Specific Combinations of Physiological Tau Phosphorylation Regulate Tau-Microtubule Interactions in Developing Neurons.

Tau phosphorylation is a defining feature of Alzheimer's disease, yet it also plays an essential physiological role in stabilizing microtubules (MTs) during normal neuronal development. While individual phosphorylation sites have been well-studied in pathology, it remains largely unknown how combinatorial phosphorylation is regulated under physiological conditions. Here, we uncover distinct, site-specific phosphorylation patterns on tau in developing human neurons. With top-down mass spectrometry we find that functional, endogenous tau is highly modified, with up to 21 phosphates per molecule. We identify patterns of co-occurrence between phosphorylation sites that are in proximity in the linear protein sequence, such as epitopes S202/T205/T212/T217 and T231/S235/S262. Moreover, these phospho-epitopes define discrete pools of tau and regulate tau-MT interactions in coordination, providing a mechanism for fine-tuning the binding of tau to MTs. Intriguingly, we find that co-occurring phospho-epitopes are dynamically regulated in response to changes in MT integrity; chemical perturbation of neuronal MTs promotes rapid tau dephosphorylation by phosphatase PP2a at most sites to enhance tau-MT interactions and counteract destabilization. We then use the PS19 tauopathy mouse model to demonstrate that developmental and pathological tau phosphorylation patterns partially overlap, and that co-occurring phospho-epitopes exhibit similar associations with the insoluble fraction in aged mice. Our results reveal an isoform-dependence on the effects of site-specific tau phosphorylation on its behavior. Together, these findings define a combinatorial phosphorylation code that modulates tau's physiological function in neurons and raises the possibility that MT destabilization precedes tau phosphorylation in disease. This work provides a mechanistic framework for distinguishing functional from pathological tau phosphorylation, with implications for the development of therapies that specifically target disease-associated tau proteoforms.