Gene fragmentation: a key to mitochondrial genome evolution in Euglenozoa?

Abstract

Phylum Euglenozoa comprises three groups of eukaryotic microbes (kinetoplastids, diplonemids, and euglenids), the mitochondrial (mt) genomes of which exhibit radically different modes of organization and expression. Gene fragmentation is a striking feature of both euglenid and diplonemid mtDNAs. To rationalize the emergence of these highly divergent mtDNA types and the existence of insertion/deletion RNA editing (in kinetoplastids) and trans-splicing (in diplonemids), we propose that in the mitochondrion of the common evolutionary ancestor of Euglenozoa, small expressed gene fragments promoted a rampant neutral evolutionary pathway. Interactions between small antisense transcripts of these gene fragments and full-length transcripts, assisted by RNA-processing enzymes, permitted the emergence of RNA editing and/or trans-splicing activities, allowing the system to tolerate indel mutations and further gene fragmentation, respectively, and leading to accumulation of additional mutations. In this way, dramatically different mitochondrial genome structures and RNA-processing machineries were able to evolve. The paradigm of constructive neutral evolution acting on the widely different mitochondrial genetic systems in Euglenozoa posits the accretion of initially neutral molecular interactions by genetic drift, leading inevitably to the observed 'irremediable complexity'.