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Full-Text Articles in Life Sciences
A Kinesin Motor In A Force-Producing Conformation, Elisabeth Heuston, C. Eric Bronner, F Jon Kull, Sharyn A. Endow
A Kinesin Motor In A Force-Producing Conformation, Elisabeth Heuston, C. Eric Bronner, F Jon Kull, Sharyn A. Endow
Dartmouth Scholarship
Kinesin motors hydrolyze ATP to produce force and move along microtubules, converting chemical energy into work by a mechanism that is only poorly understood. Key transitions and intermediate states in the process are still structurally uncharacterized, and remain outstanding questions in the field. Perturbing the motor by introducing point mutations could stabilize transitional or unstable states, providing critical information about these rarer states.
A Three-Dimensional Computer Simulation Model Reveals The Mechanisms For Self-Organization Of Plant Cortical Microtubules Into Oblique Arrays, Ezgi Can Eren, Ram Dixit, Natarajan Gautam
A Three-Dimensional Computer Simulation Model Reveals The Mechanisms For Self-Organization Of Plant Cortical Microtubules Into Oblique Arrays, Ezgi Can Eren, Ram Dixit, Natarajan Gautam
Biology Faculty Publications & Presentations
The noncentrosomal cortical microtubules (CMTs) of plant cells self-organize into a parallel three-dimensional (3D) array that is oriented transverse to the cell elongation axis in wild-type plants and is oblique in some of the mutants that show twisted growth. To study the mechanisms of CMT array organization, we developed a 3D computer simulation model based on experimentally observed properties of CMTs. Our computer model accurately mimics transverse array organization and other fundamental properties of CMTs observed in rapidly elongating wild-type cells as well as the defective CMT phenotypes observed in the Arabidopsis mor1-1 and fra2 mutants. We found that CMT …
Chapter 27 – Studying Plus-End Tracking At Single Molecule Resolution Using Tirf Microscopy, Ram Dixit, Jennifer L. Ross
Chapter 27 – Studying Plus-End Tracking At Single Molecule Resolution Using Tirf Microscopy, Ram Dixit, Jennifer L. Ross
Biology Faculty Publications & Presentations
The highly dynamic microtubule plus-ends are key sites of regulation that impact the organization and function of the microtubule cytoskeleton. Much of this regulation is performed by the microtubule plus-end tracking (+TIP) family of proteins. +TIPs are a structurally diverse group of proteins that bind to and track with growing microtubule plus-ends in cells. +TIPs regulate microtubule dynamics as well as mediate interactions between microtubule tips and other cellular structures. Most +TIPs can directly bind to microtubules in vitro; however, the mechanisms for their plus-end specificity are not fully understood. Cellular studies of +TIP activity are complicated by the fact …