The structure of the ternary Eg5-ADP-ispinesib complex.

The human kinesin Eg5 is responsible for bipolar spindle formation during early mitosis. Inhibition of Eg5 triggers the formation of monoastral spindles, leading to mitotic arrest that eventually causes apoptosis. There is increasing evidence that Eg5 constitutes a potential drug target for the development of cancer chemotherapeutics. The most advanced Eg5-targeting agent is ispinesib, which exhibits potent antitumour activity and is currently in multiple phase II clinical trials. In this study, the crystal structure of the Eg5 motor domain in complex with ispinesib, supported by kinetic and thermodynamic binding data, is reported. Ispinesib occupies the same induced-fit pocket in Eg5 as other allosteric inhibitors, making extensive hydrophobic interactions with the protein. The data for the Eg5-ADP-ispinesib complex suffered from pseudo-merohedral twinning and revealed translational noncrystallographic symmetry, leading to challenges in data processing, space-group assignment and structure solution as well as in refinement. These complications may explain the lack of available structural information for this important agent and its analogues. The present structure represents the best interpretation of these data based on extensive data-reduction, structure-solution and refinement trials.

First steps towards effective methods in exploiting high-throughput technologies for the determination of human protein structures of high biomedical value.

The EC 'Structural Proteomics In Europe' contract is aimed specifically at the atomic resolution structure determination of human protein targets closely linked to health, with a focus on cancer (kinesins, kinases, proteins from the ubiquitin pathway), neurological development and neurodegenerative diseases and immune recognition. Despite the challenging nature of the analysis of such targets, approximately 170 structures have been determined to date. Here, the impact of high-throughput technologies, such as parallel expression of multiple constructs, the use of standardized refolding protocols and optimized crystallization screens or the use of mass spectrometry to assist sample preparation, on the structural biology of mammalian protein targets is illustrated through selected examples.

Human kinetochore-associated kinesin CENP-E visualized at 17 A resolution bound to microtubules.

The highly dynamic process of cell division is effected, in part, by molecular motors that generate the forces necessary for its enactment. Several members of the kinesin superfamily of motor proteins are implicated in mitosis, such as CENP-E, which plays essential roles in cell division, including association with the kinetochore to stabilize attachment of chromosomes to microtubules prior to and during their separation. Neither the functional assembly state of CENP-E nor its direction of motion along the polar microtubule are certain. To determine the mode of interaction between CENP-E and microtubules, we have used cryo-electron microscopy to visualize CENP-E motor domains complexed with microtubules and calculated a density map of the complex to 17 A resolution by combining helical and single-particle reconstruction methods. The interface between the motor domain and microtubules was modeled by docking atomic-resolution models of the subunits into the cryoEM density map. Our results support a plus end motion for CENP-E, consistent with features of the crystallographic structure. Despite considerable functional differences from the monomeric transporter kinesin KIF1A and the oppositely directed ncd kinesin, CENP-E appears to share many features of the intermolecular interactions, suggesting that differences in motor function are governed by small variations in the loops at the microtubule interface.

Conformation of the Drosophila motor protein non-claret disjunctional in solution from X-ray and neutron scattering.

The quaternary structures of monomeric and dimeric Drosophila non-claret disjunctional (ncd) constructs were investigated using synchrotron x-ray and neutron solution scattering, and their low resolution shapes were restored ab initio from the scattering data. The experimental curves were further compared with those computed from crystallographic models of one monomeric and three available dimeric ncd structures in the microtubule-independent ADP-bound state. These comparisons indicate that accounting for the missing parts in the crystal structures for all these constructs is indispensable to obtain reasonable fits to the scattering patterns. A ncd construct (MC6) lacking the coiled-coil region is monomeric in solution, but the calculated scattering from the crystallographic monomer yields a poor fit to the data. A tentative configuration of the missing C-terminal residues in the form of an antiparallel beta-sheet was found that significantly improves the fit. The atomic model of a short dimeric ncd construct (MC5) without 2-fold symmetry is found to fit the data better than the symmetric models. Addition of the C-terminal residues to both head domains gives an excellent fit to the x-ray and neutron experimental data, although the orientation of the beta-sheet differs from that of the monomer. The solution structure of the long ncd construct (MC1) including complete N-terminal coiled-coil and motor domains is modeled by adding a straight coiled-coil section to the model of MC5.

The overall conformation of conventional kinesins studied by small angle X-ray and neutron scattering.

The quaternary structures of several monomeric and dimeric kinesin constructs from Homo sapiens and Drosophila melanogaster were analyzed using small angle x-ray and neutron scattering. The experimental scattering curves of these proteins were compared with simulated scattering curves calculated from available crystallographic coordinates. These comparisons indicate that the overall conformations of the solution structures of D. melanogaster and H. sapiens kinesin heavy chain dimers are compatible with the crystal structure of dimeric kinesin from Rattus norvegicus. This suggests that the unusual asymmetric conformation of dimeric kinesin in the microtubule-independent ADP state is likely to be a general feature of the kinesin heavy chain subfamily. An intermediate length Drosophila construct (365 residues) is mostly monomeric at low protein concentration whereas at higher concentrations it is dimeric with a tendency to form higher oligomers.

