Process of Accumulation of Metal Ions on the Interior Surface of apo-Ferritin: Crystal Structures of a Series of apo-Ferritins Containing Variable Quantities of Pd(II) Ions

Ueno, Takafumi; Abe, Masahiro; Hirata, Kunio; Abe, Satoshi; Suzuki, Masako; Shimizu, Nobutaka; Yamamoto, Masaki; Takata, Masaki; Watanabe, Yoshihito

doi:10.1021/ja806688s

Cited by 94 publications

(106 citation statements)

References 51 publications

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“…The cage can accommodate a number of other metal ions/ complexes or small organic molecules [19][20][21]. The pHdependent assembly/disassembly properties are advantageous with respect to encapsulation of larger metal complexes, organic molecules or nanoparticles [22,23].…”

Section: Ferritinmentioning

confidence: 99%

Use of the confined spaces of apo-ferritin and virus capsids as nanoreactors for catalytic reactions

Maity

Fujita

Ueno

2015

Current Opinion in Chemical Biology

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Self-assembled protein cages providing nanosized internal spaces which are capable of encapsulating metal ions/complexes, enzymes/proteins have great potential for use as catalytic nanoreactors in efforts to mimic confined cellular environments for synthetic applications. Despite many uses in biomineralization, drug delivery, bio-imaging and so on, applications in catalysis are relatively rare. Because of their restricted size, protein cages are excellent candidates for use as vessels to exert control over reaction kinetics and product selectivity. Virus capsids with larger internal spaces can encapsulate multiple enzymes and can mimic natural enzymatic reactions. The apo-ferritin cage is known to accommodate various metal ions/complexes and suitable for organic transformation reactions in an aqueous medium. This review highlights the importance, prospects and recent significant research on catalytic reactions using the apo-ferritin cage and virus capsids.

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Section: Ferritinmentioning

confidence: 99%

Use of the confined spaces of apo-ferritin and virus capsids as nanoreactors for catalytic reactions

Maity

Fujita

Ueno

2015

Current Opinion in Chemical Biology

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“…It is important to notice that most of the mineralization reactions that have been successfully carried out are not specific to iron, suggesting that the electrostatic character of the interior surface of the protein cage is the major player in the mineralization process. Besides the presence of an electrostatic gradient that favours the concentration of cations inside the cavity, it is of great value to have multiple metal binding/nucleation sites able to incorporate efficiently the required metal, which are likely to act as starting points and metal particle seeds for the mineralization reaction Ueno et al, 2009). Other parameters have to be taken into account for the preparation of protein-enclosed nanomaterials of biotechnological value, such as: the specific ferritin molecule to be used as a template; the oxidant/reducing agent; and the reaction conditions (i.e., ionic strength, pH, temperature, presence of chelating molecules, etc.).…”

Section: Biomimetic Synthesis Of Nanoparticles In Ferritins and Dpsmentioning

confidence: 99%

Biomimetic Materials Synthesis from Ferritin-Related, Cage-Shaped Proteins

Ceci¹,

Morea²,

Fornara³

et al. 2012

Advanced Topics in Biomineralization

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“…These Asp and His functional groups can be bound to Pd II ions with cooperative disruption of the hydrogen bonds and alterations of the conformation of coordinated amino acids in a manner similar to that which occurs at Site B of Rh·HEWL (Figure 4 a). [23] Therefore, it is suggested that these metal clusters in native proteins are formed by accumulation of aqua metal complexes. The reactions are coupled with the rearrangement of hydrogen bonds and conformational changes of amino acid residues, as observed in our model systems.…”

Section: Accumulation Mechanism Of Rhmentioning

confidence: 99%

“…The results indicate that the number of Pd II ions accumulated by apo-Fr increases when different coordination structures are adopted at the specific binding sites on the interior surface of apo-Fr. [23] However, there is only limited information about the cooperative roles of hydrogen bonds and amino-acid residues in the accumulation reactions, because the crystal structure with a high content of Pd II ions was obtained at low resolution. [23,30] If we can construct appropriate metal ion/protein surface models, we expect to gain an in-depth understanding of the accumulation mechanism.…”

