Contribution of ultra-short invasive elements to the evolution of the mitochondrial genome in the genus Podospora.

In the filamentous fungus Podospora anserina, senescence is associated with major rearrangements of the mitochondrial DNA. The undecamer GGCGCAAGCTC has been described as a preferential site for these recombination events. We show that: (i) copies of this short sequence GGCGCAAGCTC are present in unexpectedly high numbers in the mitochondrial genome of this fungus; (ii) a short cluster of this sequence, localised in a group II intronic ORF, encodes amino acids that disrupt a protein domain that is otherwise highly conserved between various species; (iii) most of the polymorphisms observed between three related species, P.anserina, P.curvicolla and P.comata, are associated with the presence/absence of this sequence; (iv) this element lies at the boundaries of major rearrangements of the mitochondrial genomes; (v) at least two other short elements in the Podospora mitochondrial genomes display similar features. We suggest that these short elements, called MUSEs (mitochondrial ultra-short elements), could be mobile and that they contribute to evolution of the mitochondrial genome in the genus Podospora. A model for mobility involving a target DNA-primed reverse transcription step is discussed.