On September 18, the executive director of InnovPlantProtect (InPP), António Saraiva, the director of the New Biopesticides Department, Cristina Azevedo, and researcher Luís Grilo attended the Open Day “The Cereals of Baixo Mondego”, promoted by the Centro Regional Coordination and Development Commission (CCDR Centro), at the Bico da Barca Experimental Unit in Montemor-o-Velho.
The event highlighted the latest innovations from the Coimbra Innovation Hub, from new technologies applied to maize and rice, to fertilization strategies, protection and the use of biostimulants on these key crops in the Baixo Mondego region.
Our team also monitored trials with biofungicides, including the product I21, developed with our collaborative laboratory to combat pyriculariosis in two rice varieties, which is being patented.
In an interview with Voice of the Countryside, Cristina Azevedo shared the work we have been doing in the area of biosolutions.
Maize continues to be the Portugal's most important arable crop, The sector has a significant impact on food safety and the national agri-food industry. Involving thousands of producers and generating tens of millions of euros a year, the sector is currently facing increasingly complex phytosanitary challenges.
Among already known pests and emerging diseases, there are risks ranging from cartridge caterpillar until Maize Rugose Dwarfism Virus (MRDV), The presence of this virus is increasing in Portugal. This virus, transmitted by the corn leafhopper, can seriously compromise production and is found in the climate change increasingly favorable conditions for its spread.
However, it's not just MRDV that's worrying. There are new threats that require vigilance, such as the coleopter Diabrotica virgifera or the MDMV virus (Maize Dwarf Mosaic Virus), already detected in neighboring countries, and also toxic weeds, such as the winter fig (Datura stramonium), which in addition to impacting productivity pose public health risks.
Faced with this reality, the answer is integrated and sustainable strategies, matching:
crop rotation and good agricultural practices;
careful use of insecticides to avoid resistance and environmental impacts;
resistant or tolerant varieties, where available;
research and technological innovation, including new digital tools for early detection.
As the InnovPlantProtect researcher points out, Nuno Faria, in the article entitled “The main emerging pests and diseases of the maize crop in Portugal”, available in the August edition of Voz do Campo magazine: “The phytosanitary panorama of maize in Portugal requires continuous vigilance, investment in research and the application of integrated and sustainable strategies capable of responding to an increasingly dynamic and unpredictable reality.”
To find out more about the main current risks and mitigation measures, read the full article published in the August issue of Voz do Campo magazine (pages 88-89), available on newsstands and online.
InnovPlantProtect (InPP) is pleased to announce the publication of an international patent application (PCT) for a strain of Bacillus velezensis with application as a plant biostimulant. This innovation represents a significant milestone in our research, with a direct impact on sustainable agriculture and crop resilience in the face of climate and environmental challenges.
A natural and effective solution
The biostimulant developed by our team has been carefully studied and tested on different vegetable crops, such as tomatoes and lettuce, and on cereals, such as rice. The results obtained demonstrate the potential of this technology:
Greater development in the early stages of crops, This promotes more vigorous and healthy starts.
Increased productivity, This is evidenced by greater fresh biomass in lettuce and greater fruit production in tomatoes.
Proven molecular responses, with analyses confirming the activation of genes associated with plant responses to different types of abiotic stress.
These results reinforce the effectiveness of the Bacillus velezensis as a natural biostimulation tool, capable of boosting crop performance and contributing to more sustainable agriculture.
From the lab to the field
This patent is another step in InPP's commitment to developing innovative, sustainable biotechnological solutions with industrial applicability. The aim is clear: to support farmers and companies in the sector in meeting the challenges of crop productivity, quality and resilience, in an era when agriculture needs sustainable, high-impact responses.
We are looking for strategic partnerships
We are currently looking for new partnerships with companies and entities in the agricultural sector to take this technology from the laboratory to the field. We believe that collaboration is the key to turning scientific innovation into practical solutions that benefit the entire agricultural value chain.
If you're interested in learning more about this technology or exploring opportunities for collaboration, talk to us. Together we can drive a more productive, resilient and sustainable agriculture.
Innovate together. Protect better.
Image credits: InnovPlantProtect - Inês Ferreira (Photos from left to right: Sandra Caeiro and Rui Figueiras, researchers from the Specific Crop Protection Department and Inês Mexia, researcher from the Formulations and Process Development Department.
Nature Plants highlights the advantages of new genome editing techniques but warns of three crucial aspects that still need to be addressed.
