Convergent evolutionary shifts in AGT targeting between mitochondria and peroxisomes across mammal transitions to herbivory.

Herbivory has evolved multiple times during mammalian diversification, playing a key role in the success of this globally distributed clade. A central metabolic challenge for herbivores is the detoxification of glyoxylate. The enzyme alanine:glyoxylate aminotransferase (AGT) converts glyoxylate to glycine, preventing the formation of harmful calcium oxalate crystals. AGT localizes to mitochondria and peroxisomes based on the mitochondrial targeting sequence (MTS) and the peroxisomal targeting signal (PTS1), respectively. While most studies focused on MTS, MTS variation alone does not fully explain AGT localization patterns. To assess the relative importance of the PTS1 motif, we combined comparative sequence analyses with functional assays. We find that multiple herbivorous lineages underwent independent mutations resulting in disrupted or truncated MTS regions, whereas the PTS1 motif remains functional. Immunofluorescence assays revealed more efficient peroxisomal localization of AGT in herbivores, with PTS1 often overriding mitochondrial signals even when the MTS is intact. Additionally, transcriptomic analyses show that several herbivorous lineages preferentially use downstream transcriptional start sites, producing AGT isoforms lacking the MTS. Together, our findings reveal a central role of AGT peroxisomal targeting in evolution of plant-based diets, and demonstrate how increased targeting efficiency has evolved convergently via the interplay of transcriptional regulation and targeting signals.