Abstract
Huntington's Disease (HD), the most prevalent polyglutamine (polyQ) neurodegenerative disorder, features brain aggregates induced by mutant huntingtin (mHtt) proteins harboring expanded polyQ tracts. Despite extensive efforts, molecular mechanisms of polyQ aggregates remain elusive. Here, we establish quantitative stimulated Raman scattering imaging of polyQ aggregates (q-aggSRS) for noninvasive investigations in live neuronal cocultures using deuterated glutamine labeling. Q-aggSRS allows for specific visualization by targeting the distinct Raman peak from carbon-deuterium bonds, eliminating the need for bulky fluorescent protein tagging (e.g., EGFP). Coupled with analysis from aggregate-tailored expansion microscopy, newly designed two-color imaging, and pulse-chase visualization, we comprehensively quantified the mHtt and non-mHtt proteins within the same aggregates across varying sizes, cell types, mHtt constructs, and subcellular locations. Our findings demonstrate a two-phase aggregate model with a distinct core-shell spatial organization, reveal significant heterogeneity in nucleus/cytoplasm compartmentalization specific to neurons, and identify previously unrecognized loosely packed aggregates specifically in neuronal nuclei. These insights should advance our understanding of native polyQ aggregates, and our proposed interaction coefficients may offer quantitative parameters for developing effective HD therapies.