Abstract
MAPL (mitochondria-associated protein ligase, also called MULAN/GIDE/MUL1) is a multifunctional mitochondrial outer membrane protein found in human cells that contains a unique BAM (beside a membrane) domain and a C-terminal RING-finger domain. MAPL has been implicated in several processes that occur in animal cells such as NF-kB activation, innate immunity and antiviral signaling, suppression of PINK1/parkin defects, mitophagy in skeletal muscle, and caspase-dependent apoptosis. Previous studies demonstrated that the BAM domain is present in diverse organisms in which most of these processes do not occur, including plants, archaea, and bacteria. Thus the conserved function of MAPL and its BAM domain remains an open question. In order to gain insight into its conserved function, we investigated the evolutionary origins of MAPL by searching for homologues in predicted proteomes of diverse eukaryotes. We show that MAPL proteins with a conserved BAM-RING architecture are present in most animals, protists closely related to animals, a single species of fungus, and several multicellular plants and related green algae. Phylogenetic analysis demonstrated that eukaryotic MAPL proteins originate from a common ancestor and not from independent horizontal gene transfers from bacteria. We also determined that two independent duplications of MAPL occurred, one at the base of multicellular plants and another at the base of vertebrates. Although no other eukaryote genome examined contained a verifiable MAPL orthologue, BAM domain-containing proteins were identified in the protists Bigelowiella natans and Ectocarpus siliculosis. Phylogenetic analyses demonstrated that these proteins are more closely related to prokaryotic BAM proteins and therefore likely arose from independent horizontal gene transfers from bacteria. We conclude that MAPL proteins with BAM-RING architectures have been present in the holozoan and viridiplantae lineages since their very beginnings. Our work paves the way for future studies into MAPL function in alternative model organisms like Capsaspora owczarzaki and Chlamydomonas reinhardtii that will help to answer the question of MAPL’s ancestral function in ways that cannot be answered by studying animal cells alone.
Highlights
Mitochondria are ubiquitous eukaryotic organelles derived from an ancient endosymbiotic αproteobacterium
Several mitochondrial proteins are closely related to α-proteobacterial proteins; it has been shown that many mitochondrial proteins are derived from bacteria not related to the endosymbiont [1,2]
The current study investigates the evolutionary origins of one such protein, the mitochondrial outer membrane protein MAPL
Summary
Mitochondria are ubiquitous eukaryotic organelles derived from an ancient endosymbiotic αproteobacterium. Tracing the evolutionary history of mitochondrial proteins is important in understanding how a free-living α-proteobacterium became an integrated eukaryotic organelle. The majority of the remaining mitochondrial proteins are eukaryote novelties that have no obvious homologues in bacteria [1,2]. Specific protein complexes are not either of endosymbiotic or eukaryotic origin, but instead, several systems like the mitochondrial import complexes and the complexes of the electron transport chain have mixed origins [2]. Some mitochondrial proteins have obscure evolutionary histories. The current study investigates the evolutionary origins of one such protein, the mitochondrial outer membrane protein MAPL (mitochondria-associated protein ligase, called MULAN/GIDE/MUL1)
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