Preparation and characterization of a highly soluble Aß1-42 peptide variant.

ABSTRACT

Alzheimer's disease (AD) is a progressive neurological disease marked by the accumulation and deposition of misfolded amyloid beta or Abeta (Aß) peptide. Two species of Aß peptides are found in amyloid plaques, Aß1-40 and Aß1-42, with the latter being the more amyloidogenic of the two. Understanding how and why Aß peptides misfold, oligomerize and form amyloid plaques requires a detailed understanding of their structure and dynamics. The poor solubility and strong aggregation tendencies of Aß1-42 has made the isolation and characterization of its different structural isoforms (monomer, dimer, oligomer, amyloid) exceedingly difficult. Furthermore, while synthetic Aß1-42 peptides (Aß42syn) are readily available, the cost of isotopically labeled peptide is substantial, making their characterization by NMR spectroscopy cost prohibitive. Here we describe the design, cloning, high-level production, isotopic labeling and biophysical characterization of a modified (solubility-tagged) Aß1-42 variant that exhibits excellent water solubility and shares similar aggregation properties as wildtype Aß1-42. Specifically, we attached six lysines (6K) to the C-terminus of native Aß1-42 to create a more soluble, monomeric form of Aß1-42 called Aß42C6K. A gene for the Aß42C6K was designed, synthesized and cloned into Escherichia coli (E. coli) and the peptide was expressed at milligram levels. The Aß42C6K peptide was characterized using circular dichroism (CD), NMR, electron microscopy and thioflavin T fluorescence. Its ability to form stable monomers, oligomers and fibrils under different conditions was assessed. Our results indicate that Aß42C6K stays monomeric at high concentrations (unlike Aß1-42) and can be induced to oligomerize and form fibrils like Aß1-42. Our novel construct could be used to explore the structure and dynamics of Aß1-42 as well as the interaction of ligands with Aß1-42 via NMR.