Kinesin motor proteins comprise an ATPase superfamily that goes hand in hand with microtubules in every eukaryote. The mitotic kinesins, by virtue of their potential therapeutic role in cancerous cells, have been a major focus of research for the past 28 years since the discovery of the canonical Kinesin-1 heavy chain. Perhaps the simplest player in mitotic spindle assembly, Kinesin-5 (also known as Kif11, Eg5, or kinesin spindle protein, KSP) is a plus-end-directed motor localized to interpolar spindle microtubules and to the spindle poles. Comprised of a homotetramer complex, its function primarily is to slide anti-parallel microtubules apart from one another. Based on a multi-faceted analysis of this motor from numerous laboratories over the years, we have learned a great deal about the function of this motor at the atomic level for catalysis and as an integrated element of the cytoskeleton. These data have, in turn, informed the function of motile kinesins on the whole, as well as spearheaded integrative models of the mitotic apparatus in particular and regulation of the microtubule cytoskeleton in general. We review what is known about how this nanomotor works, its place inside the cytoskeleton of cells, and its small-molecule inhibitors that provide a toolbox for understanding motor function and for anticancer treatment in the clinic.
IQGAP1 is a 190-kDa molecular scaffold containing several domains required for interaction with numerous proteins. One domain is homologous to Ras GTPase-activating protein (GAP) domains. However, instead of accelerating hydrolysis of bound GTP on Ras IQGAP1, using its GAP-related domain (GRD) binds to Cdc42 and Rac1 and stabilizes their GTP-bound states. We report here the crystal structure of the isolated IQGAP1 GRD. Despite low sequence conservation, the overall structure of the GRD is very similar to the GAP domains from p120 RasGAP, neurofibromin, and SynGAP. However, instead of the catalytic "arginine finger" seen in functional Ras GAPs, the GRD has a conserved threonine residue. GRD residues 1099 -1129 have no structural equivalent in RasGAP and are seen to form an extension at one end of the molecule. Because the sequence of these residues is highly conserved, this region likely confers a functionality particular to IQGAP family GRDs. We have used isothermal titration calorimetry to demonstrate that the isolated GRD binds to active Cdc42. Assuming a mode of interaction similar to that displayed in the Ras-RasGAP complex, we created an energy-minimized model of Cdc42⅐GTP bound to the GRD. Residues of the GRD that contact Cdc42 map to the surface of the GRD that displays the highest level of sequence conservation. The model indicates that steric clash between threonine 1046 with the phosphate-binding loop and other subtle changes would likely disrupt the proper geometry required for GTP hydrolysis.The small GTPase Ras functions as a binary switch in cell signaling processes. When bound to GTP, Ras is able to interact with effector proteins, including Raf kinase, and alter their activities. Ras signaling is terminated when bound GTP is hydrolyzed to GDP and inorganic phosphate. The basal rate of GTP hydrolysis on Ras is quite slow (ϳ1.2 ϫ 10 Ϫ4 s Ϫ1), but this rate of hydrolysis can be enhanced ϳ10 5 -fold by interaction with a GTPase-activating protein (GAP) 2 (1). Several RasGAPs have been identified to date including p120 RasGAP and neurofibromin (NF1). The Rho family of Ras-related small GTPases also function as binary switches in cell signaling processes. Whereas the intrinsic rate of GTP hydrolysis on Rho proteins is faster than Ras, this rate can also be stimulated by interaction with a RhoGAP. Examination of the structures of the GAP domains of p120RasGAP (2), neurofibromin (3), SynGAP (4), and the GAP domains from the RhoGAPs p50 RhoGAP and the Bcr homology domain of phosphatidylinositol 3-kinase (5, 6) indicates that although ostensibly different, these all-helical domains are structurally related (7).IQGAP1 was discovered by chance during an attempt to isolate novel matrix metalloproteinases (8). Analysis reveals that the protein contains several discrete domains and motifs including a region containing four isoleucine-and glutaminerich motifs (IQ repeats) and a region with sequence homology to the Ras-specific GAP domains of p120RasGAP, NF1, and
