Research Keyword: ecosystem function

Fungal Spore Seasons Advanced Across the US Over Two Decades of Climate Change

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Scientists studied fungal spores in the air across the United States from 2003 to 2022 and found that spore seasons are starting earlier due to climate change, particularly from warmer temperatures. These airborne fungal spores can trigger allergies and asthma symptoms in sensitive people. The research shows the amount of spores in the air is decreasing, but they arrive sooner in the year, which has important implications for managing allergies and public health.

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Progression of saproxylic fungal communities in fine woody debris in boreal forests of Oulanka, Finland, assessed by DNA metabarcoding

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Researchers used a novel method called MycoPins to study how fungi colonize and break down small pieces of dead wood in Finnish boreal forests. By placing sterilized wooden pins in the soil and analyzing the fungal DNA that colonized them over a year, they identified over 200 fungal species that play important roles in wood decomposition and nutrient cycling. The study compared how fungal communities differed in forests exposed to reindeer grazing versus protected areas, revealing how land management practices influence these hidden fungal ecosystems.

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The influence of mycorrhizal hyphal connections and neighbouring plants on Plantago lanceolata physiology and nutrient uptake

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Fungi that live in soil form partnerships with plant roots and can extend underground networks connecting multiple plants. In this study, plants with access to expanded fungal networks captured more carbon through photosynthesis, accumulated more nutrients like phosphorus and zinc, and released more carbon into the soil. However, whether neighboring plants were present or what type they were did not significantly change these benefits, suggesting that soil exploration volume matters more than plant-to-plant connections through fungal networks.

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Progression of saproxylic fungal communities in fine woody debris in boreal forests of Oulanka, Finland, assessed by DNA metabarcoding

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Researchers used a novel method called MycoPins—sterilized wooden pins buried in forest soil—combined with DNA analysis to identify and track fungal communities decomposing dead wood in Finnish boreal forests. Over one year, they found 215 fungal species colonizing these pins across three different forest types. Notably, 41 of these species had never been recorded in the region before, showing that DNA-based methods can reveal fungal diversity that traditional observation methods miss.

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