Surface topography of microtubule walls decorated with monomeric and dimeric kinesin constructs

Common mechanistic themes for the powerstroke of kinesin-14 motors

Kar3Cik1 is a heterodimeric kinesin-14 from Saccharomyces cerevisiae involved in spindle formation during mitosis and karyogamy in mating cells. Kar3 represents a canonical kinesin motor domain that interacts with microtubules under the control of ATP-hydrolysis. In vivo, the localization and function of Kar3 is differentially regulated by its interacting stoichiometrically with either Cik1 or Vik1, two closely related motor homology domains that lack the nucleotide-binding site. Indeed, Vik1 structurally resembles the core of a kinesin head. Despite being closely related, Kar3Cik1 and Kar3Vik1 are each responsible for a distinct set of functions in vivo and also display different biochemical behavior in vitro. To determine a structural basis for their distinct functional abilities, we used cryo-electron microscopy and helical reconstruction to investigate the 3-D structure of Kar3Cik1 complexed to microtubules in various nucleotide states and compared our 3-D data of Kar3Cik1 with that of Kar3Vik1 and the homodimeric kinesin-14 Ncd from Drosophila melanogaster. Due to the lack of an X-ray crystal structure of the Cik1 motor homology domain, we predicted the structure of this Cik1 domain based on sequence similarity to its relatives Vik1, Kar3 and Ncd. By molecular docking into our 3-D maps, we produced a detailed near-atomic model of Kar3Cik1 complexed to microtubules in two distinct nucleotide states, a nucleotide-free state and an ATP-bound state. Our data show that despite their functional differences, heterodimeric Kar3Cik1 and Kar3Vik1 and homodimeric Ncd, all share striking structural similarities at distinct nucleotide states indicating a common mechanistic theme within the kinesin-14 family.

Kar3Vik1 uses a minus-end directed powerstroke for movement along microtubules

We have used cryo-electron microscopy (cryo-EM) and helical averaging to examine the 3-D structure of the heterodimeric kinesin-14 Kar3Vik1 complexed to microtubules at a resolution of 2.5 nm. 3-D maps were obtained at key points in Kar3Vik1's nucleotide hydrolysis cycle to gain insight into the mechanism that this motor uses for retrograde motility. In all states where Kar3Vik1 maintained a strong interaction with the microtubule, we found, as observed by cryo-EM, that the motor bound with one head domain while the second head extended outwards. 3-D reconstructions of Kar3Vik1-microtubule complexes revealed that in the nucleotide-free state, the motor's coiled-coil stalk points toward the plus-end of the microtubule. In the ATP-state, the outer head is shown to undergo a large rotation that reorients the stalk ∼75° to point toward the microtubule minus-end. To determine which of the two heads binds to tubulin in each nucleotide state, we employed specific Nanogold®-labeling of Vik1. The resulting maps confirmed that in the nucleotide-free, ATP and ADP+Pi states, Kar3 maintains contact with the microtubule surface, while Vik1 extends away from the microtubule and tracks with the coiled-coil as it rotates towards the microtubule minus-end. While many previous investigations have focused on the mechanisms of homodimeric kinesins, this work presents the first comprehensive study of the powerstroke of a heterodimeric kinesin. The stalk rotation shown here for Kar3Vik1 is highly reminiscent of that reported for the homodimeric kinesin-14 Ncd, emphasizing the conservation of a mechanism for minus-end directed motility.

Helical structure of unidirectionally shadowed metal replicas of cyanide hydratase from Gloeocercospora sorghi

The helical filaments of the cyanide hydratase from Gloeocercospora sorghi have been reconstructed in three dimensions from freeze dried, unidirectionally shadowed specimens using iterative real-space helical reconstruction. The average power spectrum of all selected images has three clear reflections on different layer lines. The reconstruction is complicated by the fact that three possible indexing schemes are possible and reconstructions using the starting symmetries based on each of these indexing schemes converge on three-dimensional volumes which appear plausible. Because only one side is visible in shadowed specimens, it is necessary to examine the phases from a single filament by cryo-electron microscopy in order to make an unequivocal assignment of the symmetry. Because of the novel nature of the reconstruction method used here, conventional cryo-EM methods were also used to determine a second reconstruction, allowing us to make comparisons between the two. The filament is shown to have a left-handed one-start helix with D(1) symmetry, 5.46 dimers per turn and a pitch of 7.15nm. The reconstruction suggests the presence of an interaction across the groove not previously seen in nitrilase helical fibres.

