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61,005 resultsShowing papers similar to The plant microbiota signature of the Anthropocene as a challenge for microbiome research
ClearSymbiosis and the Anthropocene
Researchers examined how human-driven environmental changes in the Anthropocene — the current era defined by humanity's outsized impact on Earth — are disrupting symbiotic relationships between organisms that ecosystems depend on. The review argues that symbioses, from coral-algae partnerships to gut microbiomes, are keystone processes that must be considered when assessing how pollution, climate change, and habitat loss reshape entire ecosystems.
Plant pathogenesis: Toward multidimensional understanding of the microbiome
This review explores how the full community of microorganisms on a plant, not just single pathogens, contributes to plant disease. The authors introduce the concept of a 'pathobiome,' the disease-promoting portion of a plant's microbiome that can be influenced by environmental stressors. While not directly about microplastics, the findings are relevant because soil microplastic contamination can alter plant-associated microbial communities in ways that may promote crop diseases.
Improving the assessment of ecosystem and wildlife health: microbiome as an early indicator
Researchers reviewed evidence that the microbiome — the community of microorganisms living in environments and within animals — can serve as an early warning system for ecosystem disturbance, rapidly reflecting the impact of human activities before other signs of harm are visible.
Polyethylene microplastics induce microbial functional reprogramming via rhizosphere network disruption, accelerating soil decline
Researchers used metabolomics and metagenomics to study how polyethylene microplastics affect the rhizosphere ecosystem of the medicinal plant Angelica sinensis. The study found that increasing microplastic concentrations disrupted microbial network stability, shifted metabolic pathways toward stress adaptation, and reduced soil quality, with bacteria serving as primary regulatory hubs in mediating these ecosystem-level changes.
The evolution of bacterial pathogens in the Anthropocene
Researchers reviewed how anthropogenic environmental changes — including plastic pollution — may accelerate bacterial pathogen evolution by altering mutation rates, horizontal gene transfer, and selection pressures, using the microplastic plastisphere as a case study for how pollution can drive microbial diversification with implications for human infection risk.
The Impact of Metolachlor Applications and Phytoremediation Processes on Soil Microorganisms: Insights from Functional Metagenomics Analysis
This paper is not about microplastics — it studies how phytoremediation plants affect soil microbial biodiversity in fields contaminated with the herbicide metolachlor, with no connection to microplastic pollution.
Rhizosphere microbial activities in response to combined effects of drought and microplastic
Researchers studied how combined drought stress and microplastic contamination affect rhizosphere microbial activities, finding that microplastics exacerbated drought-induced suppression of soil enzyme activities and altered microbial community structure around plant roots.
Micro and nano-plastics on environmental health: a review on future thrust in agro-ecotoxicology management
This review examines the growing body of evidence on how microplastics and nanoplastics affect plant health, soil microbial communities, and agricultural productivity. The study highlights that plastic accumulation in agricultural soils can alter crop growth and yield while disrupting soil ecosystem dynamics, and calls for greater attention to agro-ecotoxicology management to address these emerging threats to food production.
Host species and microplastics differentiate the crop root endophytic antibiotic resistome
Researchers found that crop species and microplastic contamination significantly shape the antibiotic resistance gene profile in plant root endophytes, with microplastics enhancing resistance gene abundance via changes in root-associated microbial communities.
Plant-driven strategies for mitigating microplastic pollution in agricultural ecosystems
Researchers review how microplastics damage agricultural soils and crops — disrupting soil structure, starving plants of nutrients, and triggering oxidative stress — and explore plant- and microbe-based strategies like root-associated bacteria and biochar amendments as promising but underexplored tools for cleaning up plastic-contaminated farmland.
Chemical pollution and microbiomes responses
This paper reviewed how chemical pollution affects microbial community composition and function across different environments. Exposure to pollutants including plastics, heavy metals, and pesticides can disrupt microbial diversity and the ecosystem services microbes provide. The review calls for greater integration of microbiome science into environmental risk assessment.
Rhizospheric bacterial communities against microplastics (MPs): Novel ecological strategies based on the niche differentiation
Researchers studied how bacterial communities living around plant roots adapt when exposed to microplastics in soil. They found that rhizosphere bacteria developed distinct survival strategies depending on their ecological niche, with some species thriving while others declined in the presence of plastics. The study reveals that microplastics can reshape the microbial communities that plants depend on for nutrient uptake and disease resistance.
