Research Keyword: quantitative disease resistance

Genotype-by-genotype interactions reveal transcription patterns underlying resistance responses in Norway spruce to Heterobasidion annosum s.s

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This study examined how different types of Norway spruce trees respond to infection by a fungus that causes root rot. Researchers found that the spruce tree’s genetics are more important than the fungus’s virulence in determining disease severity. Resistant tree clones activate specific defense genes early in infection, particularly genes related to pathogen recognition, while susceptible trees mount a delayed and broader response. Understanding these genetic differences could help with breeding more resistant trees for forests.

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Genotype-by-genotype interactions reveal transcription patterns underlying resistance responses in Norway spruce to Heterobasidion annosum s.s

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Researchers studied how different spruce trees resist a wood-rotting fungus by examining which genes turn on and off during infection. They found that resistant trees quickly recognize the fungus and strengthen their cell walls, while susceptible trees have delayed responses. Interestingly, different resistant trees sometimes use different defense strategies to achieve similar protection, suggesting multiple genetic pathways can lead to the same outcome.

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Transformation of Alternaria dauci demonstrates the involvement of two polyketide synthase genes in aldaulactone production and fungal pathogenicity

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A fungus that causes leaf spots on carrots produces a toxic chemical that helps it infect plants. Scientists identified two genes responsible for making this toxin and used genetic engineering to create mutant fungi unable to produce it. When these mutant fungi tried to infect carrot plants, they were much less damaging than the normal fungus, proving the toxin is crucial for the fungus to cause disease.

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