Author:
Kohl Phillip,Song Chaeyeon,Fletcher Bretton,Best Rebecca L.,Tchounwou Christine,Arceo Ximena Garcia,Chung Peter J.,Miller Herbert P.,Wilson Leslie,Choi Myung Chul,Li Youli,Feinstein Stuart C.,Safinya Cyrus R.
Abstract
AbstractThe axon-initial-segment (AIS) of mature neurons contains microtubule (MT) fascicles (linear bundles) that are implicated as retrograde diffusion barriers in the retention of MT-associated protein (MAP) tau inside axons. While the role of tau in MT bundling is poorly understood, tau dysfunction and leakage outside of the axon is associated with neurodegeneration. We report on the structure of steady-state MT bundles in response to varying concentrations of divalent cations (Mg2+or Ca2+) in dissipative reaction mixtures containing αβ-tubulin, full-length tau, and GTP at 37°C. A concentration-time kinetic phase diagram generated by synchrotron small-angle X-ray scattering (SAXS) reveals a wide-spacing MT bundle phase (Bws), a transient intermediate MT bundle phase (Bint), and a tubulin ring phase. Remarkably, SAXS analysis combined with TEM of plastic embedded samples provides direct evidence of an intervening network (IN) of complexes of tubulin oligomers and tau (≈5 nm wide filaments), which stabilize MT bundles. In this model, αβ-tubulin oligomers in the IN are crosslinked by tau’s MT binding repeats, which also link αβ-tubulin oligomers to αβ-tubulin within the MT lattice. The finding of a new role for tubulin revises current dogma where cross-bridging of MTs is attributed entirely to interactions between MAPs. The tubulin-tau complexes of the IN should enhance the barrier properties of MT fascicles in preventing tau missorting to the somatodendritic compartment as happens during neurodegeneration. Furthermore, tubulin-tau complexes in the IN or bound to isolated MTs are potential sites for enzymatic modification of tau promoting nucleation and growth of tau fibrils in tauopathies.Significance StatementA cell free model of microtubule (MT) bundles of the axon-initial-segment (known as MT fascicles) was studied in physiologically relevant buffer conditions. MT fascicles have a role in retaining neuronal protein tau, a key protein stabilizing MTs, in the axon. X-ray scattering and electron microscopy led to the discovery of complexes of tubulin oligomers and tau as building blocks of an intervening network that cross-bridge MTs into stable bundles with precisely the same linear geometry observedin-vivoin neurons. Significantly, changes to the chemical structure of tau because of abnormal interactions with cellular enzymes, would be predicted to disrupt the intervening tubulin-tau network and the MT-fascicle’s barrier function, promoting leakage of tau to the somatodendritic compartment and neuron degradation.
Publisher
Cold Spring Harbor Laboratory