“The rapid development of plant biotechnologies is profoundly shaping crop improvement and catalyzing the next revolution in agriculture,” writes an editorial recently published by Nature Plants, entitled Next-generation crop engineering (Next-generation crop engineering).
Crop improvement no longer has to depend on naturally occurring mutations and artificially generated variations can be the raw material for further improvement, the text argues. “A much broader spectrum of phenotypic space is ready for exploration, allowing the development of ideal phenotypes adapted to the heterogeneous environments of Earth, or even Space,” argue the authors of the paper. article, He concluded that “a new agricultural revolution driven by biotechnology could be just around the corner”.
Image: Francesco Gallarotti/ Unsplash
The editorial refers to the promise and advantages of the new genome editing techniques, particularly compared to classical breeding, but not only. And it warns of three crucial factors that are still missing in order to achieve high levels of variation through gene editing: 1) a better understanding of the key regulators for genes that are important from an evolutionary or developmental point of view; 2) being able to dissect networks of genes that control phenotypes of interest and regulatory networks in cis that affect gene expression; 3) to establish stable and efficient transformation and regeneration procedures for most species.
Unless genetic editing in planta is developed quickly, breeding based on gene editing will be unable to benefit recalcitrant species. It is also recalled that there are alternative strategies for engineering new generation crops, such as the transfection of viral RNA in sprays, which allows for the temporary adjustment of agronomic characteristics without modifying the genetic material.
The DGAV has announced new requirements for citrus production and marketing, due to the African citrus psyllid plague.
The technical requirements for the production and marketing of citrus fruits and other rutaceous plants in a place free from Trioza erytreae, the insect vector of the disease citrus greening, were recently updated and published by the Directorate-General for Food and Veterinary (DGAV).
The rutaceae are a family of trees in which the genus Citrus is imperative from the point of view of economic value. O citrus greening, greening citrus greening, Huanglongbing disease or citrus greening is caused by the African citrus psyllid (Trioza erytreae), an insect vector that also causes direct damage to citrus fruits.
“In view of the detection of Trioza erytreae in some regions of the country and given the expansion that has already occurred in the area infested by this insect, we have tried to ensure a set of conditions to ensure the continuity of production and marketing of citrus propagating material in regions where the pest is present,” explain the DGAV officials in a press release. document. The update was motivated by “experience gained in the meantime” and by the new legislation in force: Annex VIII of Implementing Regulation (EU) 2019/2072 and Ordinance no. 142/2020.
A Trioza erytreae is a quarantine pest on national territory.
In the T. erytreae, In addition to the obligatory declaration of mother or nursery plants, citrus and other rutaceous plants must be produced “in a place with complete physical protection against this insect” and have been subject to two official inspections in the last growing season without showing any symptoms of the pest.
For marketing, the plants must also be kept in a place with complete physical protection against this insect “and come from exempt areas (outside infested zones and buffer zones) or from nurseries located in demarcated zones”, among other requirements, which aim to guarantee that no infestation occurs.
InPP has a cooperation project with the DGAV to take part in the task force phytosanitary measures and to support the biological control plan with a view to controlling the Trioza erytreae.
Researchers at InPP are developing machine learning methods for predicting phenotypic traits from genetic information of key crops. The project is led by Manisha Sirsat, from the Data Management and Risk Analysis Department, which is headed by Ricardo Ramiro, in collaboration with the Protection of Specific Crops Department, headed by Paula Oblessuc.
Over the last decade, machine learning has become part of our everyday lives, when it suggests the next song you should listen to or the restaurant you should go to. This branch of artificial intelligence is focused on building models and applications that can learn from data, in order to predict a particular outcome. For this to be possible, large amounts of data are necessary which, until recently, would preclude its application in most fields of biology. However, in the last 20 years, biology has become a data-intensive discipline, due to the revolution brought by high-throughput systems for fields as disparate as genomics and microscopy. Thus, machine learning methods are now being applied to a wide range of biological questions.
At InPP, the team is taking advantage of the availability of high-throughput genomic and phenotypic data for key phenotypes of important crops (e.g. wheat genomes and yield) and using this data to develop machine learning models that can predict the phenotype from the genotype. This approach is termed Genomic Prediction. “The aim is to develop an advanced genomic prediction tool which uses genome-wide genetic markers to predict complex traits,” states Manisha Sirsat. “This will allow us to identify genetic markers that can increase agricultural productivity and that can accelerate plant breeding programs,” adds Ricardo Ramiro.
Image by congerdesign/ Pixabay
Image by annawaldl/ Pixabay
An advanced genomic prediction tool can help accelerate plant breeding programs and increase agricultural productivity.
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