The Schizosaccharomyces pombe EB1 homolog Mal3p binds and stabilizes the microtubule lattice seam

End binding 1 (EB1) proteins are highly conserved regulators of microtubule dynamics. Using electron microscopy (EM) and high-resolution surface shadowing we have studied the microtubule-binding properties of the fission yeast EB1 homolog Mal3p. This allowed for a direct visualization of Mal3p bound on the surface of microtubules. Mal3p particles usually formed a single line on each microtubule along just one of the multiple grooves that are formed by adjacent protofilaments. We provide structural data showing that the alignment of Mal3p molecules coincides with the microtubule lattice seam as well as data suggesting that Mal3p not only binds but also stabilizes this seam. Accordingly, Mal3p stabilizes microtubules through a specific interaction with what is potentially the weakest part of the microtubule in a way not previously demonstrated. Our findings further suggest that microtubules exhibit two distinct reaction platforms on their surface that can independently interact with target structures such as microtubule-associated proteins, motors, kinetochores, or membranes.

HURP wraps microtubule ends with an additional tubulin sheet that has a novel conformation of tubulin

HURP is a newly discovered microtubule-associated protein (MAP) required for correct spindle formation both in vitro and in vivo. HURP protein is highly charged with few predicted secondary and tertiary folding domains. Here we explore the effect of HURP on pure tubulin, and describe its ability to induce a new conformation of tubulin sheets that wrap around the ends of intact microtubules, thereby forming two concentric tubes. The inner tube is a normal microtubule, while the outer one is a sheet composed of tubulin protofilaments that wind around the inner tube with a 42.5 degrees inclination. We used cryo-electron microscopy and unidirectional surface shadowing to elucidate the structure and conformation of HURP-induced tubulin sheets and their interaction with the inner microtubule. These studies clarified that HURP-induced sheets are composed of anti-parallel protofilaments exhibiting P2 symmetry. HURP is a unique MAP that not only stabilizes and bundles microtubules, but also polymerizes free tubulin into a new configuration.

A structural model for monastrol inhibition of dimeric kinesin Eg5

Eg5 or KSP is a homotetrameric Kinesin-5 involved in centrosome separation and assembly of the bipolar mitotic spindle. Analytical gel filtration of purified protein and cryo-electron microscopy (cryo-EM) of unidirectional shadowed microtubule-Eg5 complexes have been used to identify the stable dimer Eg5-513. The motility assays show that Eg5-513 promotes robust plus-end-directed microtubule gliding at a rate similar to that of homotetrameric Eg5 in vitro. Eg5-513 exhibits slow ATP turnover, high affinity for ATP, and a weakened affinity for microtubules when compared to monomeric Eg5. We show here that the Eg5-513 dimer binds microtubules with both heads to two adjacent tubulin heterodimers along the same microtubule protofilament. Under all nucleotide conditions tested, there were no visible structural changes in the monomeric Eg5-microtubule complexes with monastrol treatment. In contrast, there was a substantial monastrol effect on dimeric Eg5-513, which reduced microtubule lattice decoration. Comparisons between the X-ray structures of Eg5-ADP and Eg5-ADP-monastrol with rat kinesin-ADP after docking them into cryo-EM 3-D scaffolds revealed structural evidence for the weaker microtubule-Eg5 interaction in the presence of monastrol.

