Evolution of mitochondrial SSU-rDNA variable domain sequences and rRNA secondary structures, and phylogeny of the Agrocybe aegerita multispecies complex

Abstract

Mitochondrial small subunit (mtSSU) rDNA variable (V1, V2, V4, V6, V8 and V9) domain sequences and rRNA secondary structures evidenced eight molecular groups within 32 strains of the Agrocybe aegerita multispecies complex from different continents. mtSSU-rRNA secondary structure evolution occurred mainly by insertion/deletion of sequences from 8 to 57 nt long. Preferential insertion/deletion sites correlated with loops of the mtSSU-rRNA secondary structures, and suggested that these events occurred in regions without interactions in the ribosomal-protein assembly. Indels modified the stem length (V1 and V4 domains) or the size and loop number (V6 and V9 domains). Three indels inserted in the V1 and V4 domains had 76.5% to 94.7% identity with short sequences of the mitochondrial cytochrome c oxidase gene; this fact and the presence of inverted repeated motifs within indel sequences suggested a mechanism of evolution based on insertion/deletion of sequences from another region of the mitochondrial genome. Phylogenetic relationships inferred using both ribosomal DNA sequences and rRNA secondary structures were congruent and evidenced three clades within the A. aegerita complex: European, Argentinean, and a more distant Asian-American clade including A. aegerita and A. chaxingu strains. These results suggested that numerous genetic exchanges occurred between Asian-American strains after isolation of the European clade. V4-V6-V9 concatenated sequences of European and Argentinean clades had 86.1% identity, similar to the value calculated between two Agrocybe closely related species, suggesting that these clades could represent different species. A cleaved amplified polymorphic sequence test for rapid characterization of strains was developed.