The Complete Mitochondrial DNA Sequence of Mesostigma viride Identifies This Green Alga as the Earliest Green Plant Divergence and Predicts a Highly Compact Mitochondrial Genome in the Ancestor of All Green Plants

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Molecular Biology and Evolution 19:24-38 (2002)
© 2002 Society for Molecular Biology and Evolution

The Complete Mitochondrial DNA Sequence of Mesostigma viride Identifies This Green Alga as the Earliest Green Plant Divergence and Predicts a Highly Compact Mitochondrial Genome in the Ancestor of All Green Plants

Monique Turmel, Christian Otis and Claude Lemieux

Canadian Institute for Advanced Research, Département de Biochimie et de Microbiologie, Université Laval, Québec, Canada

To gain insights into the nature of the mitochondrial genomein the common ancestor of all green plants, we have completelysequenced the mitochondrial DNA (mtDNA) of Mesostigma viride.This green alga belongs to a morphologically heterogeneous class(Prasinophyceae) that includes descendants of the earliest diverginggreen plants. Recent phylogenetic analyses of ribosomal RNAs(rRNAs) and concatenated proteins encoded by the chloroplastgenome identified Mesostigma as a basal branch relative to theStreptophyta and the Chlorophyta, the two phyla that were previouslythought to contain all extant green plants. The circular mitochondrialgenome of Mesostigma resembles the mtDNAs of green algae occupyinga basal position within the Chlorophyta in displaying a smallsize (42,424 bp) and a high gene density (86.6% coding sequences).It contains 65 genes that are conserved in other mtDNAs. Althoughnone of these genes represents a novel coding sequence amonggreen plant mtDNAs, four of them (rps1, sdh3, sdh4, and trnL[caa])have not been reported previously in chlorophyte mtDNAs, andtwo others (rpl14 and trnI[gau]) have not been identified inthe streptophyte mtDNAs examined so far (land-plant mtDNAs).Phylogenetic analyses of 19 concatenated mtDNA-encoded proteinsfavor the hypothesis that Mesostigma represents the earliestbranch of green plant evolution. Four group I introns (two inrnl and two in cox1) and three group II introns (two in nad3and one in cox2), two of which are trans-spliced at the RNAlevel, reside in Mesostigma mtDNA. The insertion sites of thethree group II introns are unique to this mtDNA, suggestingthat trans-splicing arose independently in the Mesostigma lineageand in the Streptophyta. The few structural features that canbe regarded as ancestral in Mesostigma mtDNA predict that thecommon ancestor of all green plants had a compact mtDNA containinga minimum of 75 genes and perhaps two group I introns. Consideringthat the mitochondrial genome is much larger in size in landplants than in Mesostigma, we infer that mtDNA size began toincrease dramatically in the Streptophyta either during theevolution of charophyte green algae or during the transitionfrom charophytes to land plants.

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