Structural analysis of the ZEN-4/CeMKLP1 motor domain and its interaction with microtubules

The centralspindlin complex is required for the assembly and maintenance of the central spindle during late anaphase and the completion of cytokinesis. It is composed of two copies each of the kinesin-like protein ZEN-4, a Caenorhabditis elegans MKLP-1 (Kinesin-6 family), and the RhoGAP CYK-4. By using cryo-electron microscopy and helical 3D reconstruction, we are investigating the structural features of the interactions between monomeric and dimeric motor domain constructs of ZEN-4 and microtubules. We have calculated helically averaged 3D maps of microtubules decorated with ZEN-4 motor domain in the presence of AMP-PNP, ADP, ADP-AlF(4)(-), and nucleotide-free conditions. We used statistical difference mapping to compare these maps among each other and to related maps obtained from microtubules decorated with a well-characterized Kinesin-1 motor domain from Neurospora crassa. Thereby, we found distinct structural features in microtubule-ZEN-4 complexes that may directly relate to the functional properties of ZEN-4 and centralspindlin. Furthermore, we investigated the location, structure, and function of a highly conserved extension of approximately 50 residues unique to the Kinesin-6 subfamily, located in the motor core loop6/beta4 region.

Processive movement of single kinesins on crowded microtubules visualized using quantum dots

Kinesin-1 is a processive molecular motor transporting cargo along microtubules. Inside cells, several motors and microtubule-associated proteins compete for binding to microtubules. Therefore, the question arises how processive movement of kinesin-1 is affected by crowding on the microtubule. Here we use total internal reflection fluorescence microscopy to image in vitro the runs of single quantum dot-labelled kinesins on crowded microtubules under steady-state conditions and to measure the degree of crowding on a microtubule at steady-state. We find that the runs of kinesins are little affected by high kinesin densities on a microtubule. However, the presence of high densities of a mutant kinesin that is not able to step efficiently reduces the average speed of wild-type kinesin, while hardly changing its processivity. This indicates that kinesin waits in a strongly bound state on the microtubule when encountering an obstacle until the obstacle unbinds and frees the binding site for kinesin's next step. A simple kinetic model can explain quantitatively the behaviour of kinesin under both crowding conditions.

Coil-reinforced hydrogel tubes promote nerve regeneration equivalent to that of nerve autografts

Despite spontaneous sprouting of peripheral axons after transection injury, peripheral regeneration is incomplete and limited to short gaps, even with the use of autograft tissue, which is considered to be the "gold" standard. In an attempt to obviate some of the problems associated with autografts, including limited donor tissue and donor site morbidity, we aimed to synthesize a synthetic nerve guidance channel that would perform as well as the nerve autograft. Given that the patency of the nerve guidance channel is critical for repair, we investigated a series of nerve guidance channel designs where patency and the resulting regenerative capacity were compared in a transected rat sciatic nerve injury model. Three tube designs were compared to autograft tissue: plain, corrugated and coil-reinforced tubes of poly(2-hydroxyethyl methacrylate-co-methyl methacrylate). Of the three designs, the coil-reinforced tubes demonstrated superior performance in terms of patency. By electrophysiology and histomorphometry, the coil-reinforced tubes demonstrated outcomes that were comparable to autografts after both 8 and 16 weeks of implantation. The nerve action potential (NAP) velocity and muscle action potential (MAP) velocity for the coil-reinforced PHEMA-MMA tube was 54.6+/-10.1 and 10.9+/-1.3 m/s, respectively at 16 weeks, which was statistically equivalent to those of the autograft at 37.5+/-7.9 and 11.3+/-2.0 m/s. The axon density in the coil-reinforced tube was 2.16+/-0.61x10(4) axons/mm2, which was statistically similar to that of the autograft of 2.41+/-0.62x10(4) axons/mm2 at 16 weeks. These coil-reinforced tubes demonstrated equivalence to autografts for nerve regeneration, demonstrating the importance of channel design to regenerative capacity and more specifically the impact of patency to regeneration.

