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20 resultsShowing papers similar to Editorial: Arbuscular Mycorrhizal Fungi: The Bridge Between Plants, Soils, and Humans
ClearArbuscular Mycorrhizal Fungi Advantageous Impact on Sustainable Agroecosystems and Bridge between Plants, Soils, and Humans Health
This review discusses how arbuscular mycorrhizal fungi enhance sustainable agroecosystems by improving plant nutrient uptake, soil structure, and stress tolerance, with implications for reducing dependence on synthetic fertilizers and improving food security. The authors explore links between mycorrhizal health, soil microbiome, and human nutrition.
Symbiosis—A Perspective on the Effects of Host Traits and Environmental Parameters in Arbuscular Mycorrhizal Fungal Richness, Colonization and Ecological Functions
This review examines how host plant traits and environmental conditions regulate the richness, diversity, and ecological functions of arbuscular mycorrhizal fungi. The study highlights how these beneficial soil fungi contribute to sustainable agriculture through improved nutrient uptake, disease control, and stress tolerance, while noting that their effectiveness depends on multiple interacting factors.
Physio-Biochemical Mechanisms of Arbuscular Mycorrhizal Fungi Enhancing Plant Resistance to Abiotic Stress
This review explores how arbuscular mycorrhizal fungi, beneficial soil organisms that form partnerships with plant roots, help crops cope with environmental stresses like drought, salinity, and heavy metal contamination. The fungi improve nutrient uptake, water absorption, and antioxidant defenses while triggering beneficial hormonal responses in host plants. The authors note that wider agricultural use of these fungi is limited by challenges in mass production and variability across different crops and soil conditions.
Mycorrhizas for a sustainable world
This review synthesizes findings from the 10th International Conference on Mycorrhiza, covering how mycorrhizal fungal associations — present in over 80% of plant species — influence nutrient cycling, ecosystem resilience, and sustainability across scales from individual plants to global ecosystems. The paper highlights research priorities including mycorrhiza-based strategies for sustainable agriculture and restoration.
Unraveling the Effects of Arbuscular Mycorrhizal Fungi on Plant Growth, Nutrient Content, and Heavy Metal Accumulation in the Contaminated Soil: A Meta-analysis
This meta-analysis of 33 studies found that arbuscular mycorrhizal fungi significantly increase heavy metal accumulation in plant roots while reducing it in above-ground tissues, effectively acting as a biofilter. AMF-inoculated plants showed enhanced growth, biomass, and nutrient uptake on polluted land, suggesting a practical bioremediation strategy for contaminated soils.
Mycorrhizal and Endophytic Fungi as a Tool for Sustainable Environments
This review examines the roles of mycorrhizal and endophytic fungi in promoting plant health and environmental sustainability, focusing on arbuscular mycorrhizal fungi, dark septate endophytes, and other endophytic types that interact with vascular plant roots. The authors assessed the potential of these fungal partnerships as tools for sustainable soil and ecosystem management.
The mycorrhizal symbiosis: research frontiers in genomics, ecology, and agricultural application
This review covers the latest advances in understanding mycorrhizal fungi, which form partnerships with plant roots to help them absorb nutrients and resist stress. While not directly about microplastics, mycorrhizal networks play a critical role in soil health, and research shows that microplastic contamination in soil can disrupt these beneficial fungal partnerships. Healthy mycorrhizal networks may also help buffer plants against some negative effects of soil pollutants, including microplastics.
Potential Effects of Microplastic on Arbuscular Mycorrhizal Fungi
This review examines how microplastics in soil affect arbuscular mycorrhizal fungi, finding evidence that microplastics can alter fungal colonization of plant roots, spore production, and the broader soil microbiome, with cascading effects on plant nutrient uptake.
Arbuscular mycorrhizal fungi attenuate negative impact of drought on soil functions
A meta-analysis combined with greenhouse experiments demonstrated that arbuscular mycorrhizal fungi promote soil aggregation, microbial biomass, and nutrient-cycling enzyme activity, effectively buffering soil functions against drought. This protective effect is relevant to microplastic concerns because soil health is increasingly threatened by plastic pollution, and understanding natural soil defense mechanisms is important for protecting agricultural ecosystems.
Arbuscular Mycorrhizal Fungi Can Inhibit the Allocation of Microplastics from Crop Roots to Aboveground Edible Parts
Scientists discovered that beneficial soil fungi called arbuscular mycorrhizal fungi can reduce the amount of microplastics that travel from plant roots into the edible parts of lettuce. Plants grown with these fungi transported significantly fewer plastic particles to their leaves compared to plants without them. The findings suggest that natural fungal partnerships in soil could serve as a biological barrier helping protect food crops from microplastic contamination.
