Estamos em contagem decrescente para a Feira Nacional de Agricultura (FNA), uma das maiores feiras agrícolas do país!
É já de 7 a 15 de junho que o InPP vai estar na 61ª edição da Feira Nacional de Agricultura, que se realiza no CNEMA – Centro Nacional de Exposições, em Santarém.
O tema da edição deste ano é “Biosoluções”e pretende destacar a importância das soluções e tecnologias inovadoras no setor agroalimentar e na promoção de práticas mais sustentáveis e eficientes.
A FNA reúne agricultores, empresários e especialistas dos setores agroalimentar, pecuário e agrícola e é um excelente espaço para aumentar a nossa rede de contactos, trocar conhecimentos e apresentar as mais recentes tendências e soluções agrícolas que a nossa equipa tem desenvolvido.
Vai poder encontrar-nos no stand nº.18, à entrada do Espaço dos claustros, dedicado à Agenda InsectERA, entre as 10h e as 20h.
InnovPlantProtect (InPP) took part in the National Olive Growing Fair (FNO 25) in Campo Maior, from May 23 to 25, presenting its latest biological and digital innovations for crop protection, including projects focused on biopesticides for olive diseases and early detection of fungi that cause gafa, and monitoring insect vectors of the bacterium Xylella fastidiosa, which attacks olive groves. The Elvas CoLAB was present with its own stand to demonstrate its strengths and the impact of its research on agricultural sustainability, inviting producers, technicians and researchers to learn about its innovative bio-based and digital solutions and to actively participate in the discussion of the sector's challenges.
The collaborative laboratory (CoLAB) welcomed visitors at the stand no. 14, located at thematic area at the Campo Maior Municipal Garden, to showcase their activity, the ongoing projects that are developing solutions to the main olive diseases, the patents already submitted, the apps for agricultural management and the bio-based and digital products and services they have to offer the agricultural sector and the market. Throughout the three days of the fair, some of InPP's researchers were at the stand to demonstrate to visitors the various features of the Elvas CoLAB, which has been developing innovation that it hopes will contribute to the sustainability of agricultural systems.
InPP announced ValorCannBio project, which is processing biomass that is not used in the medical cannabis industry to develop effective and sustainable biopesticides against gafa and tuberculosis, The project will be carried out in the municipality of Elvas, which is responsible for decimating entire harvests, leading to severe economic losses and compromising food quality. The impact of this project will be felt in the municipality of Elvas, where the project is being developed, but it is expected that it will extend to the entire olive-growing region from Trás-os-Montes to the Algarve, where production losses are increasing due to these diseases. O AlViGen project was also one of the protagonists and is using cutting-edge technology to detecting and identifying the strains of fungi that cause gafa, long before the symptoms become visible. The project team has used traps to collect spores that circulate in the air to monitor the presence of fungi, which can give farmers an important advantage in preventing infections and protecting their crops, reducing production losses.
O SNM_XylellaVt project, The SNM_XylellaVt project, led by DRAPCENTRO and in which InPP actively participates, was also highlighted at FNO. SNM_XylellaVt is monitor the insect vectors of the bacteria Xyllela fastidiosa, in particular the foam leafhopper, the insect responsible for transmitting the bacterium, which attacks various agricultural and forestry crops, and in particular olive groves. The project team is developing new tools, such as risk prediction models which, in the presence of the bacterium, whether in plants or insect vectors, will allow the National Agricultural Warning Service (SNAA) to alert, in real time, about the economic attack levels (EAL) for these insects, thus allowing prevent infection of the main crops. As part of this project, the team has also developed an online platform where citizens can report the sighting of foams, which are signs of the presence of the insect vectors of X. fastidiosa, This will help to map its temporal and spatial distribution and to plan measures to combat this bacterium.
