Kiyotsuna Toyohara scite author profile

Poly(ethylene terephthalate) (PET) is used extensively worldwide in plastic products, and its accumulation in the environment has become a global concern. Because the ability to enzymatically degrade PET has been thought to be limited to a few fungal species, biodegradation is not yet a viable remediation or recycling strategy. By screening natural microbial communities exposed to PET in the environment, we isolated a novel bacterium, Ideonella sakaiensis 201-F6, that is able to use PET as its major energy and carbon source. When grown on PET, this strain produces two enzymes capable of hydrolyzing PET and the reaction intermediate, mono(2-hydroxyethyl) terephthalic acid. Both enzymes are required to enzymatically convert PET efficiently into its two environmentally benign monomers, terephthalic acid and ethylene glycol.

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Preparation of ultrafine fibrous zein membranes via electrospinning

Miyoshi

Toyohara

Minematsu

2005

Polymer International

117

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Zein is a protein in corn gluten meal. It has been investigated for use as a structural material because it is renewable and biodegradable. Potential applications of zein include use in coating, film and fiber. In this paper, ultrafine fibrous zein membranes were produced by electrospinning of an 80 wt% ethanol aqueous solution. The morphology of fibers was affected by parameters such as polymer concentration and electric field. As the concentration of the solution increased, wrinkled beads became fewer and fibers became thicker. Fibers were mainly generated above a polymer concentration of 21 wt% with an electric field of 15 kV. However, with a 30 kV field fibers were already generated above 18 wt%.

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Precursors in stereo-complex crystals of poly(L-lactic acid)/poly(D-lactic acid) blends under shear flow

et al. 2014

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To improve the mechanical and the thermal performance of poly(lactic acid) materials, this work focuses on the formation of stereo-complex crystals by blending poly(l-lactic acid) (PLLA) with poly(d-lactic acid) (PDLA). The resulting structure was analyzed using time-resolved in situ X-ray scattering, optical microscopy, differential scanning calorimetry and viscoelastic measurements. The objective of this study is to investigate the effect of shear flow imposed prior to crystallization on higher-order structure formation and acceleration of stereo-complex crystal growth of PLLA and PDLA blends using a wide spatial scale analysis and viscoelastic measurements. Density fluctuations of 100 nm scale were observed prior to nucleation by in situ simultaneous wideand small-angle X-ray scattering measurements. These density fluctuations grew with time and the intensity increased with increasing shear rate. Furthermore, the results revealed that the PLLA and PDLA chains were only partially interpenetrated; consequently, stereo-complex crystals could grow only in the mixed PLLA/PDLA phase. The correlation length of density fluctuation prior to nucleation was strongly dependent on the mixed phases.research papers

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Ruthenium Formyl Complexes as the Branch Point in Two- and Multi-Electron Reductions of CO2

Toyohara¹,

Nagao²,

Mizukawa³

et al. 1995

Inorg. Chem.

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Response to Comment on “A bacterium that degrades and assimilates poly(ethylene terephthalate)”

Yoshida

Hiraga

Takehana³

et al. 2016

Science

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Yang et al. suggest that the use of low-crystallinity poly(ethylene terephthalate) (PET) exaggerates our results. However, the primary focus of our study was identifying an organism capable of the biological degradation and assimilation of PET, regardless of its crystallinity. We provide additional PET depolymerization data that further support several other lines of data showing PET assimilation by growing cells of Ideonella sakaiensis. W e appreciate the Comment by Yang et al.(1) and are grateful for this opportunity to explain the context of how our work builds on previous studies. The intent of our study was to isolate and describe a microorganism that can degrade and assimilate poly(ethylene terephthalate) (PET) (2). Therefore, we only cited the pioneering works that report specific microorganisms able to grow on PET (3, 4). In a previous study, Sharon and Sharon (5) confirmed microbial PET degradation by semiisolated microorganisms, where the involvement of Nocardia species was implied by microscopic observation. However, the contribution of other microorganisms was not ruled out, nor was the possibility that the PET was degraded by the resting cells harboring PET-hydrolyzable enzymes. We identified the PET hydrolase (PETase) gene based on amino acid sequence identity with a known hydrolase from Thermobifida fusca (TfH) that exhibited PET-hydrolyzing activity (6), similar to other PET-hydrolyzing enzymes (7-10). We further referred cutinase from Humicola insolens (HiC) (11) and seven other enzymes in the supplementary materials [table S2 in (2)]. The functions of these enzymes, particularly TfH, LCC (9), and FsC (10), greatly contributed to the understanding of PETase enzymology.With the intention of isolating a specific microorganism that can use PET for growth, even if the PET is mostly in the amorphous form, the extent of crystallinity is of secondary importance. We described the motivation for using low-crystallinity (1.9%) PET and the observation that the structure of crystallized PET hampered the enzymatic hydrolysis of its ester linkages (8, 12) in our Report.Based on the proton nuclear magnetic resonance and gel permeation chromatography profiles of the degraded PET film, we concluded that the degradation by the consortium termed "no. 46" proceeded from the PET surface (2). To support this inference, we analyzed the surface of the PET film using x-ray photoelectron spectroscopy (XPS). The XPS spectrum for degraded PET film by no. 46 showed that a new peak appeared at 0.6 eV higher in binding energy than that observed for the O 1s peak of C-O-C linkage (532.5 eV), indicating the formation of the C-O-H linkage by hydrolysis of the ester linkage, which should either be of hydroxyl or carboxyl groups. To accurately determine the surface functional groups, each group was labeled with heptafluorobutyryl chloride (for -OH) and 1,1-carbonyldiimidazole (for -COOH) (13) and analyzed by XPS. Consequently, the peaks of F 1S (687.5 eV) and N 1S (398.5 eV) after degradation dramatically increased (Fig. 1A). The ...

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