Review Article: Ecotoxicological Impacts of Pollution on Biodiversity and Ecosystem Health in the Anthropocene
This review examines how Anthropocene-era pollutants—heavy metals, pesticides, pharmaceuticals, and microplastics—enter ecosystems, bioaccumulate through food chains, and threaten biodiversity and ecosystem functionality.
Impact of Nanoplastic Contamination on Rhizosphere Microbiome and Plant Phenotype
This study examined how nanoplastic contamination affects the rhizosphere microbiome (soil bacteria around plant roots) and plant growth. Nanoplastic exposure altered soil microbial communities and reduced plant growth, suggesting these tiny plastic particles could disrupt the soil ecosystems that support food production.
Impact of microplastics on terrestrial ecosystems: A plant-centric perspective
This review focuses on how microplastics affect plants and soil health in agricultural settings, an area that has received less attention than marine microplastic pollution. The researchers describe how microplastics can alter soil structure, disrupt microbial communities, and enter plant tissues through unique transport mechanisms. The study highlights that agricultural soils are a major sink for microplastics, with potential consequences for food safety and crop productivity.
Unveiling the hidden world of microorganisms and their impact on the Earth's ecosystems
This paper is not directly about microplastics; it is a broad review of microbial ecology covering microorganism roles in biogeochemical cycling of carbon, nitrogen, phosphorus, sulfur, and metals, and how advances in genomics have transformed our understanding of microbial community diversity and function.
‘OMICS’ Studies on Rhizosphere-Microorganism Interactions in Soils
This review covers OMICS approaches—genomics, transcriptomics, proteomics, metabolomics—used to study how plant root microbiomes interact with soil in the context of pollutants including microplastics and heavy metals. It highlights how rhizosphere microorganisms mediate phytoremediation and discusses multi-resistance challenges when pharmaceuticals and pesticides co-contaminate soils.
Bioinformatic study of the soil microbiome under different cropping systems
This doctoral thesis compares soil microbial communities across different cropping systems using bioinformatics and next-generation sequencing, identifying how intensive agricultural practices degrade soil biodiversity. Healthy soil microbiomes are critical for crop productivity and may influence how soils respond to emerging pollutants like microplastics.
Microbiomes of the Aquatic Environment
This review examines the diversity and ecological roles of microbial communities in aquatic environments, covering microbiomes associated with aquatic insects, plants, fish, phytoplankton, macrophytes, and microplastics, and their interconnected functions in nutrient cycling and primary production. The authors discuss how climate change, eutrophication, and pollution are shifting microbial community composition in ways that threaten the functioning of freshwater and marine ecosystems.
Microplastics in terrestrial ecosystem: Exploring the menace to the soil-plant-microbe interactions
This review summarizes existing research on how microplastics affect the complex relationships between soil, plants, and soil microbes. Microplastics alter soil structure, change the makeup of microbial communities, and disrupt beneficial partnerships between plants and helpful fungi and bacteria. These disruptions can reduce plant growth and nutrient cycling, which could ultimately affect crop yields and the quality of food produced on microplastic-contaminated farmland.
Unearthing soil-plant-microbiota crosstalk: Looking back to move forward
This review examines the complex interactions between soil, plants, and microbiota, tracing the evolution of soil fertility assessment from crop performance metrics to modern microbiome-based approaches. Researchers emphasize that soil quality must be evaluated by combining physical, chemical, and biological parameters, and that understanding microbial community dynamics is essential for sustainable agriculture and ecosystem health.
Regulatory Mechanisms of Plant Growth-Promoting Bacteria in Alleviating Microplastic and Heavy Metal Combined Pollution: Insights from Plant Growth and Metagenomic Analysis
Researchers used metagenomic sequencing to investigate how plant growth-promoting bacteria (PGPB) mitigate the combined toxicity of microplastics and heavy metals on plant growth. PGPB inoculation restored rhizosphere microbial function and reduced plant stress, revealing microbiome-mediated mechanisms for alleviating mixed pollutant toxicity.
Unlocking secrets of microbial ecotoxicology: recent achievements and future challenges
This review explores how microorganisms interact with environmental pollutants, including microplastics, covering how bacteria can break down pollutants but are also harmed by them. The authors highlight that microplastics create new surfaces in the environment where bacteria form communities, potentially spreading harmful species or antibiotic resistance. Understanding these microbial interactions is critical for developing nature-based solutions to reduce pollution and protect human health.
Microplastics increase soil microbial network complexity and trigger diversity-driven community assembly
Researchers found that microplastics in soil increased bacterial network complexity and shifted microbial community assembly in a diversity-dependent manner, with high-density polyethylene causing more harm to plant growth than polystyrene or polylactic acid particles.