16S rRNA amplicon sequencing

Bacterial community shifts in Fusarium-induced avocado root rot and the antagonistic potential of Bacillus siamensis NB92

mycolabadmin

Avocado plants are threatened by a fungal disease called root rot that damages roots and reduces fruit production. Researchers discovered that when avocado roots become diseased, the beneficial bacteria in the soil around the roots decrease significantly. They isolated a beneficial bacterium called Bacillus siamensis NB92 from healthy avocado soil that can fight against the disease-causing fungus by producing special compounds. When applied to diseased soil, this bacterium reduced the fungal pathogen and protected avocado stems from damage, offering a natural alternative to chemical treatments.

Identification of bacterial communities associated with needle mushroom (Flammulina filiformis) and its production environment

mycolabadmin

Researchers studied the bacteria living in needle mushroom farms in China to understand which microbes help mushrooms grow well and which ones cause diseases. They found that farms in different regions have different bacterial communities, with some bacteria being beneficial while others cause rot and disease. By identifying these bacteria, the study provides information to help farmers grow healthier, safer mushrooms through better farming practices.

The Importance of Humic Acids in Shaping the Resistance of Soil Microorganisms and the Tolerance of Zea mays to Excess Cadmium in Soil

mycolabadmin

This research explores how humic acids, which are natural organic substances found in soil, can help protect plants and soil bacteria from cadmium, a toxic heavy metal. When cadmium contaminated soil, the application of humic acid preparation called Humus Active promoted the growth of specialized bacteria that can tolerate and break down cadmium. As a result, corn plants grew better and maize biomass increased significantly when the soil was treated with the humic preparation, suggesting this is a practical solution for farming on contaminated land.

Microplastic impacts archaeal abundance, microbial communities, and their network connectivity in a Sub-Saharan soil environment

mycolabadmin

This study examined how plastic waste that has broken down into tiny microplastics affects soil microorganisms in Kenya. Researchers found that microplastics reduce the number and diversity of helpful archaea (ancient microorganisms important for nitrogen cycling) and disrupt how different microbes interact with each other in soil. While microplastics carried slightly more potentially harmful bacteria, they were much better at spreading dangerous fungi, suggesting plastic waste poses a significant threat to soil health in Sub-Saharan Africa.

Rhizosphere Bacterial Communities Alter in Process to Mycorrhizal Developments of a Mixotrophic Pyrola japonica

mycolabadmin

This study explores how bacteria living around plant roots change as the plant develops its relationship with fungi. Researchers found that when fungi fully colonized plant roots in Pyrola japonica, the bacterial community became less diverse but more stable. Even after fungi died off, the bacterial community remained, suggesting these bacteria play an important long-term role in helping the plant obtain nutrients and resist diseases.

Research Keyword: 16S rRNA amplicon sequencing

Bacterial community shifts in Fusarium-induced avocado root rot and the antagonistic potential of Bacillus siamensis NB92

Identification of bacterial communities associated with needle mushroom (Flammulina filiformis) and its production environment

The Importance of Humic Acids in Shaping the Resistance of Soil Microorganisms and the Tolerance of Zea mays to Excess Cadmium in Soil

Microplastic impacts archaeal abundance, microbial communities, and their network connectivity in a Sub-Saharan soil environment

Rhizosphere Bacterial Communities Alter in Process to Mycorrhizal Developments of a Mixotrophic Pyrola japonica