Transcellular propagation of protein aggregates, or proteopathic seeds, may drive the progression of neurodegenerative diseases in a prion-like manner. In tauopathies such as Alzheimer's disease, this model predicts that tau seeds propagate pathology through the brain via cell-cell transfer in neural networks. The critical role of tau seeding activity is untested, however. It is unknown whether seeding anticipates and correlates with subsequent development of pathology as predicted for a causal agent. One major limitation has been the lack of a robust assay to measure proteopathic seeding activity in biological specimens. We engineered an ultrasensitive, specific, and facile FRET-based flow cytometry biosensor assay based on expression of tau or synuclein fusions to CFP and YFP, and confirmed its sensitivity and specificity to tau (∼300 fM) and synuclein (∼300 pM) fibrils. This assay readily discriminates Alzheimer's disease vs. Huntington's disease and aged control brains. We then carried out a detailed time-course study in P301S tauopathy mice, comparing seeding activity versus histological markers of tau pathology, including MC1, AT8, PG5, and Thioflavin S. We detected robust seeding activity at 1.5 mo, >1 mo before the earliest histopathological stain. Proteopathic tau seeding is thus an early and robust marker of tauopathy, suggesting a proximal role for tau seeds in neurodegeneration.amyloid | neuropathology | dementia | aging P rotein aggregation characterizes many neurodegenerative disorders, including Alzheimer's disease (AD) and the related tauopathies. These disorders feature the accumulation of fibrillar deposits of the microtubule-associated protein tau with progressive deterioration of the central nervous system. Tau pathology and its associated brain atrophy do not appear randomly throughout the brain, but rather progress along distinct neural networks (1-5). This aspect suggests a role for transcellular spread of a pathogenic agent via neural connections. Our laboratory and others have previously hypothesized that tau aggregates-or seeds-serve as this agent of spread, transmitting the aggregated state from cell to cell via prion-like mechanisms (6-15).Mounting fundamental insights support this hypothesis. Tau seeds applied to the outside of cells bind the cell surface by attaching to heparan sulfate proteoglycans, triggering uptake by macropinocytosis (13). Upon internalization, tau seeds nucleate the fibrillization of endogenous tau monomer via templated conformational change, or seeding (8, 10). Tau seeding requires a critical unit of size for activity, as only particular species propagate the aggregated state (16). In vivo studies have described tau protein spreading from local sites to distant regions, presumably via transsynaptic movement (11,12,(17)(18)(19). Finally, our laboratory and another recently demonstrated that tau propagates discrete amyloid conformations through the brains of animals that give rise to unique neuropathologies (18,20).Despite this evidence, it remains unclear wheth...