The FNO, organized jointly by the Campo Maior City Council and the Centre for the Study and Promotion of Olive Oil in the Alentejo (CEPAAL), is an event that aims to enhance national olive growing, and in particular Portuguese olive oil, boosting the local economy and bringing together professionals from the sector - producers, technicians, or researchers - from all over the country to discuss challenges and trends in the Portuguese olive and olive oil sector.
Each year, crop diseases cause devastating losses in agricultural production, threatening food security and the livelihoods of millions of farmers. In the heart of Alentejo, an innovative project is harnessing the power of genomics to help combat these invisible threats. The AlViGen Project, with the participation of InnovPlantProtect researchers Rute Rego and João Bilro, is paving the way for a new era of crop surveillance and protection.
The Problem and the Solution
“Yellow rust in wheat and olive quick decline syndrome are real scourges for farmers,” explains Rute Rego, a researcher at AlViGen. “These diseases can decimate entire harvests, leading to severe economic losses and compromising food quality.”
But AlViGen is not limited to observing the problem. The team is using cutting-edge technology to detect and identify the strains of fungi that cause these diseases, long before the symptoms become visible.
“We use traps to collect spores circulating in the air,” Rute continues. “These traps allow us to monitor the presence of fungi in real-time, which gives us an important advantage in preventing infections.”
But the magic happens in the laboratory, where the team extracts the DNA from the spores and performs advanced genomic analyses, using powerful DNA sequencing technology based on the metabarcoding method, carried out with cutting-edge technology like the portable Nanopore sequencer.
Rute Rego, a researcher at InnovPlantProtect, analyzes samples of the fungus causing olive quick decline syndrome as part of the AlViGen project.
Unraveling the Genetic Code of Fungi
To better explain what metabarcoding is and its advantage in detecting the presence of species or strains of fungi that cause diseases in crops, the researcher gives the example of a bag full of different types of grains - rice, beans, corn - being analyzed by the reader. “Metabarcoding is like placing a unique label (a ‘barcode’) on each type of grain. Then, you can mix all the grains in a single sample, and by reading the labels, you can identify the quantity of each type of grain present.'”
In the case of AlViGen, this technique allows for the analysis of multiple fungal species simultaneously (in multiple samples), each with its own genetic ‘barcode,’ and to ‘identify exactly which fungi are present, even in small quantities,'” the researcher explains.
And what is the practical impact of this method for monitoring and predicting disease? The AlViGen project researcher can identify, with high precision, the moment when the pathogenic agent begins to appear in the field, which makes it possible to alert farmers in real-time about the risk of disease. Producers can adopt preventative measures and apply the necessary products to avoid infection, contributing to a rapid and effective response in disease prevention.
The Timeline of Fungal Evolution
AlViGen's research is not limited to identifying the microorganisms harmful to crops; it also seeks to understand their evolution and diversity. João Bilro, another researcher on the project, is dedicated to studying the phylogeny of the Colletotrichum fungus, a microorganism responsible for causing olive anthracnose or blight, a disease that affects olive groves in Portugal. This disease mainly affects the olives, which compromises the quality of the olive oil.
“Phylogeny is crucial for understanding how the different strains of Colletotrichum Just as a family tree traces the history of a family, showing how members are related to each other, phylogenetic trees reveal the evolutionary relationships between the different strains of this fungus. Each branch of the tree represents an evolutionary lineage, and the nodes indicate common ancestors. By comparing the DNA sequences of these strains, we can reconstruct their evolutionary history, identifying which are genetically closer or more distant, and thus infer characteristics such as virulence or resistance to fungicides,” he reveals.
This knowledge allows researchers to identify patterns of dissemination and adaptation of the fungus, which is fundamental for developing more effective strategies to contain and/or reduce the damage this fungus causes to Portuguese olive groves.
“One of the challenges of our research is the great genetic diversity of the Colletotrichum,” admits João. “However, by uncovering their evolutionary secrets, we are paving the way for the development of more precise and targeted detection and control methods.”
