We present a straightforward, versatile method for expressing and purifying beta-amyloid (A beta 40) and transmembrane peptides derived from beta-amyloid precursor protein (A beta 55). In principle, these methods should be applicable to other types of strongly aggregating peptides. We start with a DNA plasmid encoding a HexaHis tag with a flexible, hydrophilic linker sequence, followed by a cleavage site, and then A beta peptides. The HexaHis tag rather than a protein fusion partner (e.g., GST) obviates the need for a folded protein in affinity purification. Second, we present two cleavage methods, using either Factor Xa or BNPS-Skatole. Although the latter procedure requires subsequent reduction of the product, we describe methods for minimizing side reactions. Because the use of BNPS-Skatole obviates the need for a folded protein in the cleavage reaction, it is compatible with harsh conditions (e.g., inclusion of detergents and denaturants) needed to solubilize the fusion proteins; such conditions tend to inactivate Factor Xa. Finally, we also describe purification strategies for A beta 40 and A beta 55 using FPLC and/or reverse phase HPLC. Yields of peptide after these BNPS-Skatole cleavage and peptide reduction, though subquantitative, greatly exceed those obtained using Factor Xa cleavage, as the reaction of BNPS-Skatole is insensitive to the presence of detergents and denaturants, and therefore can be used to produce highly aggregative and low solubility peptides such as A beta 55. Trp is a low abundance amino acid in proteins generally, and for peptides like A beta 55, and other transmembane peptides lacking Trp in relevant positions, this cleavage method remains a useful option.