Masato Watanabe scite author profile

To elucidate the heme acquisition system in pathogenic bacteria, we investigated the heme-binding properties of the third NEAT domain of IsdH (IsdH-NEAT3), a receptor for heme located on the surfaces of pathogenic bacterial cells, by using x-ray crystallography, isothermal titration calorimetry, examination of absorbance spectra, mutation analysis, size-exclusion chromatography, and analytical ultracentrifugation. We found the following: 1) IsdH-NEAT3 can bind with multiple heme molecules by two modes; 2) heme was bound at the surface of IsdH-NEAT3; 3) candidate residues proposed from the crystal structure were not essential for binding with heme; and 4) IsdH-NEAT3 was associated into a multimeric heme complex by the addition of excess heme. From these observations, we propose a heme-binding mechanism for IsdH-NEAT3 that involves multimerization and discuss the biological importance of this mechanism.

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Block Copolymer Design for Camptothecin Incorporation into Polymeric Micelles for Passive Tumor Targeting

Opanasopit

et al. 2004

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Microstructure of FePt/Pt magneticthin films with high perpendicular coercivity

1998

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Microstructures of 50 nm thick FePt magnetic thin films deposited on Pt buffer layers with various thicknesses (0–500 nm) grown on a Fe seeded MgO (100) substrate have been studied by transmission electron microscopy to correlate them with magnetic properties. High density of planar defects such as twin and antiphase boundary are present in the FePt films. The twins observed in these films are not the {011} twins which are commonly observed in the bulk FePt magnet, but they are the {111} twins. The density and morphology of these twins drastically change depending on the composition of the FePt thin films as well as the thickness of the Pt buffer layer, while that of the antiphase boundary does not show noticeable changes. In the Pt buffer layer, a high density of dislocations is present in order to reduce the elastic strain due to a large lattice mismatch imposed between the Pt layer and the MgO substrate (about 9%). When the thickness of the Pt buffer layer is increased to 500 nm, the Pt and FePt layers show a polycrystalline microstructure having a grain size ranging from 0.3 to 2.0 μm. The origin of the magnetic hardness is discussed based on these microstructural observation results.

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Enhanced antitumor effect of camptothecin loaded in long-circulating polymeric micelles

Kawano

Watanabe

Yamamoto

et al. 2006

Journal of Controlled Release

102

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Masato Watanabe

Structural Basis for Multimeric Heme Complexation through a Specific Protein-Heme Interaction

Block Copolymer Design for Camptothecin Incorporation into Polymeric Micelles for Passive Tumor Targeting

Microstructure of FePt/Pt magneticthin films with high perpendicular coercivity

Enhanced antitumor effect of camptothecin loaded in long-circulating polymeric micelles

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