Neighbouring modifications interfere with the detection of phosphorylated alpha-synuclein at Serine 129: Revisiting the specificity of pS129 antibodies

Abstract

AbstractAlpha-synuclein (aSyn) within Lewy bodies, Lewy neurites, and other pathological hallmarks of Parkinson’s disease and synucleinopathies have consistently been shown to accumulate in aggregated and phosphorylated forms of the protein, predominantly at Serine 129 (S129). Antibodies against phosphorylated S129 (pS129) have emerged as the primary tools to investigate, monitor, and quantify aSyn pathology in the brain and peripheral tissues. However, most of the antibodies and immunoassays aimed at detecting pS129-aSyn were developed based on the assumption that neighbouring post-translational modifications (PTMs) either do not co-occur with pS129 or do not influence its detection. Herein, we demonstrate that the co-occurrence of multiple pathology-associated C-terminal PTMs (e.g., phosphorylation at Tyrosine 125 or truncation at residue 133 or 135) differentially influences the detection of pS129-aSyn species by pS129-aSyn antibodies. These observations prompted us to systematically reassess the specificity of the most commonly used pS129 antibodies against monomeric and aggregated forms of pS129-aSyn in mouse brain slices, primary neurons, mammalian cells and seeding models of aSyn pathology formation. We identified two antibodies that are insensitive to pS129 neighbouring PTMs. However, consistent with previous reports, most pS129 antibodies showed cross-reactivity towards other proteins and often detected low and high molecular weight bands in aSyn knock-out samples that could be easily mistaken for monomeric or High Molecular Weight aggregates of aSyn. Our observations suggest that the pS129 antibodies do not capture the biochemical and morphological diversity of aSyn pathology. They also underscore the need for more specific pS129 antibodies, more thorough characterization and validation of existing antibodies, and the use of the appropriate protein standards and controls in future studies.