(826.15) Misfolding Propensity of SAA1 Fragments: Special Focus on the Signal Peptide Region

Poster Board Number: D33

Morgan Haines (Purdue University), James Pirela (Pontifical Catholic University of Puerto Rico), Kendra Nylen (Michigan State University), Jessica Fortin (Purdue University)

AA amyloid is the most common form of systemic amyloidosis reported in human medicine and across animal species. AA amyloidosis is the result of over-production by hepatocytes and aberrant processing of acute-phase serum amyloid A1 (SAA1). Proteolytic cleavage of SAA1 is believed to play a central role in AA amyloid formation. The SAA1 protein is of 122 amino acids (aa) and undergoes a first cleavage of 18 residues consisting of the signal peptide at the N-terminal region. The aggregation propensity of the signal peptide region has never been studied. To better understand the mechanism behind systemic amyloidosis in the SAA1 protein, we studied the misfolding propensity of the signal peptide region considering that SAA1 is going through further cleavage processes. The goal of this research was to determine the propensity of the SAA1 signal peptide region to generate fibrils. We examined the signal peptide amino acid sequence of serum amyloid A1 (SAA1) derived from different animal species. A library of the 25 peptides was designed to study the fibril formation using in silico analysis and in vitro assays. The amyloidogenic potential of each SAA1 signal peptide homolog was assessed using thioflavin T fluorescence assays, Congo red binding assays, and transmission electron microscopy. After 7 days of incubation, 22 SAA1 signal peptide fragments had the propensity to form fibrils at a concentration of 500 µM with 50% hexafluoroisopropanol at 37 ºC. The signal peptide region might be important in contributing to the misfolding of aggregation-prone proteins. Characterizing these conformations are relevant as they may be involved in seeding intact and/or fragmented SAA1, contributing to mechanism of misfolding. This information could be important for continuation studies in the understanding of misfolding disorders.