Yusuke Kato scite author profile

Abstract:What is the smallest protein? This is actually not such a simple question to answer, because there is no established consensus among scientists as to the definition of a protein. We describe here a designed molecule consisting of only 10 amino acids. Despite its small size, its essential characteristics, revealed by its crystal structure, solution structure, thermal stability, free energy surface, and folding pathway network, are consistent with the properties of natural proteins. The existence of this kind of molecule deepens our understanding of proteins and impels us to define an "ideal protein" without inquiring whether the molecule actually occurs in nature.

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AAA+ Ring and Linker Swing Mechanism in the Dynein Motor

Roberts

Numata

Walker³

et al. 2009

Cell

207

229

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SummaryDynein ATPases power diverse microtubule-based motilities. Each dynein motor domain comprises a ring-like head containing six AAA+ modules and N- and C-terminal regions, together with a stalk that binds microtubules. How these subdomains are arranged and generate force remains poorly understood. Here, using electron microscopy and image processing of tagged and truncated Dictyostelium cytoplasmic dynein constructs, we show that the heart of the motor is a hexameric ring of AAA+ modules, with the stalk emerging opposite the primary ATPase site (AAA1). The C-terminal region is not an integral part of the ring but spans between AAA6 and near the stalk base. The N-terminal region includes a lever-like linker whose N terminus swings by ∼17 nm during the ATPase cycle between AAA2 and the stalk base. Together with evidence of stalk tilting, which may communicate changes in microtubule binding affinity, these findings suggest a model for dynein's structure and mechanism.

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Numerical Study of theS=1 Antiferromagnetic Spin Chain with Bond Alternation

1994

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We study the S = 1 quantum spin chain with bond alternation H = i (1 − (−1) i δ)S i · S i+1 by the density matrix renormalization group method recently proposed by Steven R. White (Phys. Rev. Lett. 69 (1993) 3844). We find a massless point at δ c = 0.25 ± 0.01. We also find the edge states in the region δ < δ c under the open boundary condition, which disappear in the region δ > δ c . At the massless point, the spin wave velocity v s is 3.66 ± 0.10 and the central charge c is 1.0 ± 0.15.Our results indicate that a continuous phase transition occurs at the massless point δ = δ c accompanying breaking of the hidden Z 2 × Z 2 symmetry.

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Common Mechanism of Ligand Recognition by Group II/III WW Domains

Kato

Nagata

Takahashi

et al. 2004

Journal of Biological Chemistry

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WW domain is a well known protein module that mediates protein to protein interactions by binding to proline-containing ligands. Based on the ligand predilections, the WW domains have been classified into four major groups. Group II and III WW domains have been reported to bind the proline-leucine and proline-arginine motifs, respectively. In the present study, using surface plasmon resonance technique we have shown that these WW domains have almost indistinguishable ligand preferences and kinetic properties. Hence, we propose that Group II and III WW domains should be joined together as one group (Group II/III). Unlike Group I and IV WW domains, Group II/III WW domains can bind simple polyprolines as well as the proline-leucine and proline-arginine motifs, and they possess two Xaa-proline (where Xaa is any amino acid) binding grooves similar to SH3 domains. Our work assigns Group II and III WW domains to a larger family of polyproline-binding modules and proteins, which includes SH3 domains and profilin. Because polyprolines belong to the most frequently found peptide motifs in several genomes, our study implies the versatile importance of Group II/III WW domains in signaling.

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Yusuke Kato

Crystal Structure of a Ten-Amino Acid Protein

AAA+ Ring and Linker Swing Mechanism in the Dynein Motor

Numerical Study of theS=1 Antiferromagnetic Spin Chain with Bond Alternation

Common Mechanism of Ligand Recognition by Group II/III WW Domains

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