Network topology – mycolab.ai

Bioremediation Potential of Rhodococcus qingshengii PM1 in Sodium Selenite-Contaminated Soil and Its Impact on Microbial Community Assembly

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This study investigated how a bacterium called Rhodococcus qingshengii PM1 can help clean up soil contaminated with selenium, a toxic element that accumulates in food chains. Using advanced genetic sequencing, researchers found that this bacterium can break down toxic selenite compounds by 63-71% within three weeks, which is much faster than natural processes. Adding the bacteria to contaminated soil also helped restore the diversity and health of the natural soil microbial communities, making it a promising tool for environmental cleanup efforts.

Characterization of spatio-temporal dynamics of the constrained network of the filamentous fungus Podospora anserina using a geomatics-based approach

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Researchers studied how a fungus called Podospora anserina adapts its growth pattern when exposed to challenging conditions like nutrient scarcity, temperature changes, and bright light. Using a novel computer mapping technique borrowed from geography, they discovered that fungi don’t just grow slower under stress—they reorganize how densely they pack their filaments. This geomatics approach revealed that different stresses cause different patterns of network densification, providing new insights into fungal survival strategies.

Research Keyword: Network topology

Bioremediation Potential of Rhodococcus qingshengii PM1 in Sodium Selenite-Contaminated Soil and Its Impact on Microbial Community Assembly

Characterization of spatio-temporal dynamics of the constrained network of the filamentous fungus Podospora anserina using a geomatics-based approach