Traction fibres in chromosome movement: the pros and cons

The current discussion on the mechanism of chromosome movement in anaphase is dominated by a new hypothesis assuming active movement of the chromosome along stationary kinetochore microtubules. The aim of this article is to call attention to several older as well as to more recent observations on spindle structural dynamics and microtubule rearrangements which, in the author's opinion, cannot be explained by the new model. In fact, the observations seem to be more consistent with the classical concept of a traction fibre. For this reason, these observations should not be disregarded.     

Structural characterization of KKT4, an unconventional microtubule-binding kinetochore protein

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Low-dose laulimalide represents a novel molecular probe for investigating microtubule organization

Laulimalide is a natural product that has strong taxoid-like properties but binds to a distinct site on β-tubulin in the microtubule (MT) lattice. At elevated concentrations, it generates MTs that are resistant to depolymerization, and it induces a conformational state indistinguishable from taxoid-treated MTs. In this study, we describe the effect of low-dose laulimalide on various stages of the cell cycle and compare these effects to docetaxel as a representative of taxoid stabilizers. No evidence of MT bundling in interphase was observed with laulimalide, in spite of the fact that MTs are stabilized at low dose. Cells treated with laulimalide enter mitosis but arrest at prometaphase by generating multiple asters that coalesce into supernumerary poles and interfere with the integrity of the metaphase plate. Cells with a preformed bipolar spindle exist under heightened tension under laulimalide treatment, and chromosomes rapidly shear from the plate, even though the bipolar spindle is well-preserved. Docetaxel generates a similar phenotype for HeLa cells entering mitosis, but when treated at metaphase, cells undergo chromosomal fragmentation and demonstrate reduced centromere dynamics, as expected for a taxoid. Our results suggest that laulimalide represents a new class of molecular probe for investigating MT-mediated events, such as kinetochore-MT interactions, which may reflect the location of the ligand binding site within the interprotofilament groove.     

End-on microtubule-dynein interactions and pulling-based positioning of microtubule organizing centers

During important cellular processes such as centrosome and spindle positioning, dynein at the cortex interacts with dynamic microtubules in an apparent “end-on” fashion. It is well-established that dynein can generate forces by moving laterally along the microtubule lattice, but much less is known about dynein’s interaction with dynamic microtubule ends. In this paper, we review recent in vitro experiments that show that dynein, attached to an artificial cortex, is able to capture microtubule ends, regulate microtubule dynamics and mediate the generation of pulling forces on shrinking microtubules. We further review existing ideas on the involvement of dynein-mediated cortical pulling forces in the positioning of microtubule organizing centers such as centrosomes. Recent in vitro experiments have demonstrated that cortical pulling forces in combination with pushing forces can lead to reliable centering of microtubule asters in quasi two-dimensional microfabricated chambers. In these experiments, pushing leads to slipping of microtubule ends along the chamber boundaries, resulting in an anisotropic distribution of cortical microtubule contacts that favors centering, once pulling force generators become engaged. This effect is predicted to be strongly geometry-dependent, and we therefore finally discuss ongoing efforts to repeat these experiments in three-dimensional, spherical and deformable geometries.     

Ultrastructure and Vacuolar Movements in the Free-Living Diplomonad Trepomonas agilis Klebs*

SYNOPSIS. The structure of Trepomonas agilis communis Klebs is described from light and electron microscope observations on 2 clone isolates of the organism. The surface membrane shows marked differentiation into an extremely thick (16 nm) symmetric membrane which covers the greater part of the body, and a thinner (∼ 10–12 nm) asymmetric membrane which lines the 2 lateral oral grooves and the posterior channel connecting them; a similar asymmetric membrane covers the flagella. Thorium dioxide staining suggests a denser distribution of acidic carbohydrate groups on the asymmetric membrane. The pathways of cytoplasmic streaming observed in the living flagellate coincide with those of microtubule bands arising close to the flagellar basal bodies and it is suggested that the bands play an orienting role in the streaming of food vacuoles. The contractile vacuole undergoes diastole in the anterior (postnuclear) cytoplasm, and is formed by coalescence of smaller vesicles. At systole the entire vacuole migrates to the posterior extremity to discharge into the posterior channel; the route of exit lacks guiding structural elements. Features of the flagellate's physiology and organization are discussed in relation to the observed lack of mitochondria, microbodies and Golgi apparatus in diplomonads.