Tubulins

Intracellular transport carries out very important roles within the cell including mitosis, organization, and organelle function. In order for effective transport using the motor protein dynein, a cofactor named dynactin is required. Of dynactin's many subunits, p150[Glued] holds the most responsibility for effective microtubule organization throughout the cell and the necessary anchoring at the centrosome. P150[Glued] holds two areas of high binding potential, the CAP-Gly region and the Basic region. Each of these binding domains have different binding potentials and affinities for microtubules. The CAP-Gly region binds tightly the microtubules for a longer period of tiem ; the Basic region binds loosely to microtubules. Throughout the course of my research, I manipulated these two regions binding affinity for microtubules and evaluated the resulting cells ability to effectively organize microtubules and anchor them properly at the centrosome.

The centrosome is a dynamic and highly active organelle within the cell. It plays a pivotal role in mitosis driving several of the physical changes that are taking place. The centrosome self-replicates before mitosis in order to set up two spindle poles on opposite sides of the cell. This leads to the creation of a mother and daughter centrosomes within a cell that have distinct components. This project will examine the recruitment of proteins to the centrosome as a cell progresses through the cell cycle. The proteins examined are (Sd(B-tubulin, (Sf(B-tubulin, Nek 2, Centrin2, p150Glued, EB-1, and dynein intermediate chain. In addition, chromosome arrangement was determined. By examining these proteins we hope to establish a logical order for the interactions of these proteins and their key contributions to cell cycle progression and completion, specifically dealing with the development of the mother and daughter centrosomes.

Dynactin is a multi-subunit protein complex that is the required cofactor for the cytoplasmic motor protein, dynein. Dynactin is critical for cytoplasmic activities such as vesicle transport, cytoskeletal organization, membrane organization and mitotic progression as it serves to increase processivity of dynein. The main subunit in focus for this study is the sidearm extension p150Glued. On the exposed end (N-terminus) lie two different microtubule binding motifs: CAP-Gly and Basic. CAP-Gly has a high binding affinity for microtubules, while Basic binds the microtubules quite weakly. It is at this location that dynactin is proposed to assist in the processivity of transporting cargo long distances in the cell, by providing additional support for the dynein molecule as it progresses along the microtubule. Analysis of the effects of overexpression of these motifs, alone or in tandem, suggested that there was no disruption of the dynein/dynactin interaction, but its ability to act in a processive manner had been perturbed. Effects on non-dynamic processes, such as Golgi localization and microtubule organization were generally weak, but effects were greater on y-tubulin organization. While this could suggest a defect in centrosome organization, we propose that it instead shows that cargo motility in the affected cells is defective, and that transport of centrosomal proteins to the centrosome is interrupted, suggesting a broader cargo-transport defect may be evident in these cells.