Mariko Yamaki

Heterogeneities in ferritin dimers as characterized by gel filtration, nuclear magnetic resonance, electrophoresis, transmission electron microscopy, and gene engineering techniques

To understand the mechanism underlying the preferential dimerization of ferritin shells, we studied monomers and dimers from both horse spleen and recombinant horse L-apoferritin by using gel filtration, nuclear magnetic resonance, electrophoresis, transmission electron microscopy, and gene engineering techniques. Our study of the kinetics of dimer-monomer dissociation that is produced by heating revealed the presence of at least two types of dimers, namely, weakly and strongly linked dimers with activation energies of 124 +/- 14 and 157 +/- 16 kJ/mol, respectively. Our study using thiol reagents indicated that the dimerization in horse spleen ferritin is partially mediated by disulfide bridges being formed between H-chains. Our analysis of the components that resulted from the dimer-monomer dissociation further clarified that these dimers form interdigitation structures. In summary, five types of dimers were identified in horse spleen apoferritin: reversible dimers with very weak interaction, non-sulfide dimers with weak interaction, non-sulfide dimers with strong interaction, disulfide dimers linked only by disulfide bridges, and disulfide dimers linked by disulfide bridges and having other interactions.

Fibrous textured surface of an ultrafiltration membrane delineated by atomic force microscope

The resolution of atomic force microscopy (AFM) is limited by the aspect ratio and bluntness of the currently available probe tips. With the use of electron beam deposition, the apex of an existing tip was modified, resulting in a sharp probe tip with a high aspect ratio. Application of AFM to an ultrafiltration membrane, using the modified tip, revealed numerous pores in a randomly aligned fibrous matrix. Such features were not depicted either by AFM with a commercial cantilever or by scanning electron microscopy.

Wheat germ agglutinin-reactive chains of giant hemoglobin from the polychaete Perinereis aibuhitensis.

Wheat germ agglutinin-reactive chains of multisubunit extracellular hemoglobin from the polychaete Perinereis aibuhitensis were identified to clarify the carbohydrate gluing which is the carbohydrate-dependent supramolecular architecture of the hemoglobin (Ebina S. et al. (1995) Proc. Natl. Acad. Sci. USA 92, 7367-7371). Electron microscope micrographs of Perinereis hemoglobin showed a characteristic shape of two-tiered hexagonal rings whose diameter and height were determined to be 29.4 +/- 1.7 nm and 20.0 +/- 1.8 nm, respectively. Four types of globins and two types of linkers were isolated from the giant hemoglobin by reverse-phase chromatography and SDS-PAGE. These constituents showed similar NH2-terminal sequences as those previously reported for corresponding chains of Tylorrhynchus hemoglobin (Suzuki T. and Gotoh T. (1986) J. Biol. Chem. 261, 9257-9267; Suzuki T. et al. (1990) J. Biol. Chem. 265, 12168-12177). Thus, each globin of Perinereis hemoglobin was identified in terms of amino acid sequence homology and designated using names common to Tylorrhynchus hemoglobin, namely, a, A, b, and B. The linkers were stained by horseradish peroxidase (HRP)-lectins and PAS staining kits, indicating the presence of carbohydrate oligomers. Lectin staining was also significantly positive to globins a and A, which belong to strain A, but negative to globins b and B, which belong to strain B. Results showed that linkers and globins of strain A had a site in a carbohydrate oligomer to which wheat germ agglutinin (WGA) could bind. On the other hand, an alignment between known amino acid sequences of annelid globins and linkers and the sequences of lectins revealed that only the domain of the cysteine-rich motif in linkers has a homology with WGA-type lectins. The results of this study clarify the structuring mechanism of a supramolecule by lectin-like binding, called carbohydrate gluing.

Stability of two-dimensional crystalline aggregates of a protein studied by molecular dynamics

Two‐dimensional protein (ferritin) aggregates with a square lattice symmetry, which were formed within a thin liquid layer on a mercury surface, were studied by molecular dynamics (MD) simulation. For the simulation, the ferritin molecule was modeled by an assembly of 49 spheres, and the intermolecular interactions were given by simple formulae. During the simulation, molecules were confined within a layer, which corresponds to the thin liquid layer. An annealing MD simulation was done starting from a random molecular configuration within the layer, and aggregates with the square lattice symmetry were also obtained. To study the stability of aggregates, dissociation processes of the aggregates were analyzed using MD simulations at room temperature. Interactions between the nearest‐neighbor molecules were regarded as bonds. Mean bond energies and correlation coefficients between the bond energies were calculated from the MD trajectories. A decay profile according to the dissociation was obtained, yielding a dissociation rate constant. Buried bonds were stronger than peripheral bonds. The larger the aggregate size, the stronger the bond for each of the buried and peripheral bonds. A simple theoretical account, which is applicable to a general bonded network, was introduced to analyze the dynamics of the aggregates.