Dynein and kinesin motor proteins transport cellular cargos toward opposite ends of microtubule tracks. In neurons, microtubules are abundantly decorated with microtubule-associated proteins (MAPs) such as tau. Motor proteins thus encounter MAPs frequently along their path. To determine the effects of tau on dynein and kinesin motility, we conducted single molecule studies of motor proteins moving along tau-decorated microtubules. Dynein tended to reverse direction whereas kinesin tended to detach at patches of bound tau. Kinesin was inhibited at ~ 10-fold lower tau concentration than dynein and the microtubule-binding domain of tau was sufficient to inhibit motor activity. The differential modulation of dynein and kinesin motility suggests that MAPs can spatially regulate the balance of microtubule-dependent axonal transport.Active transport of cytoplasmic material along microtubules is critical for cell organization and function, and defects in this process are associated with dysfunction and disease (1). Much of the active transport in cells depends on the molecular motor proteins cytoplasmic dynein and kinesin-1, which transport cargo toward the minus-end (toward the cell center) and plusend of microtubules (toward the cell periphery), respectively. Dynein and kinesin have very different structures and translocation mechanisms (2). Kinesin has a compact motor domain and walks unidirectionally along single protofilaments with 8-nm steps (2). In contrast, dynein has a larger, more complex motor domain and is capable of variable step sizes, lateral steps across the microtubule surface, and processive runs toward both the minus-and plus-end of the microtubule (3-5). Cytoplasmic dynein function in vivo also requires an accessory complex, dynactin. This large, multiprotein complex is thought to facilitate dynein processivity (6) and may also regulate dynein activity (5). Within the cell, the balance between oppositely directed transport determines the steady-state distribution of organelles and biomolecules.In the crowded cell environment, dynein and kinesin compete with non-motile microtubuleassociated proteins (MAPs) for binding to the microtubule surface. MAPs bound to microtubules might also block the path of motor proteins. Thus, MAPs can provide spatiotemporal regulation of motor proteins in vivo. Tau, a neuronal MAP, inhibits kinesin activity in vivo and in vitro (7-10); however, its effect on dynein activity is not well understood. Our aim was to directly observe individual encounters between single dynein or kinesin motors and tau on microtubule tracks to determine how structurally distinct motors respond to obstacles in their path. NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author ManuscriptTau is expressed in neurons as multiple splice forms in a developmentally regulated manner (11). These isoforms differ in the number of microtubule binding repeats and the length of the projection domain (Fig. 1A). Here we focused on the shortest and longest tau isoforms, tau23 and tau40, to comp...
Ordered cortical microtubule arrays are essential for normal plant morphogenesis, but how these arrays form is unclear. The dynamics of individual cortical microtubules are stochastic and cannot fully account for the observed order; however, using tobacco (Nicotiana tabacum) cells expressing either the MBD-DsRed (microtubule binding domain of the mammalian MAP4 fused to the Discosoma sp red fluorescent protein) or YFP-TUA6 (yellow fluorescent protein fused to the Arabidopsis a-tubulin 6 isoform) microtubule markers, we identified intermicrotubule interactions that modify their stochastic behaviors. The intermicrotubule interactions occur when the growing plus-ends of cortical microtubules encounter previously existing cortical microtubules. Importantly, the outcome of such encounters depends on the angle at which they occur: steepangle collisions are characterized by approximately sevenfold shorter microtubule contact times compared with shallowangle encounters, and steep-angle collisions are twice as likely to result in microtubule depolymerization. Hence, steep-angle collisions promote microtubule destabilization, whereas shallow-angle encounters promote both microtubule stabilization and coalignment. Monte Carlo modeling of the behavior of simulated microtubules, according to the observed behavior of transverse and longitudinally oriented cortical microtubules in cells, reveals that these simple rules for intermicrotubule interactions are necessary and sufficient to facilitate the self-organization of dynamic microtubules into a parallel configuration.
