Poster Presentation 13th Australian Peptide Conference 2019

Novel methods for inhibiting amyloidogenesis in the presence of peptides in order to block hydrophobic interaction (#194)

Masatoshi Saiki 1 , Takafumi Shizuma 1 , Tomomi Ueda 1 , Ikumi Shibatate 1
  1. Sanyo-Onoda City University, Sanyo-Onoda City, Yamaguchi, Japan

Amyloid fibrils, which are caused by abnormal conformation and misassembly of proteins, are responsible for several conformational diseases, including prion diseases. Various mutants of the protein fragment barnase module-1 (BM1-24) have been investigated to discover the structural principle of amyloid-like fibrils. The fibril formation seems to be determined mainly by the linear arrangement of hydrophobic residues [1,2]. In the present study, which is based on this essential linear arrangement of hydrophobic residues, we constructed a structural model of the mechanism of amyloid blocking. To examine possible mechanisms underlying the inhibition of amyloid formation by certain amyloid-forming fragments—BM1-24, prion180-193, Amyloid β, serum amyloid A protein1-27—peptides with hydrophilic substitutions for BM1-24 were prepared. The peptides of 8- and 16-residue lengths were designed to have hydrophilic residues  (Gln, Glu, Asn, Asp, and Arg) on only one side of the β-sheet. As shown by the increase in the intensity of fluorescence in thioflavin T-binding assays, amyloid fragments when left alone formed amyloids. However, when these fragments were mixed with the synthetic inhibitor peptide, the result was a decline in the intensity of fluorescence, suggesting that amyloid formation had been inhibited. Amyloidogenesis thus appears to be specifically inhibited by disrupting the hydrophobic interactions between core amyloid regions.

 

[1] Saiki, M., Honda, S., Kawasaki, K., Zhou, D., Konakahara, T., Morii, H. (2005) J. Mol. Biol., 348, 983-998.

[2] Saiki, M., Konakahara, T., Morii, H. (2006) Biochem Biophys Res Commun., 343, 1262-1271.