Self-organization of microtubules and motors

Abstract

Cellular structures are established and maintained through a dynamic interplay between assembly and regulatory processes. Self-organization of molecular components provides a variety of possible spatial structures: the regulatory machinery chooses the most appropriate to express a given cellular function¹. Here we study the extent and the characteristics of self-organization using microtubules and molecular motors² as a model system. These components are known to participate in the formation of many cellular structures, such as the dynamic asters found in mitotic and meiotic spindles^3,4. Purified motors and microtubules have previously been observed to form asters in vitro⁵. We have reproduced this result with a simple system consisting solely of multi-headed constructs of the motor protein kinesin⁶ and stabilized microtubules. We show that dynamic asters can also be obtained from a homogeneous solution of tubulin and motors. By varying the relative concentrations of the components, we obtain a variety of self-organized structures. Further, by studying this process in a constrained geometry of micro-fabricated glass chambers⁷, we demonstrate that the same final structure can be reached through different assembly ‘pathways’.