Search Results (2)

Transthyretin (TTR) variant (V30M) polyneuropathy (ATTRv-PN) is a progressive systemic amyloidosis caused by transthyretin aggregation, leading to a variety of debilitating manifestations, including neuropathy and cardiomyopathy. We investigated the plasma proteome of heterozygotic V30M TTR asymptomatic carriers and heterozygotic V30M ATTRv-PN patients (before and after tafamidis treatment) versus WT TTR healthy control plasma using an organic solvent-induced shift in solubility assay to identify biosignatures for disease progression and therapeutic response. We identified many proteins, including TTR, apolipoproteins, ceruloplasmin, and proteins with functions in innate immunity that displayed changes in either their abundances or their sensitivity to precipitation. Elevated oxidative modifications of TTR and APOE in ATTRv-PN patients suggest a role for oxidative stress in disease pathogenesis/progression. Tafamidis treatment mitigated these pathology-associated changes, suggesting that alleviating proteotoxic stress impacts these other pathways. Although our study was limited to a Portuguese cohort, these findings nevertheless provide a comprehensive plasma proteomic profile of V30M ATTRv-PN patients, V30M TTR carriers, and tafamidis-treated ATTRv-PN patients over up to 60 months; provide insights into ATTRv-PN pathophysiology; identify potential biomarkers for disease progression and therapeutic response; and highlight the utility of proteomics in advancing personalized treatments for amyloidosis. Full article

One of the molecular hallmarks of amyloidoses is ordered protein aggregation involving the initial formation of soluble protein oligomers that eventually grow into insoluble fibrils. The identification and characterization of molecular species critical for amyloid fibril formation and disease development have been the focus of intense analysis in the literature. Here, using photo-induced cross-linking of unmodified proteins (PICUP), we studied the early stages of oligomerization of human transthyretin (TTR), a plasma protein involved in amyloid diseases (ATTR amyloidosis) with multiple clinical manifestations. Upon comparison, the oligomerization processes of wild-type TTR (TTRwt) and several TTR variants (TTRV30M, TTRL55P, and TTRT119M) clearly show distinct oligomerization kinetics for the amyloidogenic variants but a similar oligomerization mechanism. The oligomerization kinetics of the TTR amyloidogenic variants under analysis showed a good correlation with their amyloidogenic potential, with the most amyloidogenic variants aggregating faster (TTRL55P > TTRV30M > TTRwt). Moreover, the early stage oligomerization mechanism for these variants involves stepwise addition of monomeric units to the growing oligomer. A completely different behavior was observed for the nonamyloidogenic TTRT119M variant, which does not form oligomers in the same acidic conditions and even for longer incubation times. Thorough characterization of the initial steps of TTR oligomerization is critical for better understanding the origin of ATTR cytotoxicity and developing novel therapeutic strategies for the treatment of ATTR amyloidosis. Full article