Ideonella sakaiensis sp. nov., isolated from a microbial consortium that degrades poly(ethylene terephthalate)

Tanasupawat, Somboon; Takehana, Toshihiko; Yoshida, Shosuke; Hiraga, Kazumi; Oda, Kōhei

doi:10.1099/ijsem.0.001058

Cited by 137 publications

(100 citation statements)

References 25 publications

(20 reference statements)

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“…Further studies led to the discovery of a bacterial species that is able to metabolize amorphous PET without any assistance from other organisms in the consortium. This strain, a gram‐negative, aerobic, rod‐shaped bacterium, was found to be a new species of the genus Ideonella , and it was named Ideonella sakaiensis 201‐F6 .…”

Section: Pet and Its Recyclingmentioning

confidence: 99%

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Biodegradation of waste PET

et al. 2019

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Section: Pet and Its Recyclingmentioning

confidence: 99%

“…While consortium No. 46 includes PET‐degrading I. sakaiensis 201‐F6 , other bacteria with specialized functions involved in PET degradation were isolated and characterized. Initially, Bacillus megaterium forms a biofilm on the PET film.…”

Section: Pet and Its Recyclingmentioning

confidence: 99%

Biodegradation of waste PET

et al. 2019

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“…Bacterial community structure was assessed via 16S rRNA gene sequencing obtained from the inoculum as well as from all ve treatments across six weeks of incubation (i.e. days 1,3,7,14,21,30,42), including separate analysis of planktonic and bio lm communities grown with the amorphous PET lms. Only two samples (replicate 2 from day 42 amorphous PET bio lm and replicate 1 from day 42 PET powder) as well as procedural controls (i.e.…”

Section: Microbial Community Succession On Petmentioning

confidence: 99%

“…One particularly noteworthy exception to this is in the degradation of polyethylene terephthalate (PET), where a number of PET hydrolases, termed PETases, have been identi ed [13]. The PETase that has garnered the most attention to date is that of the bacterium Ideonella sakaiensis, a terrestrial Betaproteobacterium isolated from outside a plastic bottle factory [14,15]. This PETase is different from other similar esterases as it exhibits higher hydrolytic activity on PET than other substrates and is active at lower temperatures.…”

Section: Introductionmentioning

confidence: 99%

A Multi-OMIC Characterisation of Biodegradation and Microbial Community Succession Within the PET Plastisphere

Wright

Bosch

Langille

et al. 2020

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BackgroundPlastics now pollute marine environments across the globe. On entering these environments, plastics are rapidly colonised by a diverse community of microorganisms termed the Plastisphere. Members of the Plastisphere have a myriad of diverse functions typically found in any biofilm but, additionally, a number of marine Plastisphere studies have claimed the presence of plastic-biodegrading organisms, although with little mechanistic verification. Here we obtained a microbial community from marine plastic debris and analysed the community succession across six weeks of incubation with different polyethylene terephthalate (PET) products as the sole carbon source, and further characterised the mechanisms involved in PET degradation by two bacterial isolates from the Plastisphere. ResultsWe found that all communities differed significantly from the inoculum and were dominated by Gammaproteobacteria, i.e. Alteromonadaceae and Thalassospiraceae at early time points, Alcanivoraceae at later time points and Vibrionaceae throughout. The large number of encoded enzymes involved in PET degradation found in predicted metagenomes and the observation of polymer oxidation by FTIR analyses both suggested PET degradation was occurring. However, we were unable to detect intermediates of PET hydrolysis with metabolomic analyses, which may be attributed to their rapid depletion by the complex community. To further confirm the PET biodegrading potential within the Plastisphere of marine plastic debris, we used a combined proteogenomic and metabolomic approach to characterise amorphous PET degradation by two novel marine isolates, Thioclava sp. BHET1 and Bacillus sp. BHET2. The identification of PET hydrolytic intermediates by metabolomics confirmed that both isolates were able to degrade PET. High-throughput proteomics revealed that while Thioclava sp. BHET1 used the degradation pathway identified in terrestrial environment counterparts, these were absent in Bacillus sp. BHET2, indicating that either the enzymes used by this bacterium share little homology with those characterised previously, or that this bacterium uses a novel pathway for PET degradation. ConclusionsOverall, the results of our multi-OMIC characterisation of PET degradation provide a significant step forwards in our understanding of marine plastic degradation by bacterial isolates and communities and evidences the biodegrading potential extant in the Plastisphere of marine plastic debris.

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“…Microorganisms known for their biodegradable ability to decompose different type of resistant compounds of hydrocarbon origin (Rusyn et al, 2003;Glaser et al, 2019;Ghatge et al, 2020) expand the possibilities of using compounds with long-term decomposition in the environment. The use of PET in the shell of the fertilizer in the minimum amount has prospects due to the isolation from the media exposed to PET, the bacteria Ideonella sakaiensis 201-F6, which are able to use PET as the main source of energy and are capable to biodegradation of environmentally stable polymer in 1.5-2 vegetation period (Tanasupawat et al, 2016;Danso et al, 2018;Liu et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Effect of mineral fertilizer encapsulated with zeolite and polyethylene terephthalate on the soil microbiota, pH and plant germination

Rusyn

Malovanyy

Tymchuk

et al. 2020

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Environmental risks caused by the use of traditional mineral fertilizers require new agro-technical solutions, which are encapsulated long-acting fertilizers. The use of the capsule allows to reduce the concentration of mineral compounds in the fertilizer and to minimize the adverse effects of the chemical compounds contained in it on the environment. Encapsulated fertilizers provide more efficient absorption of mineral nutrition by plants, allowing to synchronize the release of elements in accordance with the needs of the plant. The use of natural materials as fertilizer shells is faced with the problem of their low solubility and cost, and the use of synthetic coatings with the problems of their biodegradation in the environment. The development of new environmentally friendly materials for long-acting fertilizer capsules is a challenge for modern society. In this context, a universal mineral fertilizer coated with a coating of natural zeolite sorbent and diethylene glycol (DEG) modified polyethyl terephthalate (PET) is promising. We analyzed the influence of fertilizer on the kinetics of soil pH change, the dynamics of the total microbial count and the increase in the number of microorganisms and the germination of Hordeum sativum and Lolium perenne. The application of fertilizer for 28 days of the experiment led to decrease in soil pH by 0.3. In the presence of encapsulated fertilizer the germination of ryegrass seeds was 3.51 times higher, and ones of barley 4.14 times higher than without fertilizer. The fertilizer provided a prolonged release of minerals, which had a positive effect on the germination of barley and ryegrass plants, stimulated plant growth and increased the total number of microorganisms in the soil as an important indicator of the efficiency of agricultural technology.

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Ideonella sakaiensis sp. nov., isolated from a microbial consortium that degrades poly(ethylene terephthalate)

Cited by 137 publications

References 25 publications

Biodegradation of waste PET

Biodegradation of waste PET

A Multi-OMIC Characterisation of Biodegradation and Microbial Community Succession Within the PET Plastisphere

Effect of mineral fertilizer encapsulated with zeolite and polyethylene terephthalate on the soil microbiota, pH and plant germination

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