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20 resultsShowing papers similar to The multifaceted mechanisms of microplastic inhibition of tomato plant growth: oxidative toxicity, metabolic perturbation, and photosynthetic damage
ClearThe varied effects of different microplastics on stem development and carbon-nitrogen metabolism in tomato
Researchers tested how six different types of microplastics, including both conventional and biodegradable varieties, affect tomato plant growth. All types disrupted the plants' internal structure and altered how they processed carbon and nitrogen, with PVC causing the most severe damage. Notably, biodegradable plastics like PLA and PBS were not harmless either, suggesting that switching to so-called eco-friendly plastics may not fully protect agricultural soil and food crops from microplastic contamination.
Comparative toxicological effects of traditional and biodegradable microplastics on pepper (Capsicum annuum L.): physiological and metabolomic insights
Researchers compared the toxicity of four traditional and two biodegradable microplastics on pepper plants over 60 days and found that all types inhibited growth, though through distinct mechanisms. Non-degradable polypropylene and polystyrene caused stronger growth inhibition, while biodegradable PBS microplastics triggered the most severe oxidative stress. Metabolomic analysis revealed that biodegradable and traditional microplastics each disrupt different metabolic pathways, challenging the notion that biodegradable plastics are inherently safer for agricultural ecosystems.
Mechanistic insights into the size-dependent bioaccumulation and phytotoxicity of polyethylene microplastics in tomato seedlings
Researchers investigated how polyethylene microplastics of different sizes affect tomato seedlings and found that the smallest particles (1-50 micrometers) caused the most severe damage, reducing shoot weight by 42.3% and root length by 55.1%. The study revealed that microplastic uptake and toxicity are strongly size-dependent, with smaller particles more easily absorbed and translocated through plant tissues, triggering significant oxidative stress.
Unraveling the impact of nano-microscale polyethylene and polypropylene plastics on Nicotiana tabacum: Physiological responses and molecular mechanisms
Researchers exposed tobacco plants to polyethylene and polypropylene microplastics of different sizes and found that both types suppressed plant growth in a dose-dependent manner, with polypropylene being more toxic. The microplastics disrupted photosynthesis, triggered oxidative stress, and altered hormone signaling and defense pathways in the plants. These findings demonstrate that microplastic contamination in soil can impair crop growth at the molecular level, potentially affecting agricultural productivity.
Meta-analysis reveals the combined effects of microplastics and heavy metal on plants
A meta-analysis of 57 studies found that the combined toxicity of microplastics and heavy metals on plants is driven primarily by the heavy metals, while microplastics mainly interact by inducing oxidative stress damage. Microplastic biodegradation emerged as a core factor influencing heavy metal accumulation in plants, with culture environment, heavy metal type, exposure duration, and microplastic concentration and size all playing roles.
Biodegradable microplastics affect tomato (Solanum lycopersicum L.) growth by interfering rhizosphere key phylotypes
Scientists found that biodegradable microplastics, often promoted as eco-friendly alternatives, can negatively affect tomato plant growth by disrupting beneficial soil bacteria around the roots. This suggests that even plastics designed to break down in the environment may still pose risks to agriculture and food production as they degrade into microplastic fragments.
Microplastics as emerging stressors in plants: biochemical and metabolic responses
This review examines how microplastics act as environmental stressors in plants, disrupting biochemical and metabolic processes including photosynthesis, antioxidant defenses, and nutrient uptake, with effects varying by polymer type, particle size, and concentration.
Phytotoxicity of polystyrene, polyethylene and polypropylene microplastics on tomato (Lycopersicon esculentum L.)
Researchers tested the effects of polystyrene, polyethylene, and polypropylene microplastics on tomato plant growth using hydroponic experiments at various concentrations. The study found that all three types of microplastics negatively affected seed germination, root growth, and plant development, with effects varying by plastic type and concentration. These findings suggest that microplastic contamination in agricultural settings could interfere with crop growth and food production.
Transcriptomic and metabolomic responses of maize under conventional and biodegradable microplastic stress
Researchers studied how both conventional and biodegradable microplastics affect maize at the molecular level, finding that both types altered plant metabolism and triggered stress responses. The microplastics changed how the plants handled energy, photosynthesis, and hormone signaling, with effects varying by plastic type. This is concerning for food safety because microplastic-contaminated soil could change the nutritional quality or safety of crops that people eat.
Unveiling the mechanism of micro-and-nano plastic phytotoxicity on terrestrial plants: A comprehensive review of omics approaches.
