Identification of kinesin neck region as a stable alpha-helical coiled coil and its thermodynamic characterization

The kinesin heavy chain consists of an N-terminal globular domain, referred to as the motor domain, a rod-like middle region, and a C-terminal domain. In this study, the human kinesin neck region, the region adjacent to the motor domain which promotes dimerization, has been investigated. First, we predicted coiled-coil regions including the neck region by our newly devised statistical method. The sequence (335-372) was predominated by a unique heptad amphipathy. A comparison of the bacterially expressed human kinesin heavy chain fragments, K349 (1-349), a monomeric motor domain, and K379 (1-379), a dimer, by circular dichroism (CD) spectroscopy showed that K379 had more alpha-helical content. Chemically synthesized peptides, (332-349), (350-379), and (332-369), gave CD spectra with an alpha-helix-rich pattern, but the spectra varied depending on the peptide concentration. Analysis of the molar ellipticity at 222 nm indicated that those peptides were in monomer-dimer equilibria, and the dissociation isotherms established dissociation constants of 9.6 mM, 60 mu M, and 62 nM for the above peptides, respectively. Sedimentation equilibrium measurements verified that the peptide (332-369) existed as a dimeric form. These results strongly suggest that the sequence from 332 to 369 of the neck region forms an ct-helical coiled coil. The differential peptide of K349 and K379, (350-379), did not show sufficient ability to make K379 dimeric. It is likely that the region (350-379) forms a stable alpha-helical coiled coil only together with the (332-349) region. Fluorescence energy transfer studies of [Cys(363)]-(332-369) labeled with a fluorescence donor and an acceptor revealed that the peptide formed a parallel coiled coil. This coiled coil was thermodynamically stable against urea and thermal denaturation, and peptide exchange of the coiled coil was undetectable, or extremely slow, at neutral pH. The dissociation free energy was estimated to be 57.7 kJ mol(-1) at a peptide concentration of 22 mu M. These results indicate that the neck region of kinesin forms a stable coiled coil which may be important for the motility of dimeric kinesin.