Charge neutralization of lysine via carbamylation reveals hidden aggregation hot-spots in tau protein flanking regions.

Tau protein is found abundantly in neurofibrillary tangles in Alzheimer's disease (AD). The longest human tau isoform (2N4R) has 44 lysine residues. Several lysine-based post-translational modifications (PTMs) such as glycation, acetylation, ubiquitination, and sumoylation have been implicated not only in AD, but also in other tauopathies. Carbamylation is one such lysine neutralizing age-related nonenzymatic PTM which can modulate the aggregation propensity of tau. In this work, we have studied the aggregation potential of lysine-rich regions of tau upon carbamylation which do not aggregate in their native form. Using an array of biophysical and microscopic analyses, such as ThT kinetic assay, fluorescence microscopy, Congo red staining, and scanning electron microscopy, we demonstrate that peptides derived from four of five such regions exhibit robust fibrillar amyloid formation. These regions are found in the N-terminal projection domain that encompasses proline-rich domain (148-153 and 223-230), repeat domain R1 (253-260), as well as fibrillary core region (368-378), and can be described as hidden aggregation hot-spots which become activated upon carbamylation. We have further compared the impact of carbamylation with acetylation on the aggregation propensity of lysine-rich peptide (254 KKVAVV259 ) using biophysical experiments and molecular dynamics simulations and deduced that carbamylation is a much stronger driver of aggregation than acetylation. Our findings may offer more insight into amyloid fibrils' interaction with hidden aggregation-prone nucleating sequences that act as hot-spots for inducing tau fibrillation.