The executive director of InnovPlantProtect (InPP), António Saraiva, took part in the conference “What are the challenges facing the national agroforestry sector over the next decade?”, which took place at the Escola Superior Agrária de Coimbra (ESAC) of the Polytechnic Institute of Coimbra last Tuesday, April 22.
The event, which brought together more than 150 participants and was organized by 17 national Competence Centres, discussed topics such as innovation, sustainability, soil conservation, monitoring cork oak forests and efficient agricultural management.
António Saraiva was part of the panel of commentators, whose speaker was Pedro Santos, Director General of CONSULAI, and moderated by Maria Custódia Correia, Coordinator of the AKIS Portugal Network. The opening session was attended by the Minister for Agriculture and Fisheries, José Manuel Fernandes, who announced the publication of the Ordinance of April 21 to open the Grant for Initiatives for the creation of Operational Groups (OG).
This initiative provides a total of 11 million euros for new GOs, with a maximum of 350,000 euros per project and eligible funding of 100%.
The GOs are considered crucial structures for transferring knowledge and strengthening the AKIS (Agricultural Knowledge and Innovation System).
Special thanks to the 17 Competence Centers for the opportunity to participate in this productive meeting!
Beyond strategy: The secret ingredient of innovation
On the path to success, organizations define strategies, plan each step, and invest in crucial resources such as the sale of services and products, project applications, the development of solid business plans, and the protection of intellectual property. However, there is an often-neglected element that is fundamental to the flourishing of innovation: serendipity. But what exactly is this mysterious force, and why is it so vital to advancing agriculture and so many other areas?
When chance opens doors: The power of unplanned discovery
Serendipity lies in the art of finding something valuable when 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 of a fortuitous encounter with the unknown. Although 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 come across revelations that have the potential to revolutionize entire industries, transform technologies, and expand our understanding of the world around us.
A close look at the “error”: The genesis of an innovative biofungicide
Today, we unveil the surprising and inspiring story of Maria Miguel, a talented researcher from the InPP's New Biopesticides Department, whose insight transformed a fortuitous event into a discovery of inestimable value: a broad-spectrum biofungicide capable of combating Botrytis cinerea, the relentless fungus responsible for the devastating gray mold disease in tomato plants. This pathology represents one of the greatest phytosanitary challenges in tomato cultivation, especially when grown in greenhouses, causing significant losses to producers if not controlled in a timely manner.
From discard to discovery: An investigator's insight
The journey of this discovery began in a scenario familiar to any researcher: the observation of Petri dishes, used to grow cell or microorganism cultures. In Maria Miguel's Petri dishes, colonies of the fungus Botrytis cinerea were growing, intentionally introduced there for study. However, something else caught her attention: one of the plates was contaminated by mold, and curiously, a clear zone surrounded this intruder. Instead of discarding the plate and ignoring it as mere contamination, Maria Miguel decided to investigate the reason behind that clear area. Her curiosity revealed that the mold had a surprising ability to inhibit the growth of Botrytis cinerea in its vicinity.
“Sometimes we look at something and think it's a mistake. The truth is that within a failure, there can be something good,” shares the researcher. The emotion and enthusiasm of a researcher when realizing that what at first seemed like an obstacle, a negative result, can actually be an opportunity, is contagious. For Maria Miguel, this “error” transformed into a serendipitous discovery with enormous potential.
Maria Miguel, a researcher at the InPP's Department of New Biopesticides, transformed an unexpected event into a groundbreaking discovery: a broad-spectrum biofungicide to combat gray mold in tomato plants.
Beyond chance: The active ingredients of scientific discovery
As the story of this biofungicide demonstrates, the world of science is full of examples of discoveries that arose from the unexpected. One of the most famous cases is the discovery of penicillin by Alexander Fleming in 1928. While observing Petri dishes, Fleming noticed that a mold was producing a substance that eliminated Staphylococcus aureus bacteria around it. He identified the mold as Penicillium notatum and named his revolutionary antibiotic penicillin. Penicillin ended up becoming an extremely important drug 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 that we are right or wrong,” explains Maria Miguel. In addition to intuition, a generous dose of curiosity, an open mind to accept unexpected results, a solid scientific knowledge, and the ability to see and advance to further investigations on surprising results play a crucial role in the alchemy of discovery.
