Drought stress – mycolab.ai

Genome-wide identification of PSKR genes in wheat and differential expression under abiotic stress conditions

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Scientists identified 149 genes related to phytosulfokine receptors (PSKR) in wheat that help plants respond to environmental stresses like drought, salt, cold, and heat. These genes are spread across wheat’s chromosomes and contain regulatory elements that control their expression in response to various stresses and plant hormones. The study provides important genetic resources for developing wheat varieties that are more resistant to environmental stress, which is crucial for maintaining crop productivity in changing climate conditions.

Decoding small peptides: Regulators of plant growth and stress resilience

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Small peptides are tiny protein-like molecules that act as chemical messengers in plants, controlling growth, development, and how plants respond to stress. Scientists have recently developed better tools to find and study these peptides, discovering they play important roles in helping plants adapt to harsh environments like drought and disease. These findings could help create crops that are more resilient and productive, addressing challenges posed by climate change and food security.

Emerging Role of Arbuscular Mycorrhizal Fungi in Sustainable Agriculture: From Biology to Field Application

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Arbuscular mycorrhizal fungi are microscopic fungi that naturally partner with plant roots to help them grow stronger and healthier. These fungi can improve crop productivity without chemical fertilizers by helping plants absorb water and nutrients, resist drought and salty soils, and fight off diseases. Scientists are now developing commercial products containing these beneficial fungi to help farmers grow crops more sustainably and organically.

Development and Transfer of Microbial Agrobiotechnologies in Contrasting Agrosystems: Experience of Kazakhstan and China

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Microbial consortia—communities of beneficial microorganisms—offer promising solutions to modern agriculture’s challenges by enhancing plant growth, improving stress tolerance, and restoring soil health. China has successfully integrated these microbial products into farming through strong government support and research infrastructure, while Kazakhstan has the scientific knowledge but faces funding and implementation challenges. This comparative study shows that adopting these technologies requires both scientific advancement and practical support systems tailored to each country’s specific needs.

Genome-Wide Characterization and Expression Profiling of Phytosulfokine Receptor Genes (PSKRs) in Triticum aestivum with Docking Simulations of Their Interactions with Phytosulfokine (PSK): A Bioinformatics Study

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This study mapped and analyzed receptor genes in wheat that respond to a natural plant hormone called phytosulfokine. Researchers identified 57 versions of these receptor genes distributed across wheat’s genome and found they are most active in roots and leaves at different growth stages. Computer modeling showed how the plant hormone binds to its receptors. These findings could help develop wheat varieties that grow better and handle stress more effectively.

Serendipita indica Enhances Drought Tolerance in Phoebe sheareri Seedlings by Improving Photosynthetic Efficiency, Stimulating the Antioxidant Defense System, and Modulating Hormone Synthesis

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Scientists discovered that inoculating seedlings of Phoebe sheareri, a valuable Chinese tree species, with a special fungus called Serendipita indica significantly improves their ability to survive drought. The fungus colonizes plant roots and enhances photosynthesis, boosts the plant’s natural antioxidant defenses, and regulates growth hormones. This research suggests a practical and biological approach to improve seedling survival in nurseries and reforestation efforts, particularly in regions affected by drought and climate change.

Arbuscular mycorrhizal networks—A climate-smart blueprint for agriculture

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Arbuscular mycorrhizal fungi are beneficial organisms that form partnerships with plant roots to improve crop health and productivity without relying heavily on synthetic chemicals. These fungal networks enhance soil health, help plants survive droughts and diseases, improve nutrient absorption, and redistribute water through the soil. By using proper farming practices like crop diversification and fungal inoculants, farmers can harness these natural networks to increase yields while reducing fertilizer costs and environmental pollution.

Melatonin-Producing Microorganisms: A Rising Research Interest in Their Melatonin Biosynthesis and Effects on Crops

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Scientists are discovering that certain microorganisms like yeast, algae, and bacteria naturally produce melatonin, the same molecule that helps humans sleep. These melatonin-producing microbes could help farmers grow healthier crops by sharing their melatonin with plants and protecting them from stress like drought and disease. This discovery offers an eco-friendly alternative to synthetic melatonin and could make agriculture more sustainable as climate change poses increasing challenges.

Disease: Drought stress