extremophile adaptation

Roles of mobile genetic elements and biosynthetic gene clusters in environmental adaptation of acidophilic archaeon Ferroplasma to extreme polluted environments

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Scientists discovered how a special acid-loving microorganism called Ferroplasma survives and thrives in highly polluted mine drainage environments rich in dangerous heavy metals. The study revealed that these microorganisms use special genetic elements like jumping genes and metabolite-producing genes to adapt to these extreme conditions, enabling them to help clean up pollution. This discovery could lead to better biological methods for treating contaminated environments and making water safer near old mining sites.

The HOG signal pathway contributes to survival strategies of the piezo-tolerant fungus Aspergillus sydowii DM1 in hadal sediments

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Scientists discovered a special deep-sea fungus from the Mariana Trench (nearly 7 miles deep) and studied how it survives extreme pressure and harsh conditions. By examining its DNA and turning off a specific gene called hog1, they found this gene is crucial for the fungus to handle stress and produce energy. Understanding how this deep-sea fungus adapts could help us develop stronger microorganisms for various applications and better understand how life survives in Earth’s most extreme environments.

Research Keyword: extremophile adaptation

Roles of mobile genetic elements and biosynthetic gene clusters in environmental adaptation of acidophilic archaeon Ferroplasma to extreme polluted environments

The HOG signal pathway contributes to survival strategies of the piezo-tolerant fungus Aspergillus sydowii DM1 in hadal sediments