16S rRNA – Page 2 – mycolab.ai

The Effect of Topical Ketoconazole and Topical Miconazole Nitrate in Modulating the Skin Microbiome and Mycobiome of Patients With Tinea Pedis

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This study examined how two common antifungal creams (ketoconazole and miconazole) affect the complex community of bacteria and fungi living on the skin of people with athlete’s foot. Both treatments effectively reduced the harmful fungus causing the infection and improved symptoms, with ketoconazole working slightly faster. However, the researchers found that while these treatments reduced the disease-causing fungus, the skin’s normal microbial community did not fully recover to a healthy state, particularly in the spaces between the toes.

Root zone microbial communities of Artemisia ordosica Krasch. at different successional stages in Mu US Sandy Land: a metagenomic perspective with culturomics insights

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Researchers studied the bacteria and fungi living around the roots of a desert plant called Artemisia ordosica that helps prevent sand dunes from spreading in China. By analyzing DNA and growing microbes in the lab, they found different communities of microorganisms at different stages of sand dune recovery. Key beneficial microbes like Bacillus and Penicillium were identified, which may help the plant survive in harsh, nutrient-poor sandy soils.

Morphological, Genetic, and Microbiological Characterization of Tuber magnatum Picco Populations from “Alto Molise”, Central-Southern Italy

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Italian white truffles from the Molise region were studied to identify unique characteristics that could help verify their authenticity and origin. Researchers examined the physical features, genetic makeup, and microbial communities of truffles from four different municipalities. They discovered that truffles from certain areas share a unique genetic marker not found elsewhere in Italy, and that different populations have distinct microbial communities. These findings could help prevent truffle fraud and protect the reputation of Molise truffles in the global market.

The Expanding Truffle Environment: A Study of the Microbial Dynamics in the Old Productive Site and the New Tuber magnatum Picco Habitat

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Researchers studied how microbial communities (fungi and bacteria) develop in expanding white truffle forests compared to established productive forests in Tuscany, Italy. Over two years, they found that new forest areas have more diverse and unstable microbial communities with rapid colonization by various fungi, while older forests show more stable communities dominated by truffle-associated fungi. The study reveals how forest management practices, like selective cutting, influence the balance between fungi that break down plant material and those that form beneficial relationships with tree roots, suggesting that understanding these microbial dynamics is key to successfully expanding truffle cultivation.

The Expanding Truffle Environment: A Study of the Microbial Dynamics in the Old Productive Site and the New Tuber magnatum Picco Habitat

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This study examined the microbial communities in white truffle forests in Italy, comparing an established productive forest with a nearby expanding area. Researchers found that the expanding area had more diverse fungal communities with opportunistic species like Mortierella, while the mature forest had a more stable community dominated by ectomycorrhizal fungi. The study identified specific bacteria like Sphingomonas that showed positive associations with white truffles, suggesting these microbes may play important roles in truffle development and could help guide future cultivation efforts.

Biocontrol of Seedborne Fungi on Small-Grained Cereals Using Bacillus halotolerans Strain B33

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Researchers tested a naturally occurring soil bacterium called Bacillus halotolerans strain B33 to protect cereal seeds from harmful fungi. When seeds infected with fungal pathogens were treated with this bacterium, it successfully eliminated 83-100% of the fungi, depending on the pathogen and crop type. The treatment was as effective as commercial chemical disinfectants but offers a more environmentally friendly alternative for sustainable farming.

Mycovorax composti gen. nov., sp. nov., a member of the family Chitinophagaceae isolated from button mushroom compost

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Scientists have discovered a new type of bacteria living in button mushroom compost called Mycovorax composti. This bacterium is found in the compost during a special preparation phase and helps break down tough plant materials and fungal structures. The bacteria thrive at warm temperatures (around 45°C) and play an important role in creating a healthy environment for growing button mushrooms. This discovery helps us better understand the microbial communities that make mushroom farming possible.

Warming and Reduced Rainfall Alter Fungal Necromass Decomposition Rates and Associated Microbial Community Composition and Functioning at a Temperate–Boreal Forest Ecotone

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When soil gets warmer and drier due to climate change, dead fungal biomass breaks down faster at first but slower overall compared to normal conditions. The microorganisms that decompose this fungal material change their composition and abilities depending on how long the decomposition has been happening. This study shows that climate change affects soil carbon cycling in complex ways that depend on timing and environmental conditions.

Research Keyword: 16S rRNA