Project description:Plastics are emerging pollutants of great concern. Macroplastics degrade into microplastics and nanoplastics, which can accumulate in living organisms with still poorly known consequences. Nanoplastics being particulate pollutants, they are handled in animal organisms by scavenger cells such as macrophages, which are important players in the immune system. Polyethylene terephthalate is one of these plastics of concern, as it is widely used in food packaging where it releases nanoparticles. We have thus undertaken a study on the effects of true-to-life polyethylene terephthalate nanoparticles prepared from water bottles on macrophages. To this purpose, we used a combination of proteomics and targeted validation experiments. Proteomics showed important adaptive changes in the proteome in response to exposure to polyethylene terephthalate nanoparticles. These changes affected for example mitochondrial, cytoskeletal and lysosomal proteins, but also proteins implicated in immune functions. Validation experiments showed that many of these changes were homeostatic, with no induced oxidative stress and no gross perturbation of the mitochondrial function. However, polyethylene terephthalate nanoparticles induced endoplasmic reticulum stress and disturbed the immune functions of macrophages. We indeed observed a slight pro-inflammatory response (1.5-fold increase in TNF secretion). We also observed a decrease in the response to bacterial stimulation (1.6 decrease in IL-6 secretion). We also observed a 20 percent decrease in the expression of important proteins involved in immune responses such as TLR2, TLR7 or collectin 12, and a two-fold decrease in the production of lysozyme. This suggests that macrophages having ingested polyethylene terephthalate nanoparticles are less efficient in their immune functions.

Project description:Synthetic plastics, like polyethylene terephthalate (PET), have become an essential part of modern life. Many of these products are remarkably persistent in the environment, and the accumulation in the environment is recognised as a major threat. Therefore, an increasing interest has been paid to screen for organisms able to degrade and assimilate the plastic. Ideonella sakaiensis was isolated from a plastisphere, a bacterium that solely was thriving on the degradation on PET films. The processes affected by the presence of PET, terephthalic acid, ethylene glycol, ethyl glycolate, and sodium glyoxylate monohydrate was elucidated by differential proteomes. The exposure of PET and its monomers seem to affect two major pathways, the TCA cycle and the β-oxidation pathway, since multiple of the conditions resulted in an increased expression of proteins directly or indirectly involved in these pathways, underlying the importance in the degradation of PET by I. sakaiensis.

Project description:Synthetic plastics, like polyethylene terephthalate (PET), have become an essential part of modern life. Many of these products are remarkably persistent in the environment, and the accumulation in the environment is recognised as a major threat. Therefore, an increasing interest has been paid to screen for organisms able to degrade and assimilate the plastic. Ideonella sakaiensis was isolated from a plastisphere, a bacterium that solely was thriving on the degradation on PET films. The processes affected by the presence of PET, terephthalic acid, ethylene glycol, ethyl glycolate, and sodium glyoxylate monohydrate was elucidated by differential proteomes. The exposure of PET and its monomers seem to affect two major pathways, the TCA cycle and the β-oxidation pathway, since multiple of the conditions resulted in an increased expression of proteins directly or indirectly involved in these pathways, underlying the importance in the degradation of PET by I. sakaiensis.

Project description:Polyethylene terephthalate microplastics generated from disposable water bottles induce interferon signalling pathway in mouse lung epithelial cells

Project description:Long-term exposure to secondary polyethylene terephthalate nanoplastics induces carcinogenesis in vitro

Project description:Purpose: This study aimed to investigate the biological effects of PET microfibers and their underlying mechanisms in early-staged sheepshead minnows (Cyprinodon variegatus). Method: PET microfibers (about 13 μm diameter × 106 μm length) were prepared by cutting PET threads and treated to sheepshead minnow larvae at 10 and 100 mg/L for 10 days. mRNA was produced with a TruSeq Standed mRNA library kit, and sequencing using a NovaSeq6000 equipment. Results and Conclusions: Our study represents a detailed analysis of the transcriptome of sheepshead minnow larvae exposed to PET microfibers by RNA-seq technology. No acute toxicity was found in the minnow, but PET microfibers significantly produced reactive oxygen species and reduced behavioral responses of traveled distance and maximum velocity. The transcriptomic data suggested that Merkel cells (flow sensors) and corpuscles of Stannius (calcium regulator) are putative targets, which were derived from oxidative stress, sensory neuropathy, cognitive impairment, and movement disorders. These findings underscore that although PET microfibers are not directly lethal to sheepshead minnows, they could impact their survival by damaging swimming-related key genes. This study provides new insights into how PET microfibers are toxic to aquatic organisms and disrupt ecosystems beyond survival and pathological changes.

Project description:two cultures one grown on terephthalate and other on pyruvate Keywords: growth type

Project description:To get further insights on the micro-nanoplastic (MNP) effects on plants, the aim of this study was to: 1) shed light on the transcriptome changes provoked by two different polyethylene terephthalate (PET) MNPs in plant roots; 2) determine their effects on key plant growth parameters in hydroponically-cultivated Arabidopsis thaliana. MNPs of transparent (Tr-PET) and blue (Bl-PET) material caused a significant reduction in root length, while only Bl-PET significantly reduced rosette area. Plant fresh and dry weight did not change, even though various OJIP-test parameters decreased in the presence of MNPs. RNA-seq data showed that Bl-PET and, especially, Tr-PET affected gene expression in comparison to controls. Tr-PET induced starch degradation and isoprenoids, while glycolysis, trehalose metabolism and fermentation were generally repressed. Tr-PET upregulated genes involved in signaling of xenobiotics, whereas Bl-PET scarcely affected root transcriptomic profile, activating few gene categories for abiotic stresses. Regarding hormones, genes involved in ABA response were repressed, while brassinosteroid-related genes were differentially regulated by Tr-PET. Both MNPs, but especially Tr-PET, upregulated major latex protein-related genes. These results allowed to gain insight into the effects of MNP contamination in plant metabolism, identifying targets for biotechnological strategies to enhance plant tolerance and phytoremediation of these xenobiotic agents.

Project description:Degradation of polyurethane and polyethylene terephthalate by a Fusarium strain enriched from soil-plant systems

Project description:Polyethylene terephthalate (PET) is one of the most commonly used plastics, utilized in synthetic fibers, water containers, and food packaging. From the 1990s onwards, the demand for PET, and therefore its production, increased exponentially. This increased usage of PET has resulted in a staggering accumulation of undegraded plastic waste. Nearly 80% of the 6300 million tons of plastic waste that had been generated as of 2015 were accumulated in landfills or the natural environment. Moreover, the production of PET relies heavily on non‐renewable fossil fuels, exacerbating environmental concerns over its widespread use. In alignment with principles of environmental sustainability, the biotechnological upcycling of PET has recently emerged as a compelling solution. Since the discovery of PETase, a hydrolase capable of depolymerizing this polyester, enzymatic plastic breakdown is increasingly considered as a promising solution for managing PET waste. This enzyme and its improved derivatives, such as Fast‐PETase, enable the breakdown of PET into bis(2‐41 hydroxyethyl) terephthalate (BHET) and mono(2‐hydroxyethyl) terephthalate (MHET). Subsequently, the enzyme MHETase is responsible for further degradation of MHET into ethylene glycol and terephthalic acid. The metabolic capability of microorganisms to utilize these monomers of PET for growth has been explored in various biotechnological applications, especially in the context of bioremediation and bioconversion processes aimed at transforming plastic waste into useful products using genetically engineered bacteria.