Tau can switch microtubule network organizations: from random networks to dynamic and stable bundles.

In neurons, microtubule networks alternate between single filaments and bundled arrays under the influence of effectors controlling their dynamics and organization. Tau is a microtubule bundler that stabilizes microtubules by stimulating growth and inhibiting shrinkage. The mechanisms by which tau organizes microtubule networks remain poorly understood. Here, we studied the self-organization of microtubules growing in the presence of tau isoforms and mutants. The results show that tau's ability to induce stable microtubule bundles requires two hexapeptides located in its microtubule-binding domain and is modulated by its projection domain. Site-specific pseudophosphorylation of tau promotes distinct microtubule organizations: stable single microtubules, stable bundles, or dynamic bundles. Disease-related tau mutations increase the formation of highly dynamic bundles. Finally, cryo-electron microscopy experiments indicate that tau and its variants similarly change the microtubule lattice structure by increasing both the protofilament number and lattice defects. Overall, our results uncover novel phosphodependent mechanisms governing tau's ability to trigger microtubule organization and reveal that disease-related modifications of tau promote specific microtubule organizations that may have a deleterious impact during neurodegeneration.

A TIRF microscopy assay to decode how tau regulates EB's tracking at microtubule ends.

Tau is a major microtubule-associated protein (MAP) mainly expressed in the brain. Tau binds the lattice of microtubules and favors their elongation and bundling. Recent studies have shown that tau is also a partner of end-binding proteins (EBs) in neurons. EBs belong to the protein family of the plus-end tracking proteins that preferentially associate with the growing plus-ends of microtubules and control microtubule end behavior and anchorage to intracellular organelles. Reconstituted cell-free systems using purified proteins are required to understand the precise mechanisms by which tau influences EB localization on microtubules and how the concerted activity of these two MAPs modulates microtubule dynamics. We developed an in vitro assay combining TIRF microscopy and site-directed mutagenesis to dissect the interaction of tau with EBs and to study how this interaction affects microtubule dynamics. Here, we describe the detailed procedures to purify proteins (tubulin, tau, and EBs), prepare the samples for TIRF microscopy, and analyze microtubule dynamics, and EB binding at microtubule ends in the presence of tau.

TIRF assays for real-time observation of microtubules and actin coassembly: Deciphering tau effects on microtubule/actin interplay.

Microtubule and actin cytoskeletons are key players in vital processes in cells. Although the importance of microtubule-actin interaction for cell development and function has been highlighted for years, the properties of these two cytoskeletons have been mostly studied separately. Thus we now need procedures to simultaneously assess actin and microtubule properties to decipher the basic mechanisms underlying microtubule-actin crosstalk. Here we describe an in vitro assay that allows the coassembly of both filaments and the real-time observation of their interaction by TIRF microscopy. We show how this assay can be used to demonstrate that tau, a neuronal microtubule-associated protein, is a bona fide actin-microtubule cross-linker. The procedure relies on the use of highly purified proteins and chemically passivated perfusion chambers. We present a step-by-step protocol to obtain actin and microtubule coassembly and discuss the major pitfalls. An ImageJ macro to quantify actin and microtubule interaction is also provided.

Tau antagonizes end-binding protein tracking at microtubule ends through a phosphorylation-dependent mechanism.

Proper regulation of microtubule dynamics is essential for cell functions and involves various microtubule-associated proteins (MAPs). Among them, end-binding proteins (EBs) accumulate at microtubule plus ends, whereas structural MAPs bind along the microtubule lattice. Recent data indicate that the structural MAP tau modulates EB subcellular localization in neurons. However, the molecular determinants of EB/tau interaction remain unknown, as is the effect of this interplay on microtubule dynamics. Here we investigate the mechanisms governing EB/tau interaction in cell-free systems and cellular models. We find that tau inhibits EB tracking at microtubule ends. Tau and EBs form a complex via the C-terminal region of EBs and the microtubule-binding sites of tau. These two domains are required for the inhibitory activity of tau on EB localization to microtubule ends. Moreover, the phosphomimetic mutation S262E within tau microtubule-binding sites impairs EB/tau interaction and prevents the inhibitory effect of tau on EB comets. We further show that microtubule dynamic parameters vary, depending on the combined activities of EBs and tau proteins. Overall our results demonstrate that tau directly antagonizes EB function through a phosphorylation-dependent mechanism. This study highlights a novel role for tau in EB regulation, which might be impaired in neurodegenerative disorders.

Tau co-organizes dynamic microtubule and actin networks.

The crosstalk between microtubules and actin is essential for cellular functions. However, mechanisms underlying the microtubule-actin organization by cross-linkers remain largely unexplored. Here, we report that tau, a neuronal microtubule-associated protein, binds to microtubules and actin simultaneously, promoting in vitro co-organization and coupled growth of both networks. By developing an original assay to visualize concomitant microtubule and actin assembly, we show that tau can induce guided polymerization of actin filaments along microtubule tracks and growth of single microtubules along actin filament bundles. Importantly, tau mediates microtubule-actin co-alignment without changing polymer growth properties. Mutagenesis studies further reveal that at least two of the four tau repeated motifs, primarily identified as tubulin-binding sites, are required to connect microtubules and actin. Tau thus represents a molecular linker between microtubule and actin networks, enabling a coordination of the two cytoskeletons that might be essential in various neuronal contexts.