Hidemi Sato scite author profile

This article summarizes our current views on the dynamic structure of the mitotic spindle and its relation to mitotic chromosome movements. The following statements are based on measurements of birefringence of spindle fibers in living cells, normally developing or experimentally modified by various physical and chemical agents, including high and low temperatures, antimitotic drugs, heavy water, and ultraviolet microbeam irradiation. Data were also obtained concomitantly with electron microscopy employing a new fixative and through measurements of isolated spindle protein. Spindle fibers in living cells are labile dynamic structures whose constituent filaments (microtubules) undergo cyclic breakdown and reformation. The dynamic state is maintained by an equilibrium between a pool of protein molecules and their linearly aggregated polymers, which constitute the microtubules or filaments. In living cells under physiological conditions, the association of the molecules into polymers is very weak (absolute value of AF25.c < 1 kcal), and the equilibrium is readily shifted to dissociation by low temperature or by high hydrostatic pressure. The equilibrium is shifted toward formation of polymer by increase in temperature (with a large increase in entropy: AS~soc ~---100 eu) or by the addition of heavy water. The spindle proteins tend to polymerize with orienting centers as their geometrical foci~ The centrioles, kinetochores, and cell plate act as orienting centers successively during mitosis. Filaments are more concentrated adjacent to an orienting center and yield higher birefringence. Astral rays, continuous fibers, chromosomal fibers, and phragmoplast fibers are thus formed by successive reorganization of the same protein molecules. During late prophase and metaphase, polymerization takes place predominantly at the kinetochores; in metaphase and anaphase, depolymerization is prevalent near the spindle poles. When the concentration of spindle protein is high, fusiform bundles of polymer are precipitated out even in the absence of obvious orienting centers. The shift of equilibrium from free protein molecules to polymer increases the length and number of the spindle microtubules or filaments. Slow depolymerization of the 259

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Microtubular origin of mitotic spindle form birefringence. Demonstration of the applicability of Wiener's equation.

Sato¹,

Ellis²,

Inoué³

1975

167

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Meiosis I metaphase spindles were isolated from oocytes of the sea-star Pisaster ochraceus by a method that produced no detectable net loss in spindle birefringence. Some of the spindles were fixed immediately and embedded and sectioned for electron microscopy. Others were laminated between gelatine pellicles in a perfusion chamber, then fixed and sequentially and reversibly imbibed with a series of media of increasing refractive indices. Electron microscopy showed little else besides microtubules in the isolates, and no other component present could account for the observed form birefringence. An Ambronn plot of the birefringent retardation measured during imbibition was a good least squares fit to a computer generated theoretical curve based on the Bragg-Pippard rederivation of the Wiener curve for form birefringence. The data were best fit by the curve for rodlet index (n1) = 1.512, rodlet volume fraction (f) = 0.0206, and coefficient of intrinsic birefringence = 4.7 X 10(-5). The value obtained for n1 is unequivocal and is virtually as good as the refractometer determinations of imbibing medium index on which it is based. The optically interactive volume of the microtubule subunit, calculated from our electron microscope determination of spindle microtubule distribution (106/mum2), 13 protofilaments per microtubules, an 8 nm repeat distance and our best value for f, is compatible with known subunit dimensions as determined by other means. We also report curves fitted to the results of Ambronn imbibition of Bouin's-fixed Lytechinus spindles and to the Noll and Weber muscle imbibition data.

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Vinblastine and Griseofulvin Reversibly Disrupt the Living Mitotic Spindle

Malawista

Sato

Bensch

1968

Science

262

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Using polarized light we have studied the effects of various mitotic poisons on mitotic spindles of living Pectinaria oocytes; we have studied fixed specimens with phase and electron microscopy. Vinblastine caused attrition and eventual disappearance of spindle structure as rapidly as did colcemid, and subsequent recovery from this treatment was at least as fast as that from colcemid. Griseofulvin, however, was easily the best agent for rapid, reversible, and repeated dissolution of the spindle. Agents that arrest metaphase may act on nondividing cells by interfering with the organization of other gelated structures.

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Unique Spindle Poisons, Curvularin and Its Derivatives, Isolated fromPenicilliumSpecies

Kobayashi

Hino

Yata

et al. 1988

Agricultural and Biological Chemistry

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Unique spindle poisons, curvularin and its derivatives, isolated from Penicillium species.

Kobayashi

Hino

Yata

et al. 1988

Agricultural and Biological Chemistry

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Curvularin, 8-dehydrocurvularin, and 8-hydroxycurvularin as well as a minor newmetabolite, 8-methoxycurvularin, wereisolated as fungal metabolites having cytotoxic activity toward sea urchin embryogenesis. Curvularin induced barrel-shaped mitotic spindles and 8-dehydrocurvularin caused miniature spindles. They were shownto act on componentsof the mitotic apparatus and to effectively inhibit cell division. Cell cleavage has great physiological significance for cell biologists. Many chemicals

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Hidemi Sato

Cell Motility by Labile Association of Molecules

Microtubular origin of mitotic spindle form birefringence. Demonstration of the applicability of Wiener's equation.

Vinblastine and Griseofulvin Reversibly Disrupt the Living Mitotic Spindle

Unique Spindle Poisons, Curvularin and Its Derivatives, Isolated fromPenicilliumSpecies

Unique spindle poisons, curvularin and its derivatives, isolated from Penicillium species.

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