Essential in mitosis, the human Kinesin-5 protein is a target for >80 classes of allosteric compounds that bind to a surfaceexposed site formed by the L5 loop. Not established is why there are differing efficacies in drug inhibition. Here we compare the ligand-bound states of two L5-directed inhibitors against 15 Kinesin-5 mutants by ATPase assays and IR spectroscopy. Biochemical kinetics uncovers functional differences between individual residues at the N or C termini of the L5 loop. Infrared evaluation of solution structures and multivariate analysis of the vibrational spectra reveal that mutation and/or ligand binding not only can remodel the allosteric binding surface but also can transmit long range effects. Changes in L5-localized 3 10 helix and disordered content, regardless of substitution or drug potency, are experimentally detected. Principal component analysis couples these local structural events to two types of rearrangements in -sheet hydrogen bonding. These transformations in -sheet contacts are correlated with inhibitory drug response and are corroborated by wild type Kinesin-5 crystal structures. Despite considerable evolutionary divergence, our data directly support a theorized conserved element for long distance mechanochemical coupling in kinesin, myosin, and F 1 -ATPase. These findings also suggest that these relatively rapid IR approaches can provide structural biomarkers for clinical determination of drug sensitivity and drug efficacy in nucleotide triphosphatases.Allostery is important in controlled catalysis, signal transduction, and apoptosis (1). The classic view of proteins demonstrating this property (2) asserts that binding of a ligand at one site provokes conformational changes at a remote, second site. Recent studies (3) evaluating underlying mechanisms of allostery alternatively suggest that ligand binding results in selection of preexisting conformational substates. Implicit in the latter model is the principle that interactions between the orthosteric and allosteric sites are tightly linked through structure and thermodynamics (4). Active challenges in structural biology, which are central to this work, are deciphering the chemical nature of the ligand-protein interactions as well as how energy is transduced through protein structures to transmit allosteric events.Our experimental model, the human Kinesin-5 motor protein (Eg5 or KSP), plays key roles in bipolar mitotic spindle formation and is a protein target for allosteric compounds (5-7) that alter catalytic ATPase activity of the protein (8, 9). Biochemical studies demonstrate a wide concentration range of inhibition by these compounds (10 -12); there may be differences in the kinetic mechanism of allostery (13-15), and even allosteric activation (16) is possible. The best characterized inhibitors, monastrol (10) and S-trityl-L-cysteine (STC)2 (11), were uncovered from independent chemical screens.Interest in these allosteric compounds has been acute because they are potential anticancer agents. Additionally, these compo...
Background:The genome of the major malaria parasites encodes a single Kinesin-5 homolog. Results: MMV666693 is a selective allosteric inhibitor of Plasmodium Kinesin-5. Conclusion: Plasmodium Kinesin-5 is druggable and susceptible to allosteric inhibition. Significance: This is the first demonstration of allosteric control of a non-human Kinesin-5 by a small chemical and opens the door to new antimalarials.
How signals between the kinesin active and cytoskeletal binding sites are transmitted is an open question and an allosteric question. By extracting correlated evolutionary changes within 700+ sequences, we built a model of residues that are energetically coupled and that define molecular routes for signal transmission. Typically, these coupled residues are located at multiple distal sites and thus are predicted to form a complex, non-linear network that wires together different functional sites in the protein. Of note, our model connected the site for ATP hydrolysis with sites that ultimately utilize its free energy, such as the microtubule-binding site, drug-binding loop 5, and necklinker. To confirm the calculated energetic connectivity between non-adjacent residues, double-mutant cycle analysis was conducted with 22 kinesin mutants. There was a direct correlation between thermodynamic coupling in experiment and evolutionarily derived energetic coupling. We conclude that energy transduction is coordinated by multiple distal sites in the protein rather than only being relayed through adjacent residues. Moreover, this allosteric map forecasts how energetic orchestration gives rise to different nanomotor behaviors within the superfamily.
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