You Hachikubo

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.

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