Structural links to kinesin directionality and movement.

The kinesin motor proteins generate directional movement along microtubules and are involved in many vital processes, including cell division, in eukaryotes. The kinesin superfamily is characterized by a conserved motor domain of approximately 320 residues. Dimeric constructs of N and C class kinesins, with the motor domains at opposite ends of the heavy chain, move towards microtubule plus and minus ends, respectively. Their crystal structures differ mainly in the region linking the motor domain core to the alpha-helical coiled coil dimerization domain. Chimeric kinesins show that regions outside of the motor domain core determine the direction of movement and mutations in the linker region have a strong effect on motility. Recent work on chimeras and mutants is discussed in a structural context giving insights to possible molecular mechanisms of kinesin directionality and motility.

The crystal structure of the minus-end-directed microtubule motor protein ncd reveals variable dimer conformations.

BACKGROUND: The kinesin superfamily of microtubule-associated motor proteins are important for intracellular transport and for cell division in eukaryotes. Conventional kinesins have the motor domain at the N terminus of the heavy chain and move towards the plus end of microtubules. The ncd protein is necessary for chromosome segregation in meiosis. It belongs to a subfamily of kinesins that have the motor domain at the C terminus and move towards the minus end of microtubules. RESULTS: The crystal structure of dimeric ncd has been obtained at 2.9 A resolution from crystals with the C222(1) space group, with two independent dimers per asymmetric unit. The motor domains in these dimers are not related by crystallographic symmetry and the two ncd dimers have significantly different conformations. An alpha-helical coiled coil connects, and interacts with, the motor domains. CONCLUSIONS: The ncd protein has a very compact structure, largely due to extended interactions of the coiled coil with the head domains. Despite this, we find that the overall conformation of the ncd dimer can be rotated by as much as 10 degrees away from that of the twofold-symmetric archetypal ncd. The crystal structures of conventional kinesin and of ncd suggest a structural rationale for the reversal of the direction of movement in chimeric kinesins.

A model of the microtubule-kinesin complex based on electron cryomicroscopy and X-ray crystallography.

BACKGROUND: Motor proteins of the kinesin superfamily play an organising role in eukaryotic cells and participate in many crucial phases of the cell cycle by moving along microtubules and thereby changing the position of attached organelles. In their 'standard' form, kinesin motors are elongated heterotetrameric protein complexes composed of two identical heavy chains and two light chains; the central regions of the heavy chains intertwine, forming a coiled coil, with the globular 'heads' of the microtubule-interacting motor domains at one end. In order to understand how kinesin motors interact with and move along microtubules, we have combined electron cryomicroscopy and X-ray crystallographic data to build a model of the complex. RESULTS: Using electron cryomicroscopy and image reconstruction, we have obtained three-dimensional maps of complexes of kinesin motor domain dimers and microtubules. Motor domain dimers interact one to one with tubulin dimers, with one head attached--lying along the microtubule protofilament--and the other unattached--pointing sideways and upwards towards the microtubule plus end. Using currently available crystallographic data, we have built an atomic resolution model of the motor domain dimer, which can be successfully 'docked' into the three-dimensional framework of the maps from electron cryomicroscopy. CONCLUSIONS: Docking the atomic resolution model into the map of the microtubule-kinesin complex with the coiled coil of kinesin pointing away from the microtubule surface shows that the attached and unattached heads have similar relative positions on the microtubule and in the crystal. Three regions of the attached head appear likely to interact with the microtubule.

Crystallization and preliminary X-ray analysis of the single-headed and double-headed motor protein kinesin.

Crystals of the single-headed and double-headed kinesin motor domains of Rattus norvegicus have been grown by vapor diffusion using ammonium sulfate as the precipitant. Both crystal systems belong to the orthorhombic space group P2(1)2(1)2(1). Double-headed kinesin crystallized with unit cell constants of a = 72.2 A, b = 91.9 A, and c = 141.7 A, and so far the best crystals diffracted to a maximum resolution of 2.7 A. Using ammonium sulfate single-headed kinesin crystallized in two different crystal forms with cell constants of a = 73.1 A, b = 73.2 A, c = 84.0 A and a = 73.4 A, b = 74.1 A, c = 74.7 A, respectively. They were found to diffract to 2.1 A resolution. Crystals of monomeric kinesin were also obtained with lithium sulfate as precipitant. They have cell constants of a = 71.6 A, b = 73.7 A, and c = 74.1 A and diffract up to 1.7 A resolution.

The crystal structure of dimeric kinesin and implications for microtubule-dependent motility.

The dimeric form of the kinesin motor and neck domain from rat brain with bound ADP has been solved by X-ray crystallography. The two heads of the dimer are connected via a coiled-coil alpha-helical interaction of their necks. They are broadly similar to one another; differences are most apparent in the head-neck junction and in a moderate reorientation of the neck helices in order to adopt to the coiled-coil conformation. The heads show a rotational symmetry (approximately 120 degrees) about an axis close to that of the coiled-coil. This arrangement is unexpected since it is not compatible with the microtubule lattice. In this arrangement, the two heads of a kinesin dimer could not have equivalent interactions with microtubules.