Yoshihiro Shinoda scite author profile

A free-standing polymer brush film with tailored thicknesses based on a colorless polydopamine (PDA) thin layer is prepared and characterized. The surface-initiated atom transfer radical polymerization (ATRP) of 2-hydroxyethyl methacrylate (HEMA) is performed on a PDA layer with thickness of ca. 6 nm, which generated an optically transparent and colorless free-standing PHEMA brush film (1.5 cm × 1.5 cm). Because the cross-linked PDA layer is used as the base for the polymer brushes, the reported method does not require cross-linking the polymer brushes. The free-standing film thicknesses of ≈16-75 nm are controlled by simply changing the ATRP reaction time. The results show that the free-standing PHEMA brush film transferred onto a plate exhibits a relatively smooth surface and is stable in any solvent.

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Nonisothermal crystallization of poly(ethylene terephthalate) and its blends in the injection‐molding process

Okamoto

Shinoda

Kinami

et al. 1995

J of Applied Polymer Sci

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SYNOPSISWe investigated the nonisothermal crystallization during the cooling process of injection molding of poly(ethy1ene terephthalate) ( P E T ) , PET/talc, and PET/Surlyn blends. We applied the isothermal crystallization parameters obtained by the Hoffman-Lauritzen theory to the kinetics of nonisothermal crystallization and then calculated the relative crystallinity X / X , as a function of the mold temperature. X/X, were nicely interpreted by calculation without eff'ect of the pressure history on crystallization in PET and PET/talc (1 wt W ) blends. In contrast, in the PET/Surlyn ( 3 wt 96) blend, crystallization occurred at a lower mold temperature than predicted by our calculation. T h e transmission electron micrograph near t h e surface of the injection-molded PETfSurlyn blend showed deformation and stretching of dispersed Surlyn particles, suggesting that orientation of the PET matrix proceeds with the flow in processing. T h e orientation o f t h e PET matrix resulted in acceleration of the crystallization in the injection molding. CC

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Toughening mechanism in a ternary polymer alloy: PBT/PC/rubber system

Okamoto

Shinoda

Kojima

et al. 1993

Polymer

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Sec-dependent Pathway and ΔpH-dependent Pathway Do Not Share a Common Translocation Pore in Thylakoidal Protein Transport

Asai¹,

Shinoda²,

Nohara³

et al. 1999

Journal of Biological Chemistry

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Thylakoidal proteins of plant chloroplasts are transported to thylakoids via several different pathways, including the ⌬pH-dependent and the Sec-dependent pathways. In this study, we asked if these two pathways utilize a common translocation pore. A fusion protein consisting of a 23-kDa subunit of the oxygen evolving complex and Escherichia coli biotin carboxyl carrier protein was biotinylated in E. coli cells and purified. When incubated with isolated pea thylakoids in the absence of avidin, the purified fusion protein was imported into the thylakoids via the ⌬pH-dependent pathway. However in the presence of avidin, the fusion protein became lodged in the thylakoid membranes, with its N terminus reaching the thylakoidal lumen, while its C-terminal segment complexed with avidin exposed on the thylakoidal surface. The translocation intermediate of the fusion protein inhibited the import of authentic 23-kDa subunit, suggesting that it occupies a putative translocation pore for the ⌬pH-dependent pathway. However the intermediate did not block import of the 33-kDa subunit of the oxygen evolving complex, which is a substrate for the Sec-dependent pathway. These results provide evidence against the possibility of a common translocation pore shared by the Sec-dependent pathway and the ⌬pH-dependent pathway.Nuclear-encoded thylakoidal proteins are synthesized in the cytosol, are imported into the chloroplast stroma, and are subsequently inserted into or translocated across the thylakoid membranes. Recent evidence has shown that thylakoidal proteins are transported to the thylakoids via several different pathways, including the Sec-dependent and the ⌬pH-dependent pathways (1, 2). In bacterial cells, secretory proteins are translocated across the cytoplasmic membrane through a channel consisting of SecY/E/G proteins with the aid of a translocation ATPase, SecA. In chloroplasts, homologues of SecA (cpSecA), SecY (cpSecY) and SecE (cpSecE) have been identified and shown to mediate transport of a class of thylakoid lumenal proteins in vitro and in vivo (3-12). Another class of thylakoid lumenal proteins is translocated across the thylakoid membranes via a transport pathway that requires ⌬pH across the thylakoid membranes as a sole energy source and Hcf106 protein in the thylakoid membranes (13-15). This ⌬pH pathway appears to have ability to translocate folded proteins that are not accepted by the Sec-dependent pathway (16 -18). Recent studies have revealed that a protein transport pathway similar to the thylakoidal ⌬pH-dependent pathway is present in bacterial cells (19 -21).Although the Sec-dependent and the ⌬pH-dependent pathways appear to utilize some pathway-specific components, they could share common translocation pore in the thylakoid membranes. In vitro competition experiments have shown that the import of a certain substrate protein into isolated thylakoids is effectively competed with saturating amounts of another competitor protein which utilizes the same thylakoidal transport pathway as the substrate protein but...

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