The ecosystem of discovery: 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 under a new light.
Flexibility: The courage to venture into unknown territories without fear of failure, thus increasing the odds of serendipitous encounters.
But no discovery flourishes in isolation. At InPP, the strong team spirit and culture of collaboration transcend departmental boundaries. Maria Miguel's discovery is a testament 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 stimulates open discussions and connects people from diverse areas of knowledge and life experiences, without judgment; that encourages curiosity and receptiveness to new experiences; and that promotes a relentless pursuit of improving 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, driven by a prestigious Marie Skłodowska-Curie doctoral fellowship - a program that supports the career of researchers and promotes excellence and innovation in research - her legacy at InPP is already flourishing. Her innovative discovery is opening new and promising doors for future research in the area of crop protection, demonstrating how, at times, it is in the unexpected that the potential to transform our world lies.
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.
Sometimes, if you're inside a building, it's hard to tell whether or not it's raining outside. However, you will easily conclude that it is raining if you see people with open umbrellas. The umbrella is an accessory that helps human beings deal with their environment.
Bacteria can also use “accessories” to better cope with their environments. These accessories, however, have much more profound effects on the lives of microbes, as they take the form of genes that can be integrated into their own genomes. These “accessory” genes are obtained from other microbes or from the environment, and can play various roles, from allowing bacteria to resist antibiotics to enabling symbiotic associations with plants.
Image: Adrianna Calvo/ Pexels
At InPP, the Data Management and Risk Analysis Department is comparing bacterial genomes to identify those that have “accessory” genes that can help plants defend themselves better against pathogens. On the other hand, these analyses also allow us to rule out bacterial strains that could have adverse effects. This information will be crucial for identifying microbes and microbial characteristics that are important for plant protection.
Tobacco whitefly uses a stolen gene to avoid the host's defenses. The discovery is highly relevant to pest control.
The first known case of a natural gene transfer from a plant to an insect has been identified by an international team of researchers. The insect is a whitefly and the discovery could pave the way for new pest control strategies, according to a report published in the newspaper Nature.
Scientists have discovered that Bemisia tabaci appropriated a gene from a host plant millions of years ago, reveals a article published in Cell. The gene allows this pest to neutralize a toxin produced by certain plants to defend themselves against insects.
Some whiteflies use plant genes to render toxins harmless. Image: Gaucho/ Wiki
This aleirodid, also known as the bean or sweet potato whitefly, although it attacks many other vegetable crops, is a worldwide pest and one of the most destructive we know of. A Bemisia tabaci ingests the sugary sap of hundreds of types of plants, excreting a sweet, sticky substance, honeydew, which then serves as a medium for fungi to grow. Whiteflies are also vectors for more than a hundred viruses that are pathogenic to plants.
“It's a remarkable example of how the study of evolution can underpin new approaches to applications such as crop protection,” says Andrew Gloss, who studies plant-pest interactions at the University of Chicago in the USA. The study suggests that inhibiting the gene identified could make this whitefly vulnerable to the toxin, opening up a new way of combating this pest.
Protecting plants from pathogens without genetically modifying crops? A team of Chinese researchers suggests an alternative strategy in the latest issue of Plant Communications.
The biotechnological methods that currently exist to create crops that are resistant to pests and diseases are limited in their applicability, mainly because they are based on transgenics or surface application (which does not allow access to the inner areas of the plant). A scientists' proposal involves the use of small RNA produced by beneficial microbes for crop protection, guaranteeing the stability and delivery of these RNAs to the appropriate place and time.
RNA associated with beneficial microbes in the microbiome to protect crops against pathogens.
The strategy, which eliminates “the need for genetic modification of cultures”, assumes that small RNAs (sRNAs) can be transferred from the microbiome to the host and pathogen, or between elements of the microbiome.
sRNAs are the crucial molecular devices of so-called gene silencing via RNA interference, a mechanism that regulates gene expression at both the transcriptional and post-transcriptional levels.
Title of original article: Trans-kingdom RNAs and their fates in recipient cells: advances, utilization, and perspectives
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