Phylogenetic Distribution of Plastic-Degrading Microorganisms

Gambarini, Victor; Pantos, Olga; Kingsbury, Joanne M.; Weaver, Louise; Handley, Kim M.; Lear, Gavin

doi:10.1128/msystems.01112-20

Cited by 104 publications

(66 citation statements)

References 83 publications

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“…1). We therefore urge authors and reviewers to confirm that these data are made accessible at the time of publication, ensuring that these data may be used for other purposes, such as in other meta-analyses 16 , the construction of databases containing known genes for plastic degradation 238,352 , or for the mining of metagenomes for plastic degradation genes 353 .…”

Section: Discussionmentioning

confidence: 99%

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<em> </em>Current Research on Microbe-Plastic Interactions in the Marine Environment

Latva¹,

Zadjelovic²,

Wright³

2021

Preprint

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The microbial colonisers of plastics – the ‘plastisphere’ – can affect all interactions that plastics have with their surrounding environments. While only specifically characterised within the last 10 years, at the beginning of 2021 there were 140 primary research and 65 review articles that investigate at least one aspect of the plastisphere. We gathered information on the locations and methodologies used by each of the primary research articles, highlighting several aspects of plastisphere research that remain understudied: (i) the non-bacterial plastisphere constituents; (ii) the mechanisms used to degrade plastics by marine isolates or communities; (iii) the capacity for plastisphere members to be pathogenic or carry antimicrobial resistance genes; and (iv) meta-OMIC characterisations of the plastisphere. We have also summarised the topics covered by the existing plastisphere review articles, identifying areas that have received less attention to date – most of which are in line with the areas that have fewer primary research articles. Therefore, in addition to providing an overview of some fundamental topics such as biodegradation and community assembly, we discuss the importance of eukaryotes in shaping the plastisphere, potential pathogens carried by plastics and the impact of the plastisphere on plastic transport and biogeochemical cycling. Finally, we summarise the future directions suggested by the reviews that we have evaluated and suggest other key research questions.

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Section: Discussionmentioning

confidence: 99%

“…Microbes' potential ability to degrade plastics seems to be well distributed across a wide range of taxa. Furthermore, the majority of putative degraders reported in degradation studies were found in soil (27.8%), followed by plastic waste dumping sites (9.6%) and finally compost (5.3%) 238 .…”

Section: Plastic Degradationmentioning

confidence: 99%

<em> </em>Current Research on Microbe-Plastic Interactions in the Marine Environment

Latva¹,

Zadjelovic²,

Wright³

2021

Preprint

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“…In April 2020, a total of 436 species reported in 1451 publications were found to degrade plastic. The three types of species that can degrade plastic that were reported most often reported among the 66 different types are Bacillus pumilus , Aspergillus fumigatus , and Phanerochaete chrysosporium , which were found to degrade 14, 11, and 10 different types of plastic, respectively [ 279 ]. Furthermore, many enzymes have been found that can hydrolyze polyesters, such lipase, esterase, protease, cutinase, PHA depolymerase, catalase, urease and glucosidases [ 280 ].…”

Section: Solutions For Ms- and Ns-caused Pollutionmentioning

confidence: 99%

Micro- and Nanosized Substances Cause Different Autophagy-Related Responses

Wang

Zheng

Lee

et al. 2021

IJMS

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With rapid industrialization, humans produce an increasing number of products. The composition of these products is usually decomposed. However, some substances are not easily broken down and gradually become environmental pollutants. In addition, these substances may cause bioaccumulation, since the substances can be fragmented into micro- and nanoparticles. These particles or their interactions with other toxic matter circulate in humans via the food chain or air. Whether these micro- and nanoparticles interfere with extracellular vesicles (EVs) due to their similar sizes is unclear. Micro- and nanoparticles (MSs and NSs) induce several cell responses and are engulfed by cells depending on their size, for example, particulate matter with a diameter ≤2.5 μm (PM2.5). Autophagy is a mechanism by which pathogens are destroyed in cells. Some artificial materials are not easily decomposed in organisms. How do these cells or tissues respond? In addition, autophagy operates through two pathways (increasing cell death or cell survival) in tumorigenesis. Many MSs and NSs have been found that induce autophagy in various cells and tissues. As a result, this review focuses on how these particles interfere with cells and tissues. Here, we review MSs, NSs, and PM2.5, which result in different autophagy-related responses in various tissues or cells.

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“…In accordance to the current literature related to phylogenetic distribution of genes encoding enzymes with potential to degrade plastics, this is one of the phylum with the highest number of fungal species that may have ability to perform biodegradation. 76 Furthermore, it is known that C. gloeosporioides interacts with cocoa plantations (Theobroma cacao) in pathogenic and endophytic associations. 55 In our LC-MS/MS analysis we detected a compound at m/z 237.1852 (D ¼ 0.14 ppm) in positive ionization mode, which was accumulated during the biodegradation process.…”

Section: Metabolites Produced During the Biodegradation Processmentioning

confidence: 99%