Etsuko Muto

Long-range cooperative binding of kinesin to a microtubule in the presence of ATP

Interaction of kinesin-coated latex beads with a single microtubule (MT) was directly observed by fluorescence microscopy. In the presence of ATP, binding of a kinesin bead to the MT facilitated the subsequent binding of other kinesin beads to an adjacent region on the MT that extended for micrometers in length. This cooperative binding was not observed in the presence of ADP or 5′-adenylylimidodiphosphate (AMP-PNP), where binding along the MT was random. Cooperative binding also was induced by an engineered, heterodimeric kinesin, WT/E236A, that could hydrolyze ATP, yet remained fixed on the MT in the presence of ATP. Relative to the stationary WT/E236A kinesin on a MT, wild-type kinesin bound preferentially in close proximity, but was biased to the plus-end direction. These results suggest that kinesin binding and ATP hydrolysis may cause a long-range state transition in the MT, increasing its affinity for kinesin toward its plus end. Thus, our study highlights the active involvement of MTs in kinesin motility.

Identification of a strong binding site for kinesin on the microtubule using mutant analysis of tubulin.

The kinesin‐binding site on the microtubule has not been identified because of the technical difficulties involved in the mutant analyses of tubulin. Exploiting the budding yeast expression system, we succeeded in replacing the negatively charged residues in the α‐helix 12 of β‐tubulin with alanine and analyzed their effect on kinesin‐microtubule interaction in vitro. The microtubule gliding assay showed that the affinity of the microtubules for kinesin was significantly reduced in E410A, D417A, and E421A, but not in E412A mutant. The unbinding force measurement revealed that in the former three mutants, the kinesin‐microtubule interaction in the adenosine 5′‐[β,γ‐imido]triphosphate state (AMP‐PNP state) became less stable when a load was imposed towards the microtubule minus end. In parallel with this decreased stability, the stall force of kinesin was reduced. Our results implicate residues E410, D417, and E421 as crucial for the kinesin‐microtubule interaction in the strong binding state, thereby governing the size of kinesin stall force.

Overexpression, purification, and functional analysis of recombinant human tubulin dimer.

Microtubules consisting of tubulin dimers play essential roles in various cellular functions. Investigating the structure–function relationship of tubulin dimers requires a method to prepare sufficient quantities of recombinant tubulin. To this end, we simultaneously expressed human α1‐ and β3‐tubulin using a baculovirus‐insect cell expression system that enabled the purification of 5 mg recombinant tubulin per litre of cell culture. The purified recombinant human tubulin could be polymerized into microtubules that glide on a kinesin‐coated glass surface. The method provides a powerful tool for in vitro functional analyses of microtubules.

Key residues on microtubule responsible for activation of kinesin ATPase

Microtubule (MT) binding accelerates the rate of ATP hydrolysis in kinesin. To understand the underlying mechanism, using charged‐to‐alanine mutational analysis, we identified two independent sites in tubulin, which are critical for kinesin motility, namely, a cluster of negatively charged residues spanning the helix 11–12 (H11–12) loop and H12 of α‐tubulin, and the negatively charged residues in H12 of β‐tubulin. Mutation in the α‐tubulin‐binding site results in a deceleration of ATP hydrolysis (kcat), whereas mutation in the β‐tubulin‐binding site lowers the affinity for MTs (K0.5MT). The residue E415 in α‐tubulin seems to be important for coupling MT binding and ATPase activation, because the mutation at this site results in a drastic reduction in the overall rate of ATP hydrolysis, largely due to a deceleration in the reaction of ADP release. Our results suggest that kinesin binding at a region containing α‐E415 could transmit a signal to the kinesin nucleotide pocket, triggering its conformational change and leading to the release of ADP.

Immunological detection of actin in the 14S ciliary dynein of Tetrahymena

The association of actin with Tetrahymena ciliary dyneins was examined using a polyclonal antibody against Tetrahymena actin. Western blotting shows that actin is present in the 14S dynein fraction, but not in the 22S dynein fraction, which comprises the outer arm. By anion‐exchange chromatography, 14S dynein can be further separated into three major fractions that contain four distinct heavy chains in total. When each fraction was tested by anti‐actin immunoblotting, all three fractions contained actin in nearly stoichiometric amounts with the heavy chain. Since Tetrahymena actin differs significantly from acting of other species, the association with inner‐arm dynein may be a conserved property of actin.

A flipped ion pair at the dynein-microtubule interface is critical for dynein motility and ATPase activation

Salt bridges at the dynein–microtubule interface couple microtubule binding to ATPase activation and thereby control the directional movement of dynein

Affinity purification and characterization of functional tubulin from cell suspension cultures of Arabidopsis and tobacco

New methods allow for efficient affinity purification of polymerization-competent tubulin from tobacco and Arabidopsis cell cultures. Microtubules assemble into several distinct arrays that play important roles in cell division and cell morphogenesis. To decipher the mechanisms that regulate the dynamics and organization of this versatile cytoskeletal component, it is essential to establish in vitro assays that use functional tubulin. Although plant tubulin has been purified previously from protoplasts by reversible taxol-induced polymerization, a simple and efficient purification method has yet to be developed. Here, we used a Tumor Overexpressed Gene (TOG) column, in which the tubulin-binding domains of a yeast (Saccharomyces cerevisiae) TOG homolog are immobilized on resin, to isolate functional plant tubulin. We found that several hundred micrograms of pure tubulin can readily be purified from cell suspension cultures of tobacco (Nicotiana tabacum) and Arabidopsis (Arabidopsis thaliana). The tubulin purified by the TOG column showed high assembly competence, partly because of low levels of polymerization-inhibitory phosphorylation of α-tubulin. Compared with porcine brain tubulin, Arabidopsis tubulin is highly dynamic in vitro at both the plus and minus ends, exhibiting faster shrinkage rates and more frequent catastrophe events, and exhibits frequent spontaneous nucleation. Furthermore, our study shows that an internal histidine tag in α-tubulin can be used to prepare particular isotypes and specifically engineered versions of α-tubulin. In contrast to previous studies of plant tubulin, our mass spectrometry and immunoblot analyses failed to detect posttranslational modification of the isolated Arabidopsis tubulin or detected only low levels of posttranslational modification. This novel technology can be used to prepare assembly-competent, highly dynamic pure tubulin from plant cell cultures.

Preparation of Dual-Color Polarity-Marked Fluorescent Microtubule Seeds

Assaying microtubule dynamics in vitro requires stabilized nucleation centers, a method to immobilize individual microtubules onto a surface, and a specialized microscope to image the microtubule. Microtubules are polar structures with different dynamic properties at the plus and minus ends. However, the dynamics of the two ends can be modified by the addition of other proteins, such as microtubule plus-end-tracking proteins (+TIPs), so that it becomes impossible to distinguish the microtubule polarity by measuring the differences in the dynamic properties of the ends alone. In this chapter, we describe a method for labeling tubulin protein with N-hydroxysuccinimide ester fluorescent dyes, enabling the formation of dual-color polarity-marked stable microtubule seeds that can be immobilized onto a microscopic cover glass for imaging by fluorescence microscopy. These seeds create functional nucleation centers for the growth of dynamic microtubules.