Cell Motility by Labile Association of Molecules: The nature of mitotic spindle fibers and their role in chromosome movement

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CONTRACTILE PROCESSES IN NONMUSCULAR SYSTEMS

Cell Motility by Labile Association of Molecules

The nature of mitotic spindle fibers and their role in chromosome movement

Shinya Inoué ¹ and Hidemi Sato ¹

¹ From the Laboratories of Biophysical Cytology, Department of Biology, University of Pennsylvania, Philadelphia

This article summarizes our current views on the dynamic structureof the mitotic spindle and its relation to mitotic chromosomemovements. The following statements are based on measurementsof birefringence of spindle fibers in living cells, normallydeveloping or experimentally modified by various physical andchemical agents, including high and low temperatures, antimitoticdrugs, heavy water, and ultraviolet microbeam irradiation. Datawere also obtained concomitantly with electron microscopy employinga new fixative and through measurements of isolated spindleprotein. Spindle fibers in living cells are labile dynamic structureswhose constituent filaments (microtubules) undergo cyclic breakdownand reformation. The dynamic state is maintained by an equilibriumbetween a pool of protein molecules and their linearly aggregatedpolymers, which constitute the microtubules or filaments. Inliving cells under physiological conditions, the associationof the molecules into polymers is very weak (absolute valueof $Delta$ F_25°C < 1 kcal), and the equilibrium is readily shiftedto dissociation by low temperature or by high hydrostatic pressure.The equilibrium is shifted toward formation of polymer by increasein temperature (with a large increase in entropy: $Delta$ S_25°C $sime$ 100 eu) or by the addition of heavy water. The spindle proteinstend to polymerize with orienting centers as their geometricalfoci. The centrioles, kinetochores, and cell plate act as orientingcenters successively during mitosis. Filaments are more concentratedadjacent to an orienting center and yield higher birefringence.Astral rays, continuous fibers, chromosomal fibers, and phragmoplastfibers are thus formed by successive reorganization of the sameprotein molecules. During late prophase and metaphase, polymerizationtakes place predominantly at the kinetochores; in metaphaseand anaphase, depolymerization is prevalent near the spindlepoles. When the concentration of spindle protein is high, fusiformbundles of polymer are precipitated out even in the absenceof obvious orienting centers. The shift of equilibrium fromfree protein molecules to polymer increases the length and numberof the spindle microtubules or filaments. Slow depolymerizationof the polymers, which can be brought about by low concentrationsof colchicine or by gradual cooling, allows the filaments toshorten and perform work. The dynamic equilibrium controlledby orienting centers and other factors provides a plasusiblemechanism by which chromosomes and other organelles, as wellas the cell surface, are deformed or moved by temporarily organizedarrays of microtubules or filaments.

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