SummaryThe green¯uorescent protein (GFP) and other intrinsically¯uorescent proteins (IFPs) are popular reporters because they allow visualization of cellular constituents in living specimens. IFP technology makes it possible to view dynamic processes in living cells, but extended observation, using¯uorescence microscopy (both wide-®eld and confocal), can result in signi®cant light energy exposure. Therefore, it is possible that cells experience light-induced damage that alters cell physiology and confounds observations. To understand the impact that extended viewing has on cells, we obtained quantitative information about the effect of light energy dose and observation conditions on tobacco BY-2 cell physiology. Our results show a non-linear relationship between the excitation light intensity and mitotic arrest, and the frequency of mitotic arrest is dependent on the presence of an IFP that absorbs the excitation light. Moreover, uorescence microscopy induces the production of reactive oxygen species (ROS), as assayed using BY-2 cells loaded with oxidation-sensitive dyes, and the level of ROS production increases if the cells express an IFP that absorbs the excitation light energy. The dye oxidation follows sigmoidal kinetics and is reversible if the cells are exposed to low irradiation levels. In addition, the dye oxidation rate shows a non-linear relationship to the excitation light intensity, and a good correlation exists between photobleaching, mitotic arrest, and dye oxidation. The data highlight the importance of ROS scavenging for normal mitotic progression, and provide a reference for judiciously choosing conditions that avoid photobleaching that can lead to ROS accumulation and physiological damage.
Microtubules are polarized polymers that exhibit dynamic instability, with alternating phases of elongation and shortening, particularly at the more dynamic plus-end. Microtubule plus-end tracking proteins (؉TIPs) localize to and track with growing microtubule plus-ends in the cell. ؉TIPs regulate microtubule dynamics and mediate interactions with other cellular components. The molecular mechanisms responsible for the ؉TIP tracking activity are not well understood, however. We reconstituted the ؉TIP tracking of mammalian proteins EB1 and CLIP-170 in vitro at single-molecule resolution using time-lapse total internal reflection fluorescence microscopy. We found that EB1 is capable of dynamically tracking growing microtubule plus-ends. Our singlemolecule studies demonstrate that EB1 exchanges rapidly at microtubule plus-ends with a dwell time of <1 s, indicating that single EB1 molecules go through multiple rounds of binding and dissociation during microtubule polymerization. CLIP-170 exhibits lattice diffusion and fails to selectively track microtubule ends in the absence of EB1; the addition of EB1 is both necessary and sufficient to mediate plus-end tracking by CLIP-170. Single-molecule analysis of the CLIP-170 -EB1 complex also indicates a short dwell time at growing plus-ends, an observation inconsistent with the copolymerization of this complex with tubulin for plus-end-specific localization. GTP hydrolysis is required for ؉TIP tracking, because end-specificity is lost when tubulin is polymerized in the presence of guanosine 5-[␣,-methylene]triphosphate (GMPCPP). Together, our data provide insight into the mechanisms driving plus-end tracking by mammalian ؉TIPs and suggest that EB1 specifically recognizes the distinct lattice structure at the growing microtubule end.ϩTIP ͉ single molecule ͉ total internal reflection fluorescence (TIRF) microscopy ͉ dynamic instability
Neuronal development, function and repair critically depend on axonal transport of vesicles and protein complexes, which is mediated in part by the molecular motor kinesin-1. Adaptor proteins recruit kinesin-1 to vesicles via direct association with kinesin heavy chain (KHC), the force-generating component, or via the accessory light chain (KLC). Binding of adaptors to the motor is believed to engage the motor for microtubule-based transport. We report that the adaptor protein Sunday Driver (syd, also known as JIP3 or JSAP1) interacts directly with KHC, in addition to and independently of its known interaction with KLC. Using an in vitro motility assay, we show that syd activates KHC for transport and enhances its motility, increasing both KHC velocity and run length. syd binding to KHC is functional in neurons, as syd mutants that bind KHC but not KLC are transported to axons and dendrites similarly to wild-type syd. This transport does not rely on syd oligomerization with itself or other JIP family members. These results establish syd as a positive regulator of kinesin activity and motility.
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