In long-range transport of cargo, prototypical kinesin-1 steps along a single protofilament on the microtubule, an astonishing behavior given the number of theoretically available binding sites on adjacent protofilaments. Using a laser trap assay, we analyzed the trajectories of several representatives from the kinesin-2 class on freely suspended microtubules. In stark contrast to kinesin-1, these motors display a wide range of left-handed spiraling around microtubules and thus generate torque during cargo transport. We provide direct evidence that kinesin's neck region determines the torque-generating properties. A model system based on kinesin-1 corroborates this result: disrupting the stability of the neck by inserting flexible peptide stretches resulted in pronounced left-handed spiraling. Mimicking neck stability by crosslinking significantly reduced the spiraling of the motor up to the point of protofilament tracking. Finally, we present a model that explains the physical basis of kinesin's spiraling around the microtubule.
The widespread LIS1-proteins were originally identified as the target for sporadic mutations causing lissencephaly in humans. Dictyostelium LIS1 (DdLIS1) is a microtubule-associated protein exhibiting 53% identity to human LIS1. It colocalizes with dynein at isolated, microtubule-free centrosomes, suggesting that both are integral centrosomal components. Replacement of the DdLIS1 gene by the hypomorphic D327H allele or overexpression of an MBP-DdLIS1 fusion disrupted various dynein-associated functions. Microtubules lost contact with the cell cortex and were dragged behind an unusually motile centrosome. Previously, this phenotype was observed in cells overexpressing fragments of dynein or the XMAP215-homologue DdCP224. DdLIS1 was coprecipitated with DdCP224, suggesting that both act together in dyneinmediated cortical attachment of microtubules. Furthermore, DdLIS1-D327H mutants showed Golgi dispersal and reduced centrosome/nucleus association. Defects in DdLIS1 function also altered actin dynamics characterized by traveling waves of actin polymerization correlated with a reduced F-actin content. DdLIS1 could be involved in actin dynamics through Rho-GTPases, because DdLIS1 interacted directly with Rac1A in vitro. Our results show that DdLIS1 is required for maintenance of the microtubule cytoskeleton, Golgi apparatus and nucleus/centrosome association, and they suggest that LIS1-dependent alterations of actin dynamics could also contribute to defects in neuronal migration in lissencephaly patients. INTRODUCTIONThe LIS1 gene was originally identified as the target for sporadic mutations resulting in haploinsufficiency and a severe brain developmental disease called type I lissencephaly in human infants. Lissencephaly (Greek lissos ϭ smooth) is characterized by a smooth appearance of the neocortical surface due to the absence of gyri and sulci (Reiner et al., 1993). This is believed to be the consequence of impaired migration of neuronal precursors from the paraventricular area, where they divide, to the cerebral cortex during development. The LIS1 protein has a calculated molecular mass of ϳ45 kDa and is characterized by seven WD40-repeats, which are thought to form a -propeller fold as in structurally similar -subunits of heterotrimeric G-proteins. Indeed, LIS1 could be identified as a subunit of a brain-specific isoform of the G-protein-like platelet-activating factor acetylhydrolase. Yet, the first clues for the molecular function of LIS1 in neuronal migration came from a filamentous fungus. The Aspergillus nidulans LIS1 homologue, NUDF, was identified in a screen for nuclear distribution mutants (Xiang et al., 1995). Further nud mutants include nudA, encoding the cytoplasmic dynein heavy chain, and nudE. Mutations in nudA, nudE, and nudF caused similar defects in nuclear migration during hyphal stalk formation (Morris et al., 1998). Nuclear migration is an important factor in neuronal cell migration as well (reviewed by Gupta et al., 2002), and it is achieved through the activity of dynein/dynactin locali...
The Dictyostelium XMAP215 family member DdCP224 is involved in centrosome duplication and cytokinesis and is concentrated at the centrosome and microtubule tips. Herein, we have created a DdCP224 promoter replacement mutant that allows both over-and underexpression. Overexpression led to supernumerary microtubule-organizing centers and, independently, an increase of the number of multinuclear cells. Electron microscopy demonstrated that supernumerary microtubule-organizing centers represented bona fide centrosomes. Live cell imaging of DdCP224-green fluorescent protein mutants also expressing green fluorescent protein-histone2B as a DNA label revealed that supernumerary centrosomes were also competent of cell cycle-dependent duplication. In contrast, underexpression of DdCP224 inhibited cell growth, reduced the number and length of astral microtubules, and caused nocodazole hypersensitivity. Moreover, microtubule regrowth after nocodazole removal was dependent on DdCP224. Underexpression also resulted in a striking disappearance of supernumerary centrosomes and multinuclear cells caused by previous overexpression. We show for the first time by live cell observation that the number of supernumerary centrosomes can be reduced either by centrosome fusion (coalescence) or by the formation of cytoplasts containing supernumerary centrosomes during cytokinesis. INTRODUCTIONIn dividing cells, control of centrosome number is essential for the fidelity of mitosis and maintenance of euploidy. Supernumerary centrosomes are a hallmark of tumor cells, although it is still a matter of discussion whether their appearance is a cause or a consequence of carcinogenesis (Lingle et al., 2002;Nigg, 2002). However, it is widely accepted that supernumerary centrosomes contribute to the formation of multipolar spindles and thus to defective chromosome segregation. Although most of the daughter cells resulting from such mitotic chaos will die, some of them will acquire the potential for neoplastic growth in spite of supernumerary centrosomes and aneuploidy, as they regain the ability to form a bipolar spindle. Brinkley (2001) suggested two mechanisms how this can be achieved: first, "deamplification" of supernumerary centrosomes by elimination or inactivation, and second, fusion or "coalescence" of supernumerary centrosomes resulting in one or two compound microtubule-organizing centers (MTOCs).Herein, we have studied the fate of supernumerary centrosomes in a simple model system. In Dictyostelium amoebae, one molecular component involved in the formation of supernumerary centrosomes is DdCP224, a member of the XMAP215 family of microtubule-associated proteins (Gräf et al., 2000). In most species, these proteins are long, thin, monomeric molecules with a size of ϳ 230 kDa (Cassimeris et al., 2001). Their ubiquitous occurrence, even in plants, suggests indispensible functions (Ohkura et al., 2001). XMAP215, for instance, is a promoter of microtubule elongation due to a suppression of catastrophe events induced by the Kin I family kinesin ...
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