Litcius/Paper detail

Microtubule instability driven by longitudinal and lateral strain propagation

Maxim Igaev, Helmut Grubmüller

2020PLoS Computational Biology36 citationsDOIOpen Access PDF

Abstract

Tubulin dimers associate longitudinally and laterally to form metastable microtubules (MTs). MT disassembly is preceded by subtle structural changes in tubulin fueled by GTP hydrolysis. These changes render the MT lattice unstable, but it is unclear exactly how they affect lattice energetics and strain. We performed long-time atomistic simulations to interrogate the impacts of GTP hydrolysis on tubulin lattice conformation, lateral inter-dimer interactions, and (non-)local lateral coordination of dimer motions. The simulations suggest that most of the hydrolysis energy is stored in the lattice in the form of longitudinal strain. While not significantly affecting lateral bond stability, the stored elastic energy results in more strongly confined and correlated dynamics of GDP-tubulins, thereby entropically destabilizing the MT lattice.

Topics & Concepts

MicrotubuleDimerMetastabilityTubulinLattice (music)InstabilityBiophysicsGTPaseCrystallographyMolecular dynamicsStrain energyChemistryChemical physicsPhysicsMechanicsBiologyComputational chemistryNuclear magnetic resonanceBiochemistryThermodynamicsCell biologyFinite element methodOrganic chemistryAcousticsMicrotubule and mitosis dynamicsProtein Structure and DynamicsPlant nutrient uptake and metabolism