Abstract

Tau is a microtubule-associated protein thought to function in the regulation of microtubule stability and dynamics. Normally, tau plays an important role in modulating axonal microtubules in neurons, where it is highly expressed. Intracellular tau aggregates are found in a broad class of disorders, including Alzheimer's Disease, termed tauopathies. As an intrinsically disordered protein, tau lacks stable secondary and tertiary structure, and this structural disorder is maintained even when binding to soluble tubulin and microtubules. Multiple tau-tubulin binding sites have also been identified, spanning the proline-rich region (PRR), microtubule binding repeats (MTBR: R1-R4), and pseudo-repeat, R′. Although dozens of post-translational modifications have been identified on tau, phosphorylation, and specifically hyperphosphorylation, of tau is correlated with disease and alterations to microtubule binding. Intriguingly, potential phosphorylation sites also cluster with high frequency within the PRR. Our lab has recently demonstrated that the isolated PRR both binds tubulin and has tubulin polymerization capacity. Here, we use fluorescence correlation spectroscopy (FCS) in conjunction with bulk polymerization measurements to characterize the impact of phosphomimic mutations in the PRR on tubulin binding and polymerization. We find that single phosphomimics affect tubulin binding nominally, with T231E having the most significant impact. However, as phosphorylation events rarely occur in isolation on tau, we also tested combinatorial effects. We found that multiple phosphomimics alter tubulin binding and microtubule polymerization. Furthermore, we used mass spectrometry to map the regions of the PRR involved in tubulin binding. Together these measurements provide insight into previously overlooked relevance of tau's PRR in functional interactions with tubulin.

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