Cytoplasmic dynein and dynactin coordinate microtubule dynamics at the growing plus end.

Format:

Book

Thesis/Dissertation

Author/Creator:

Lazarus, Jacob Eric.

Contributor:

Ferguson, Kathryn, committee member.

Birnbaum, Morris, committee member.

Ostap, Michael, committee member.

Bi, Erfei, committee member.

Holzbaur, Erika L. F., advisor.

University of Pennsylvania. Cell and Molecular Biology.

Language:

English

Subjects (All):

Biophysics.

Biochemistry.

Cytology.

Biology, Cell.

Chemistry, Biochemistry.

Biophysics, General.

0379.

0487.

0786.

Penn dissertations--Cell and molecular biology.

Cell and molecular biology--Penn dissertations.

Local Subjects:

Biology, Cell.

Chemistry, Biochemistry.

Biophysics, General.

Penn dissertations--Cell and molecular biology.

Cell and molecular biology--Penn dissertations.

0379.

0487.

0786.

Physical Description:

162 pages

Contained In:

Dissertation Abstracts International 74-06B(E).

System Details:

Mode of access: World Wide Web.

text file

Summary:

Microtubules are cytoskeletal polymers that serve as long-distance tracks for intracellular transport. However, microtubules are not static tracks; they undergo dynamic instability, a non-equilibrium behavior which allows them to continually remodel. Microtubules must remodel to adapt to the changing needs of the cell, yet they must also be stable enough to allow long-distance transport by kinesins and by cytoplasmic dynein and its partner complex dynactin. Microtubule dynamics are strongly influenced by microtubule-associated proteins, which bind to microtubules and bias them toward growth or shrinkage. A pool of dynein and dynactin localizes to the microtubule plus end and to the cortex, where we hypothesized that they might not be solely poised to initiate retrograde runs, but might also act to modify microtubule dynamics. To test this, we reconstituted microtubule dynamic instability in vitro and visualized it using TIRF microscopy. We show that dynein, when immobilized in an orientation recapitulating its membrane recruitment, can tether growing microtubules, reducing their lateral diffusion and delaying catastrophe. This effect does not represent mere microtubule binding; dynein tethers microtubules more effectively than kinesin or the plus end-tracking protein EB1, and we show that this ability of dynein is dependent on its ATPase activity. Modeling suggests that dynein may delay catastrophe by actively applying tension to straighten, and thus stabilize the microtubule. We also have examined the effects of the p150Glued subunit of dynactin on microtubule dynamics. We find that to modify dynamics, p150Glued must be dimerized, and it must bind tubulin, an interaction that requires its CAP-Gly and basic domains in tandem. p150Glued is alternatively spliced in vivo, with the isoform including both these domains expressed primarily in neurons. Accordingly, depletion of p150Glued in a non-polarized cell line does not alter microtubule dynamics, while p150 Glued RNAi in neurons leads to a dramatic increase in microtubule catastrophe. Strikingly, a Parkinson syndrome-associated mutation blocks this microtubule-stabilizing activity both in vitro and in neurons. Together, these data provide novel mechanistic insight into how cytoplasmic dynein and dynactin, the principle minus end-directed motor complex in the cell, also act at the plus end to coordinate microtubule dynamics.

Notes:

Thesis (Ph.D. in Cell and Molecular Biology) -- University of Pennsylvania, 2012.

Source: Dissertation Abstracts International, Volume: 74-06(E), Section: B.

Adviser: Erika L. F. Holzbaur.

Local Notes:

School code: 0175.

ISBN:

9781267887108

Access Restriction:

Restricted for use by site license.