The project addresses the global need for a reliable mass production of a pathogen free live feed for the larval aquaculture industry. The new ready-to-use solution will be produced sustainably to supplement or replace Artemia, the most important current live feed. Mainly produced in USA, the only existing storage stable live feed, Artemia, is limited in supply, threatening future growth of the aquaculture industry. Hatcheries are eagerly looking for new ready-to-use and pathogen free solutions as all live feeds are potential carriers or vectors for diseases causing severe losses per year. E-nema has produced and successfully tested nematodes as live feed. This new protein feed, made in Europe, is produced in bioreactors using cost effective and readily available feedstock from land bound agriculture. Contrary to state of the art solutions no fish oil or fishmeal is required to enhance the feed to proper nutritional value. The storage stable new European live feed is ready-to-use within 1-hour rehydration in water, requiring minimal labour and facility. Existing live feeds are complicated to use, requiring treatment with chemicals, incubation periods and dedicated equipment. This consumes space, energy, skilled labour and produces waste. Manufactured under sterile conditions, the new feed eliminates the need for prophylactic or curative use of antibiotics in hatcheries. Hatcheries provide aquaculture farms with fingerlings that are then grown to market size in tanks, ponds or open water installations. Aquaculture is the fastest growing food production sector, requiring reliable feed sources to sustain this growth. A strong potential for sales into aquaculture of current and high-value emerging European aquatic species has been identified. Next step is to choose and verify methods for technical upscale as well as building an in depth researched business case. A high level investigation has so far found the project financially viable.

The Directive 2009/128/EC sets rules in EU for the sustainable use of pesticides to reduce the risks and impacts of pesticide use on people's health and the environment. Among the listed actions there is the promotion of low pesticide-input management including non-chemical methods. In parallel several chemical active ingredients have been banned because of toxicity concerns. The result is that growers are left with few control tools against pests. On the other hand most of the available alternative control methods have several limitations, especially in term of efficacy. Several new ideas are not reaching the industry and are confined in the academic world. The concept behind this EIT is to explore new approaches to identify new cutting edge solutions for pest control based on new non classical approaches in strict collaboration with industrial partner and to train 11 highly skilled early stage researchers (ESR) through a doctoral programme that integrates 5 academic research with concept-driven product development in 6 EU companies with a strong curriculum in development and innovation within a large interdisciplinary environment. Microorganisms are often used so far as replacement of chemical active ingredients. The innovative aspect of this EID is to base the new pest control solutions on interactions of microorganisms with plants and insects rather than using them as plant protection products. Microorganisms’ unsurpassed inclination towards the association with eukaryotic macro-organisms determines traits and qualities in the host that harbours them. Microbial symbionts’ ability to profoundly transform their living habitat paves the way for unexplored outlooks in the ability to use microbial symbioses as sustainable and renewable tools to improve production and quality in agriculture. Microorganisms are key players in shaping several insect’s semiochemicals, in particular kairomones indicating a food source or oviposition site for some insect species.

The Japanese beetle, Popillia japonica, is one of the worst invasive pests of North America. Costs to control the pest in the US exceed $450 million per year. P. japonica was detected near Milano in 2014, and is now starting to spread in Europe. It is an enormous threat to Europe, since (1) it can feed on more than 300 host plants, including many important crops, (2) it is a good flyer and can be relocated via movement of goods and people, (3) climate suitability puts at risk an area ranging from the Atlantic to the Black Sea, and from the Mediterranean to Great Britain and Southern Scandinavia. EFSA and the JRC of the European Commission nominated P. japonica a candidate high priority pest in the EU in the new EU Plant health Law. IPM-Popillia has the aim to counteract this invasion. The project will provide fast and reliable monitoring tools, including an app-based citizen science approach to rise public awareness. Its main deliverable will be an IPM-Toolbox for control of P. japonica, relying exclusively on environmentally friendly control measures. Several teams of the consortium will collaborate in the core of the recent outbreak area, doing practical research in an European environment that can be applied immediatedly. The ambition of IPM-Popillia is to show that it is possible to control the new pest, and meet the requirements of quarantine regulations, and at the same time respect the environment and the principles of the sustainable use directive. IPM-Popillia will provide an integrated pest management strategy against P. japonica at a very early timepoint of the invasion process. So far, the new pest is still confined to one single and comparatively small area of about 6’000 square kilometres on mainland Europe. This timeliness is exceptional when compared to previous invasions into Europe, and will significantly enhance chances for successful containment, provided that the starting signal is given NOW.

The FF-IPM project targets three highly polyphagous fruit fly (FF) species (Tephritidae) that cause devastating losses in the fresh fruit producing industry, the Mediterranean fruit fly (Ceratitis capitata), a serious emerging pest in northern temperate areas of Europe, the Oriental fruit fly (Bactrocera dorsalis) and the peach fruit fly (B. zonata) two major new (invasive) pests, which pose an imminent threat to European horticulture. The project aims to introduce in-silico supported prevention, detection and Integrated Pest Management (IPM) approaches for both new and emerging FF, based on spatial modelling across a wide range of spatial levels, novel decision support systems, and new knowledge regarding biological traits of the target species, fruit trading and socioeconomics. FF-IPM introduces a fundamental paradigm shift in IPM towards “OFF-Season” management of FF by targeting the overwintering generation when population undergoes significant bottlenecks, preventing, this way, population growth later in season. “ON-Season” control approaches will be generated for different spatial scales considering both existing and developed by FF-IPM tools and services. Innovative prevention tools to track FF infested fruit (e-Nose) and rapidly identify intercepted specimens (Rapid-Molecular-Pest-ID tools) in imported commodities and at processing industries will be produced. Species specific e-trapping systems for the three-target FF will be advanced and employed by novel detection strategies based on spatial modelling. Both “ON and OFF-Season” IPM approaches and detection strategies will be validated in selected locations in eight different countries. FF-IPM generated data on FF response under stress conditions, overwintering dynamics, establishment and dispersion patterns of low population densities combined with advanced spatial population modeling are expected to contribute towards understanding drivers of emerging and new pests under climate change scenarios.