Surface-decoration of microtubules by human tau

Tau is a neuronal, microtubule-associated protein that stabilizes microtubules and promotes neurite outgrowth. Tau is largely unfolded in solution and presumably forms mostly random coil. Because of its hydrophilic nature and flexible structure, tau complexed to microtubules is largely invisible by standard electron microscopy methods. We applied a combination of high-resolution metal-shadowing and cryo-electron microscopy to study the interactions between tau and microtubules. We used recombinant tau variants with different domain compositions, (1) full length tau, (2) the repeat domain that mediates microtubule binding (K19), and (3) two GFP-tau fusion proteins that contain a globular marker (GFP) attached to full-length tau at either end. All of these constructs bind exclusively to the outside of microtubules. Most of the tau-related mass appears randomly distributed, creating a "halo" of low-density mass spread across the microtubule surface. Only a small fraction of tau creates a periodic signal at an 8 nm interval, centered on alpha-tubulin subunits. Our data suggest that tau retains most of its disordered structure even when bound to the microtubule surface. Hence, it binds along, as well as across protofilaments. Nevertheless, even minute concentrations of tau have a strong stabilizing effect and effectively scavenge unpolymerized tubulin.

Complex formation with kinesin motor domains affects the structure of microtubules

Microtubules are highly dynamic components of the cytoskeleton. They are important for cell movement and they are involved in a variety of transport processes together with motor proteins, such as kinesin. The exact mechanism of these transport processes is not known and so far the focus has been on structural changes within the motor domains, but not within the underlying microtubule structure. Here we investigated the interaction between kinesin and tubulin and our experimental data show that microtubules themselves are changing structure during that process. We studied unstained, vitrified samples of microtubules composed of 15 protofilaments using cryo electron microscopy and helical image analysis. 3D maps of plain microtubules and microtubules decorated with kinesin have been reconstructed to approximately 17A resolution. The alphabeta-tubulin dimer could be identified and, according to our data, alpha- and beta-tubulin adopt different conformations in plain microtubules. Significant differences were detected between maps of plain microtubules and microtubule-kinesin complexes. Most pronounced is the continuous axial inter-dimer contact in the microtubule-kinesin complex, suggesting stabilized protofilaments along the microtubule axis. It seems, that mainly structural changes within alpha-tubulin are responsible for this observation. Lateral effects are less pronounced. Following our data, we believe, that microtubules play an active role in intracellular transport processes through modulations of their core structure.

A structural analysis of the interaction between ncd tail and tubulin protofilaments

ncd is a minus-end directed, kinesin-like motor, which binds to microtubules with its motor domain and its cargo domain as well. Typical of retrograde motors, the motor domain of ncd locates to the C-terminal end of the polypeptide chain, and hence, the cargo domain constitutes the N-terminal region. To date, several studies have investigated the interaction properties of the motor domain with microtubules, but very few structural data are available about the tail itself or its interaction with microtubules as cargo. Here, we applied cryo-electron microscopy and helical 3D image reconstruction to 15 protofilament microtubules decorated with an ncd tail fragment (N-terminal residues 83-187, named NT6). In our study, the ncd tail shows a behaviour resembling filamentous MAPs such as tau protein, exhibiting a highly flexible structure with no large globular domains. NT6 binds to four different sites on the outer side of microtubules within the proximity of the kinesin motor-binding site. Two of these sites locate within the groove between two neighbouring protofilaments, and appear as strong binding sites, while the other two sites, located at the outer rim, appear to play a secondary role. In addition, the ncd tail fragment induces the formation of large protofilament sheets, suggesting a tail-induced modification of lateral protofilament contacts.

Nucleotide-induced conformations in the neck region of dimeric kinesin

The neck region of kinesin constitutes a key component in the enzyme's walking mechanism. Here we applied cryoelectron microscopy and image reconstruction to investigate the location of the kinesin neck in dimeric and monomeric constructs complexed to microtubules. To this end we enhanced the visibility of this region by engineering an SH3 domain into the transition between neck linker and neck coiled coil. The resulting chimeric kinesin constructs remained functional as verified by physiology assays. In the presence of AMP-PNP the SH3 domains allowed us to identify the position of the neck in a well defined conformation and revealed its high flexibility in the absence of nucleotide. We show here the double-headed binding of dimeric kinesin along the same protofilament, which is characterized by the opposite directionality of neck linkers. In this configuration the neck coiled coil appears fully zipped. The position of the neck region in dimeric constructs is not affected by the presence of the tubulin C-termini as confirmed by subtilisin treatment of microtubules prior to motor decoration.