Scientists discovered that a tiny three‑letter tag (SKM) at the end of a protein called human soluble epoxide hydrolase (hsEH) can send the protein into peroxisomes, but only under certain conditions. The tag alone isn’t enough – the protein needs to be made in large amounts or be shaped so the tag is exposed. This explains why hsEH is found both inside peroxisomes and in the cell’s fluid.

The peroxisomal targeting sequence 1 (PTS1) is a consensus tripeptide 1 (S/C/A)(K/R/H)(L/M) that is found at the C-terminus of most peroxisomal proteins. However, the only known mammalian protein containing a terminal methionine PTS1 (SKM), human soluble epoxide hydrolase (hsEH), shows both peroxisomal and cytosolic localizations in vivo. Mechanisms regulating the subcellular localization of hsEH thus remain unclear. Here we utilized green fluorescent protein-hsEH fusion constructs to study the peroxisomal targeting of hsEH in transiently and stably transfected Chinese hamster ovary cells. Our results suggest that the peroxisomal import of hsEH is regulated by three factors. First, we show that SKM is required, but not sufficient, for peroxisomal import. Second, by manipulating protein expression levels, we show that SKM mediates peroxisomal import of wild-type hsEH only when expression levels are high. Third, we show that amino acid modifications that decrease subunit oligomerization and presumably enhance accessibility of the SKM motif confer peroxisomal targeting even at low protein expression levels. We conclude that, in hsEH, SKM is a necessary but inefficient and context-dependent PTS1. Peroxisomal import occurs when expression levels are high or when the SKM motif is accessible. These results provide a mechanistic basis for understanding the cell-specific and tissue-specific localization of hsEH in vivo.