Left photo: João Bilro, a bioinformatician at InnovPlantProtect, studying the phylogeny of the Colletotrichum fungus within the scope of the AlViGen project; Right photo: Rute Rego and João Bilro discuss ideas about the AlViGen project.
The Future of Agriculture Starts Here
The AlViGen Project aims to have a significant impact on the agricultural landscape, especially in Alentejo, a region with a strong agricultural tradition. By providing farmers with early detection tools and precise information about the microorganisms that cause crop diseases, the project intends to aid in decision-making, allowing farmers to protect their crops and reduce production losses.
“Our ultimate goal is to empower farmers with the knowledge and tools they need to protect their crops sustainably,” states Rute. “We believe that genomic surveillance is a key tool for the future of crop protection.”
João Bilro agrees and adds, “Continuous research is fundamental to keep up with the evolution of harmful microorganisms and to develop new, consistently effective control strategies. In the future, we hope to expand the scope of AlViGen to include other microorganisms and crops, and to make genomic surveillance an accessible tool for all farmers.”
Science at the Service of Agriculture
The AlViGen Project, supported by the Promove Program of the “la Caixa” Foundation, in partnership with Banco BPI and the Foundation for Science and Technology (FCT), is an inspiring example of how science and technology can be applied to solve real-world problems and transform agriculture. By unraveling the genetic secrets of crop microorganisms, Rute Rego and João Bilro are paving the way for a safer, more sustainable, and resilient agriculture.
The fight against crop diseases continues, but with AlViGen, farmers can finally see the enemy before it becomes visible.
Beyond strategy: The secret ingredient of innovation
On the road to success, organizations define strategies, plan every step and invest in crucial resources such as selling services and products, applying for projects, drawing up solid business plans and protecting intellectual property. However, there is an element that is often overlooked, but which is fundamental to the flourishing of innovation: serendipity. But what exactly is this mysterious force and why is it so vital to the advancement of agriculture and so many other areas?
When chance opens doors: The power of unplanned discovery
Serendipity is the art of finding something valuable when you're looking for something else. It's the unintentional discoveries that arise from unexpected situations. Throughout history, some of the most transformative innovations have not been the result of a rigorous plan, but rather a chance encounter with the unknown. While deliberate research and methodical experimentation are pillars of scientific and technological progress, openness to the unexpected proves to be a powerful catalyst. When researchers cultivate this openness, they often stumble upon revelations that have the potential to revolutionize entire industries, transform technologies and expand our understanding of the world around us.
A close look at “error”: The genesis of an innovative biofungicide
Today, we unveil the surprising and inspiring story of Maria Miguel, a talented researcher from InPP's New Biopesticides Department, whose acumen turned a chance event into a priceless discovery: a broad-spectrum biofungicide capable of combating the Botrytis cinerea, the relentless fungus responsible for the devastating gray rot disease in tomato plants. This pathology represents one of the biggest phytosanitary challenges in tomato cultivation, especially when grown in greenhouses, causing significant losses to producers if it is not controlled in good time.
From discard to discovery: The insight of a researcher
The journey of this discovery began in a setting familiar to any researcher: the observation of Petri dishes, used to grow cultures of cells or microorganisms. On Maria Miguel's plates, colonies of the fungus Botrytis cinerea were growing, intentionally introduced there for study. However, something else caught her eye: one of the plates was contaminated by mold, and curiously, a clear area surrounded this intruder. Instead of discarding the plate and dismissing it as mere contamination, Maria Miguel decided to investigate the reason behind the clear area. Her curiosity revealed that the mold had a surprising ability to prevent the growth of Botrytis cinerea in its vicinity.
“Sometimes we look at something and think it's a mistake. The truth is that in a failure there can be something good,” the researcher shares. The excitement and enthusiasm of a researcher realizing that what at first glance seemed like an obstacle, a negative result, could actually be an opportunity, is contagious. For Maria Miguel, this “mistake” turned into a serendipitous discovery with enormous potential.
