Protist and Fungal Metaxin-like Proteins: Relationship to Vertebrate Metaxins that Function in Protein Import into Mitochondria

Abstract

ABSTRACTMetaxin-like proteins are shown to be encoded in the genomes of a wide range of protists and fungi. The metaxin proteins were originally described in humans and mice, and were experimentally demonstrated to have a role in the import of nascent proteins into mitochondria. In this study, metaxin-like proteins of protists and fungi predicted from genome sequences were identified by criteria including their sequence homology with vertebrate metaxin proteins and the existence of distinctive metaxin protein domains. Protists of diverse taxa, including amoebae, protozoa, phytoplankton, downy mildews, water molds, and algae, were found to possess genes for metaxin-like proteins. With fungi, the important taxonomic divisions (phyla) of Ascomycota, Basidiomycota, Chytridiomycota, Mucoromycota, and Zoopagomycota had species with metaxin-like protein genes. The presence of distinctive GST_N_Metaxin, GST_C_Metaxin, and Tom37 domains in the predicted proteins indicates that the protist and fungal proteins are related to the vertebrate metaxins. However, the metaxin-like proteins are not direct homologs of vertebrate metaxins 1, 2, or 3, but have similarity to each of the three. The alignment of the metaxin-like proteins of a variety of protists with vertebrate metaxins 1 and 2 showed about 26% and 19% amino acid identities, respectively, while for fungal metaxin-like proteins, the identities were about 29% and 23%. The different percentages with the two vertebrate metaxins indicates that the metaxin-like proteins are both metaxin 1-like and, to a lesser degree, metaxin 2-like. The secondary structures of protist and fungal metaxin-like proteins both consist of nine α-helical segments, the same as for the vertebrate metaxins, with a negligible contribution from β-strand. Phylogenetic analysis demonstrated that the protist and fungal metaxin-like proteins and the vertebrate metaxins form distinct and separate groups, but that the groups are derived from a common ancestral protein sequence.