Nurturing with Nature: The Efficacy of Arbuscular Mycorrhizal Fungi Microbe for Cocoa Sector Environmental Management in Ghana
Researchers tested the efficacy of arbuscular mycorrhizal fungi inoculation for improving plant establishment and soil health in revegetation of degraded land, finding that mycorrhizal treatments increased plant biomass, root development, and soil nutrient cycling compared to uninoculated controls. The study supports the use of mycorrhizal bioinoculants as a nature-based tool for ecological restoration.
The Interaction between Arbuscular Mycorrhizal Fungi (AMF) and Grass Endophyte (Epichloë) on Host Plants: A Review
This review examines the interactions between arbuscular mycorrhizal fungi and grass endophytes when both colonize the same host plants. The study suggests that understanding how these two symbiotic fungi interact could have important implications for agricultural production and ecological conservation strategies.
Effects of microplastic types and shapes on the community structure of arbuscular mycorrhizal fungi in different soil types
Researchers examined how different types and shapes of microplastics affect arbuscular mycorrhizal fungi communities across various soil types. The study found that microplastics alter soil structure and chemistry in ways that disrupt these beneficial fungi, which play crucial roles in nutrient exchange, soil stability, and water movement.
Effects of microplastics on the plant-arbuscular mycorrhizal fungal symbiotic system: type, size, and concentration
This review examines how different types, sizes, and concentrations of microplastics affect the symbiotic relationship between plants and arbuscular mycorrhizal fungi in soil. The study found that low microplastic concentrations may stimulate fungal colonization, while higher levels generally inhibit it, and that biodegradable microplastics and nanoplastics tend to have stronger effects on the plant-fungal system than conventional microplastics.
Arbuscular mycorrhizal network-mediated allelochemical transfer: a critical hypothesis of juglone-walnut case and its ecological implications
This review paper summarizes research on how underground fungal networks might help walnut trees spread toxic chemicals that kill nearby plants. The fungi that live on plant roots could act like underground highways, carrying these plant-killing chemicals farther than previously thought. Understanding this process could help farmers grow walnut trees alongside other crops more successfully by managing these helpful fungi.
Bidirectional interference between nanoplastics and arsenic in arbuscular mycorrhizal symbiosis: Reciprocal modulation of uptake, transformation and translocation
Researchers used a dual-compartment culture system to show that nanoplastics and arsenic interfere with each other inside arbuscular mycorrhizal fungi, where nanoplastics reduce arsenic uptake by fungal hyphae while promoting its conversion to less toxic organic forms, and the fungi in turn internalize and translocate nanoplastics — revealing potential for fungal-based remediation of co-contaminated soils.
Synergistic Reduction of Arsenic Uptake and Alleviation of Leaf Arsenic Toxicity in Maize (Zea mays L.) by Arbuscular Mycorrhizal Fungi (AMF) and Exogenous Iron through Antioxidant Activity
Researchers studied whether combining a beneficial soil fungus (arbuscular mycorrhizal fungi) with iron supplements could help protect corn plants from arsenic contamination in soil. They found that using both together significantly reduced arsenic uptake in the plants while boosting growth, phosphorus absorption, and antioxidant defenses in the leaves. The study suggests that this combined biological and mineral approach could help make crops safer to grow in arsenic-contaminated farmland.
Migration and accumulation of microplastics in soil-plant systems mediated by symbiotic microorganisms and their ecological effects
This study found that beneficial soil fungi (mycorrhizal fungi) actually accelerate the uptake of smaller microplastics by plant roots while slowing the uptake of larger ones. The microplastics disrupted the symbiotic relationship between the fungi and plants, reducing plant nutrient absorption and growth, which matters because crops grown in microplastic-contaminated soil may be less nutritious.
Arbuscular mycorrhizal fungi enhance maize cadmium resistance and reduce translocation: Dependence on microplastics concentration
Researchers investigated how beneficial soil fungi called arbuscular mycorrhizal fungi can help maize plants resist cadmium toxicity in soils contaminated with both microplastics and heavy metals. They found that high concentrations of polyethylene microplastics worsened cadmium toxicity, but inoculation with mycorrhizal fungi significantly improved plant growth, nutrient uptake, and photosynthesis. The study suggests that these fungi could serve as a biological tool for managing crop health in soils with combined microplastic and heavy metal contamination.
Arbuscular mycorrhizal fungi and glomalin mediate the effects of microplastics on soil carbon storage
Arbuscular mycorrhizal fungi and a soil protein called glomalin were found to mediate the effects of microplastics on plant growth and soil structure. This suggests that the ecological impact of microplastics in agricultural soils is shaped by the presence and health of fungal communities that support plant nutrition.