Maria Miguel, a researcher at InPP's New Biopesticides Department, who turned an unexpected event into a discovery that changed the course of her work: a broad-spectrum biofungicide to combat gray rot in tomato plants.
Beyond chance: The active ingredients of scientific discovery
As the history of this biofungicide shows, the world of science is full of examples of discoveries that came out of the blue. One of the most famous cases is Alexander Fleming's discovery of penicillin in 1928. While observing Petri dishes, Fleming noticed that a mold was producing a substance that eliminated bacteria Staphylococcus aureus around him. He identified the mold as Penicillium notatum and named his revolutionary antibiotic penicillin. Penicillin ended up becoming an extremely important medicine for fighting infections.
However, chance is not the only protagonist of these important revelations. “Sometimes we have to follow our intuition and be able to prove ourselves right or wrong,” explains Maria Miguel. In addition to intuition, a generous dose of curiosity, an open mind to accept unexpected results, solid scientific knowledge and the ability to see and move on to further research into surprising results play a crucial role in the alchemy of discovery.
The discovery ecosystem: Fostering an environment conducive to innovation
There are other ingredients that contribute to the recipe for scientific success:
Creativity: The ability to generate new perspectives, concepts, questions or solutions, and the willingness to explore existing ideas in a new light.
Flexibility: The courage to venture into unknown territory without the fear of failure, thus increasing the chances of serendipitous encounters.
But no discovery flourishes in isolation. At InPP, the strong team spirit and culture of collaboration transcend departmental boundaries. The case of Maria Miguel's discovery is testimony to this synergy, as she herself acknowledges: “My colleagues opened doors so that I could do my research”.
To foster innovation, organizations need to cultivate an environment that encourages open discussions and connects people from different areas of knowledge and life experiences, without judgment; that encourages curiosity and receptiveness to new experiences; and that promotes an incessant quest to improve scientific knowledge, the fertile ground where serendipity can germinate.
Sowing the future: The impact of a discovery and the path of research
Although Maria Miguel is about to embark on a new journey, boosted by a prestigious Marie Skłodowska-Curie PhD scholarship - a program that supports the careers of researchers and promotes excellence and innovation in research - her legacy at InPP is already flourishing. Her groundbreaking discovery is opening promising new doors for future research in the field of crop protection, demonstrating how sometimes it is in the unexpected that the potential to transform our world lies.
In the March issue of Fruits, vegetables and flowers you will find the opinion article entitled “The role of InnovPlantProtect in Organic Farming: Paths to sustainable and efficient solutions”, in which the executive director of InnovPlantProtect (InPP), António Saraiva, reveals how our CoLAB is contributing to the success of organic farming.
“By boosting research, collaboration and knowledge sharing, InPP is helping to solve the central challenges of this practice [organic farming], allowing it to expand and enhancing the supply of agricultural products to consumers. The solutions developed by InPP make organic farming a more viable option for producers,” says the executive director.
Read the full article and find out how we are shaping the future of agriculture.
We thank Frutas, legumes e flores magazine for its recognition and reiterate our commitment to the agriculture of the future.
Imagine a future where drones and artificial intelligence work together to protect your vineyards. That's what the AI4Leafhopper project is making a reality!
Manisha Sirsat, a researcher on the AI4Leafhopper team, has developed two artificial intelligence models that analyze the aerial images captured by our latest generation drone... and these models make it possible:
geolocation of each vine
to know if there are vine failures
quickly identify “sick” vines”
optimize the application of treatments
The result? Growers can have a detailed view of the health of their vineyards, detect problems early and make more informed decisions.
AI4Leafhopper is a project led by InPP and funded by the ICAERUS Horizon Europe program, which began in April 2024 and ended on April 30 with a final meeting involving the six European projects approved in the 1st edition of the ICAERUS program's PULL applications. The project team presented the AI-based models for detecting and monitoring the impact of the green leafhopper on vineyards.
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