Section: Introductionmentioning

confidence: 99%

“…This is possible because more flexibility is achievable with respect to reaction conditions for PPCs (including pH, and the identity and quantity of metal ions) relative to the more restrictive conditions required for working with crystals of apo-Fr containing metal ions. [23] We demonstrate a snapshot analysis of protein-mediated metal accumulation processes by using porous hen egg white lysozyme (HEWL) crystals that contain different amounts of Rh III ions to elucidate the metal accumulation mechanism, as a preorganization of metal ions for biomineralization reactions at the atomic level. HEWL, a small hydrolytic enzyme, forms a tetragonal crystal (space group P4 3 2 1 2) with different types of pores, as shown in Fig-A C H T U N G T R E N N U N G ure 1 a.…”

Section: Introductionmentioning

confidence: 99%

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Elucidation of Metal‐Ion Accumulation Induced by Hydrogen Bonds on Protein Surfaces by Using Porous Lysozyme Crystals Containing Rh^IIIIons as the Model Surfaces

Ueno

Abe

Koshiyama

et al. 2010

Chemistry A European J

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Metal-ion accumulation on protein surfaces is a crucial step in the initiation of small-metal clusters and the formation of inorganic materials in nature. This event is expected to control the nucleation, growth, and position of the materials. There remain many unknowns, as to how proteins affect the initial process at the atomic level, although multistep assembly processes of the materials formation by both native and model systems have been clarified at the macroscopic level. Herein the cooperative effects of amino acids and hydrogen bonds promoting metal accumulation reactions are clarified by using porous hen egg white lysozyme (HEWL) crystals containing Rh(III) ions, as model protein surfaces for the reactions. The experimental results reveal noteworthy implications for initiation of metal accumulation, which involve highly cooperative dynamics of amino acids and hydrogen bonds: i) Disruption of hydrogen bonds can induce conformational changes of amino-acid residues to capture Rh(III) ions. ii) Water molecules pre-organized by hydrogen bonds can stabilize Rh(III) coordination as aqua ligands. iii) Water molecules participating in hydrogen bonds with amino-acid residues can be replaced by Rh(III) ions to form polynuclear structures with the residues. iv) Rh(III) aqua complexes are retained on amino-acid residues through stabilizing hydrogen bonds even at low pH (approximately 2). These metal-protein interactions including hydrogen bonds may promote native metal accumulation reactions and also may be useful in the preparation of new inorganic materials that incorporate proteins.

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Process of Accumulation of Metal Ions on the Interior Surface of apo-Ferritin: Crystal Structures of a Series of apo-Ferritins Containing Variable Quantities of Pd(II) Ions

Cited by 94 publications

References 51 publications

Use of the confined spaces of apo-ferritin and virus capsids as nanoreactors for catalytic reactions

Use of the confined spaces of apo-ferritin and virus capsids as nanoreactors for catalytic reactions

Biomimetic Materials Synthesis from Ferritin-Related, Cage-Shaped Proteins

Elucidation of Metal‐Ion Accumulation Induced by Hydrogen Bonds on Protein Surfaces by Using Porous Lysozyme Crystals Containing Rh^IIIIons as the Model Surfaces

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Process of Accumulation of Metal Ions on the Interior Surface of apo-Ferritin: Crystal Structures of a Series of apo-Ferritins Containing Variable Quantities of Pd(II) Ions

Cited by 94 publications

References 51 publications

Use of the confined spaces of apo-ferritin and virus capsids as nanoreactors for catalytic reactions

Use of the confined spaces of apo-ferritin and virus capsids as nanoreactors for catalytic reactions

Biomimetic Materials Synthesis from Ferritin-Related, Cage-Shaped Proteins

Elucidation of Metal‐Ion Accumulation Induced by Hydrogen Bonds on Protein Surfaces by Using Porous Lysozyme Crystals Containing RhIIIIons as the Model Surfaces

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Product

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Elucidation of Metal‐Ion Accumulation Induced by Hydrogen Bonds on Protein Surfaces by Using Porous Lysozyme Crystals Containing Rh^IIIIons as the Model Surfaces