Using Secondary Structure to Identify Ribosomal Numts: Cautionary Examples from the Human Genome

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Molecular Biology and Evolution 19:93-100 (2002)
© 2002 Society for Molecular Biology and Evolution

Using Secondary Structure to Identify Ribosomal Numts: Cautionary Examples from the Human Genome

Link E. Olson and Anne D. Yoder¹

Department of Cell and Molecular Biology, Northwestern University Medical School, Chicago;
Division of Mammals, Field Museum of Natural History, Chicago

The identification of inadvertently sequenced mitochondrialpseudogenes (numts) is critical to any study employing mitochondrialDNA sequence data. Failure to discriminate numts correctly canconfound phylogenetic reconstruction and studies of molecularevolution. This is especially problematic for ribosomal mtDNAgenes. Unlike protein-coding loci, whose pseudogenes tend toaccumulate diagnostic frameshift or premature stop mutations,functional ribosomal genes are not constrained to maintain areading frame and can accumulate insertion-deletion events ofvarying length, particularly in nonpairing regions. Severalauthors have advocated using structural features of the transcribedrRNA molecule to differentiate functional mitochondrial rRNAgenes from their nuclear paralogs. We explored this approachusing the mitochondrial 12S rRNA gene and three known 12S numtsfrom the human genome in the context of anthropoid phylogenyand the inferred secondary structure of primate 12S rRNA. Contraryto expectation, each of the three human numts exhibits strikingconcordance with secondary structure models, with little, ifany, indication of their pseudogene status, and would likelyescape detection based on structural criteria alone. Furthermore,we show that the unwitting inclusion of a particularly ancient(18–25 Myr old) and surprisingly cryptic human numt ina phylogenetic analysis would yield a well-supported but dramaticallyincorrect conclusion regarding anthropoid relationships. Thoughwe endorse the use of secondary structure models for inferringpositional homology wholeheartedly, we caution against relianceon structural criteria for the discrimination of rRNA numts,given the potential fallibility of this approach.

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