPM packages for economically important crops. Together with partners, CABI will lead the development of a web-based IPM tool performance demonstrator. CABI will also make valuable contributions to the development and efficacy of IPM tools against fall armyworm and develop a biocontrol agent for common ragweed.
Earth observation to improve critical datasets for pest risk modelling
Rising temperatures have led to pests, diseases and weeds establishing in areas of the world that were previously uninhabitable. Furthermore, growth in global trade and new trade pathways increase the risk of accidental movement of pests. Earth Observation (EO) and climatic data can help by improving predictions about where potential agricultural pests and diseases may be a threat. Information produced by models can help decision makers understand and prepare for future risks. Working with a consortium of researchers, this project will use EO data to improve the data layers used in models that predict where pests can establish, including irrigation, areas under protected agriculture and climatic canopy conditions, demonstrating the improvements made to species distribution estimations for key pests and biological control agents.
Juno: Transforming Evidence for Agriculture, Food and Climate
To respond urgently in times of crises we need to be ready. Researchers need the know-how and tools to develop rapid evidence synthesis at short notice, and coordinated networks need to be able to translate, communicate, and share evidence at a moment’s notice so that policymakers can use that evidence. The Juno Evidence Alliance will be a cutting-edge global platform that empowers evidence-based policy in agriculture, food systems, and climate adaptation. By utilising artificial intelligence and proven research methodologies, the aim is to streamline the synthesis of diverse data sources, providing timely, relevant, and high-quality conclusions for governments, funders, and policymakers. With Juno, decision-makers can accelerate progress, reduce costs, coordinate messages, and shape a sustainable and resilient future for the benefit of all.
The European MICRObiome Biobanking (RI) Enabler
Microbiomes are communities of microorganisms that include bacteria, archaea, protists, fungi and microalgae, their structural elements, metabolites, signal molecules, mobile genetic elements and surrounding environmental conditions. They are essential for maintaining ecosystems and the health of plants, animals and humans. The EU-funded MICROBE project will cooperate with research infrastructures to create and develop methodologies and technologies to enable access to microbiome samples and associated data. The project objectives include technical solutions for microbiome preservation, propagation and functionality assessment, as well as data infrastructures. MICROBE will also address issues associated with standardization, ethical and legal requirements, and business opportunities.
Classical biological control of Japanese beetle
The Japanese beetle (Popillia japonica) is a pest that feeds on hundreds of fruit tree species, causing considerable damage. In the USA, costs to control the pest exceed $450 million per year. Global regions that climatically support the invasion of the Japanese beetle include central Europe where it is considered a high priority pest. This project is aiming to tackle the spread of the Japanese beetle by exploring the use of the parasitic fly, Istocheta aldrichi, as a classical biological control agent in Switzerland, where it arrived in 2017.