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January 22, 2025

Breed, Sow, Grow: Adventures and Challenges in Plant Breeding

In our previous blog episode, we talked about selection intensity. Today, we will get an overview of plant stressors and how to manage them. Let's dive into "Under Pressure: Breeding Resilience for all Seasons".

Understanding Plant Stress

Plants, like humans, face challenges that threaten their health and growth. Understanding these stresses and their impact is crucial, particularly as climate change amplifies their intensity. In this blog episode, we look closer into how to equip our crops to withstand these pressures.

The challenges that affect plants are broadly classified into two categories: biotic and abiotic stress.

• Biotic stress: This is caused by living organisms such as insects, fungi, bacteria, and viruses. Biotic stress happens when pests or pathogens attack plants. For example, caterpillar infestations can damage leaves, while fungal infections may rot the roots.
   
• Abiotic stress: Non-living factors, such as drought, extreme temperatures, high salinity, and pollution, cause abiotic stress. Environmental conditions like prolonged droughts can dry out plants, while heatwaves can damage plant tissues, impair growth, and reduce yields.

The Role of Climate Change

Climate change exacerbates these stresses, making them more severe and unpredictable:

Heat stress: Rising temperatures and more frequent heatwaves damage plant cells and reduce photosynthesis, stunting growth and lowering yields.

Water-related stress: Longer droughts lead to water shortages, while intense rainfall causes flooding, soil erosion, and nutrient depletion. Flooding suffocates roots and washes away vital nutrients, significantly impacting plant health and productivity.

Pests and pathogens: Changing climates create favorable conditions for pests and diseases in regions where they previously could not survive, increasing biotic stress on crops.
 

An overview of plant stress factors and potential solutions. Biotic stress arises from e.g. pests, fungi, bacteria, and viruses, while abiotic stress is caused by factors like drought, extreme heat, salinity, and pollution. These stresses are seen as external threats that hinder plant growth. Potential solutions include genetic engineering, modern machinery, molecular breeding, and AI-driven tools. These advanced technologies and methods enable plants to adapt and thrive under challenging conditions.

The Role of Plant Breeders

In agriculture, biotic and abiotic stresses can drastically reduce yields, lower crop quality, and drive up costs for pest control and irrigation significantly, threatening food security and farmers' livelihoods.

Plant breeders play a pivotal role in addressing these challenges by:

• Developing resilient crops: Breeders select plants with traits that enhance resistance to pests and environmental extremes. This can be achieved through traditional breeding or advanced genetic engineering techniques.
   
• Breeding for resistance & tolerance: Resistance enables plants to prevent or combat stressors like pests, while tolerance allows them to endure stress with minimal damage.

Farmers can manage these biotic and abiotic stresses by adopting resistant varieties, integrated pest management, efficient irrigation, and crop rotation.

Tools and Technologies for Modern Plant Breeders

To breed resilient crops, plant breeders leverage a range of different tools and technologies:

• Genetic diversity: A diverse gene pool provides breeders with a rich reservoir of traits. Genetic diversity allows breeders to select and cross to enhance resistance and tolerance in their varieties
• Molecular markers: By using markers, breeders identify valuable traits at the DNA level, making their work more precise and speeding up the breeding process.
• Genome editing: Technologies like CRISPR/Cas9 allow specific modifications to plant DNA, allowing faster development of stress-resistant varieties.

Artificial intelligence (AI) and machine learning are transforming plant breeding, offering powerful tools to analyze vast datasets and predict crop performance under specific climate and stress conditions. For instance:

• AI algorithms can identify genetic markers linked to drought tolerance or pest resistance.
• Machine learning can simulate breeding scenarios, optimizing breeding programs and reducing reliance on lengthy field trials.
• AI-driven phenotyping can monitor plants in real-time, providing insights into growth and stress responses.

As the negative effects of climate change intensify, the pressure on plants continue to grow. However, advances in breeding technologies, genetic diversity, and AI-driven tools are empowering breeders to develop resilient crops. Through innovation and adaptation, we can ensure sustainable agriculture and secure food supplies for the future.

If you missed any of our previous episodes, read them here:

S1E1 - Breeding Brilliance: Unveiling the Crop Superheroes
S1E2 - Genius Genes: Unlocking Genetic Diversity
S1E3 - Phenomenal Phenotyping: The Science of Collecting Data
S1E4 - Genotyping Galore: Crafting Crops From Genetic Blueprints
S1E5 - Data Drama: Breeding's Behind-the-Scenes
S1E6 - Need for Speed: Accelerating Crop Breeding
S1E7 - Precision Play: The Art of Crop Makeover

Do you want to know how Computomics can support plant breeding for the future?
Check out our Climate-Smart Breeding page or contact us!

Website: https://www.computomics.com

Published: January 22, 2025