This comprehensive review examined how micro-and-nano plastics (MNPs) in terrestrial soils damage plant health by inhibiting water and nutrient uptake, reducing seed germination, impairing photosynthesis, and inducing oxidative stress. The review identified key knowledge gaps in understanding MNP phytotoxicity mechanisms and their implications for food security.
Comparing the impact of microplastics derived from a biodegradable and a conventional plastic mulch on plant performance
Researchers directly compared how microplastics from biodegradable and conventional plastic mulch films affect plant growth and found that biodegradable plastic particles actually reduced plant biomass more than conventional plastic particles in some cases. This challenges the assumption that biodegradable plastics are always safer for agriculture, since their breakdown products may still harm crops that end up in the human food supply.
Effect of Non-biodegradable and Biodegradable Microplastics on Plants from Physiological to individual levels: A Meta-analysis
This meta-analysis pools data from 180 studies to compare how biodegradable and non-biodegradable microplastics affect plant health. It found that both types can harm plant growth and physiology, which matters because contaminated crops could eventually transfer microplastics into the food supply that humans depend on.
Integrated physiological, transcriptomic, and metabolic analysis reveals the effects of nanoplastics exposure on tea plants
Researchers used physiological, transcriptomic, and metabolic analysis to assess the effects of nano/microplastics on tea plants, finding impaired photosynthesis, oxidative stress, and disrupted metabolic pathways at environmentally relevant concentrations. The study highlights risks to tea crop safety and quality from plastic pollution in agricultural soils.
Can microplastics threaten plant productivity and fruit quality? Insights from Micro-Tom and Micro-PET/PVC
Researchers grew tomato plants in soil containing environmentally realistic levels of PET and PVC microplastics and found mixed effects on plant productivity and fruit quality. While some growth parameters were affected, the microplastics also altered the mineral content of the tomatoes. This study suggests that microplastics in agricultural soil could change the nutritional profile of the food we eat.
Impact of polyvinyl chloride (PVC) microplastic on growth, photosynthesis and nutrient uptake of Solanum lycopersicum L. (Tomato)
Adding PVC microplastics to soil reduced tomato plant growth, photosynthesis, and nutrient uptake in a dose-dependent manner, even though no visible damage appeared on the leaves. At the molecular level, the microplastics disrupted genes and proteins involved in photosynthesis and nutrient absorption. This matters for food safety because microplastics in agricultural soils could reduce crop yields and potentially enter the food supply.
Polyethylene nanoplastics affected morphological, physiological, and molecular indices in tomato (Solanum lycopersicum L.)
Polyethylene nanoplastics in soil caused significant damage to tomato plants, including reduced growth, delayed flowering, lower fruit quality, and changes in DNA methylation patterns. Even at low concentrations, the nanoplastics triggered oxidative stress and altered gene expression in the plants. These findings raise concerns about food safety because nanoplastic contamination in farm soil could reduce both the yield and nutritional quality of tomatoes and potentially other food crops.
Effects of polyethylene and biodegradable microplastics on the physiology and metabolic profiles of dandelion
Researchers compared how conventional polyethylene and two "biodegradable" plastic alternatives affected dandelion plants when mixed into soil. All three types of microplastics stunted plant growth and caused oxidative stress, with conventional polyethylene being the most toxic -- showing that even so-called biodegradable plastics can harm plant health and soil ecosystems.
Micro and nanoplastics pollution: Sources, distribution, uptake in plants, toxicological effects, and innovative remediation strategies for environmental sustainability
This review examines how microplastics and nanoplastics enter plants through roots, disrupt growth and photosynthesis, and cause oxidative stress that reduces crop yields. Because these plastic particles can move through plant tissues and into edible parts, they represent a potential pathway for microplastics to enter the human food supply.
Molecular mechanisms underlying microplastics-induced inhibition of lateral root development in tomato (Solanum lycopersicum L.)
Researchers investigated how PET microplastics affect tomato seedling root development and found that exposure significantly inhibited lateral root growth, reduced chlorophyll content, and impaired photosynthesis. The study revealed that microplastics triggered oxidative stress in root tips and disrupted auxin and abscisic acid hormone signaling pathways, suggesting these molecular mechanisms underlie the observed phytotoxicity.
Effects of microplastics polluted soil on the growth of Solanum lycopersicum L.
This study tested how microplastic-contaminated soil affects tomato plant growth, finding that higher concentrations of plastic particles in soil reduced plant height, root development, and overall crop health. The results suggest that microplastic pollution in farmland could reduce food crop yields and potentially affect the quality of the produce we eat.