Research Keyword: pan-genome

Population structure in a fungal human pathogen is potentially linked to pathogenicity

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Aspergillus flavus is a common fungal infection found in both hospitals and the environment. Researchers studied the genetic makeup of 300 fungal samples from patients and the environment across multiple countries. They discovered that clinical isolates cluster into specific genetic groups, with one group containing most patient-derived samples. This finding suggests that certain genetic populations of this fungus may be better adapted to infecting humans than others.

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Population structure in a fungal human pathogen is potentially linked to pathogenicity

mycolabadmin

Researchers studied 300 strains of Aspergillus flavus, a fungus that causes serious infections in people and damages crops. They found that strains causing human infections are not randomly distributed but instead belong to specific genetic groups, particularly a newly identified group called population D. This discovery suggests that certain genetic traits make some strains more likely to infect humans, providing insights that could lead to better treatments and prevention strategies.

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Population structure in a fungal human pathogen is potentially linked to pathogenicity

mycolabadmin

A. flavus is a common fungal pathogen that causes serious infections in humans and damages crops. Researchers analyzed DNA from hundreds of fungal samples collected from both infected patients and environmental sources. They found that clinical isolates cluster into specific genetic groups, especially a newly identified group called population D that contains most of the disease-causing strains. This suggests that certain genetic variations make some fungal strains more likely to infect humans than others.

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Pan-genomic characterization and structural variant analysis reveal insights into spore development and species diversity in Ganoderma

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Researchers completed the first comprehensive genome study of 15 Ganoderma (Lingzhi/Reishi) varieties, including five new Chinese strains. They discovered that specific genetic changes in the MSH4 gene dramatically increase spore production in one superior strain. These findings help explain why different Ganoderma varieties have different medicinal properties and can guide breeding of better medicinal mushroom varieties.

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