A Force Balance Model of Early Spindle Pole Separation in Drosophila Embryos

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A Force Balance Model of Early Spindle Pole Separation in Drosophila Embryos

E. N. Cytrynbaum^*^,, J. M. Scholey^*^, and A. Mogilner^*^,

^* Center for Genetics and Development, Section of Molecular and Cell Biology, Department of Mathematics, University of California, Davis, California 95616 USA

Correspondence: Address reprint requests to Alexander Mogilner, E-mail: mogilner{at}math.ucdavis.edu.

The formation and function of the mitotic spindle depends uponforce generation by multiple molecular motors and by the dynamicsof microtubules, but how these force-generating mechanisms relateto one another is unclear. To address this issue we have modeledthe separation of spindle poles as a function of time duringthe early stages of spindle morphogenesis in Drosophila embryos.We propose that the outward forces that drive the separationof the spindle poles depend upon forces exerted by corticaldynein and by microtubule polymerization, and that these forcesare antagonized by a C-terminal kinesin, Ncd, which generatesan inward force on the poles. We computed the sum of the forcesgenerated by dynein, microtubule polymerization, and Ncd, asa function of the extent of spindle pole separation and solvedan equation relating the rate of pole separation to the netforce. As a result, we obtained graphs of the time course ofspindle pole separation during interphase and prophase thatdisplay a reasonable fit to the experimental data for wild-typeand motor-inhibited embryos. Among the novel contributions ofthe model are an explanation of pole separation after simultaneousloss of Ncd and dynein function, and the prediction of a largevalue for the effective centrosomal drag that is needed to fitthe experimental data. The results demonstrate the utility offorce balance models for explaining certain mitotic movementsbecause they explain semiquantitatively how the force generatorsdrive a rapid initial burst of pole separation when the netforce is great, how pole separation slows down as the forcedecreases, and how a stable separation of the spindle polescharacteristic of the prophase steady state is achieved whenthe force reaches zero.

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