The Complete Mitochondrial Genome Sequence of the Spider Habronattus oregonensis Reveals Rearranged and Extremely Truncated tRNAs

doi:10.1093/molbev/msh096

MBE Advance Access originally published online on March 10, 2004

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Mol. Biol. Evol. 21(5):893-902. 2004
DOI: 10.1093/molbev/msh096
© 2004 by the Society for Molecular Biology and Evolution. ISSN: 0737-4038

The Complete Mitochondrial Genome Sequence of the Spider Habronattus oregonensis Reveals Rearranged and Extremely Truncated tRNAs

Susan E. Masta¹ and Jeffrey L. Boore

Department of Energy Joint Genome Institute, Department of Evolutionary Genomics, Walnut Creek, California

E-mail: smasta{at}pdx.edu.

We sequenced the entire mitochondrial genome of the jumpingspider Habronattus oregonensis of the arachnid order Araneae(Arthropoda: Chelicerata). A number of unusual features distinguishthis genome from other chelicerate and arthropod mitochondrialgenomes. Most of the transfer RNA (tRNA) gene sequences aregreatly reduced in size and cannot be folded into typical cloverleaf-shapedsecondary structures. At least nine of the tRNA sequences lackthe potential to form T ${Psi}$ C arm stem pairings and instead are inferredto have TV-replacement loops. Furthermore, sequences that couldencode the 3' aminoacyl acceptor stems in at least 10 tRNAsappear to be lacking, because fully paired acceptor stems arenot possible and because the downstream sequences instead encodeadjacent genes. Hence, these appear to be among the smallestknown tRNA genes. We postulate that an RNA editing mechanismmust exist to restore the 3' aminoacyl acceptor stems to allowthe tRNAs to function. At least seven tRNAs are rearranged withrespect to the chelicerate Limulus polyphemus, although thearrangement of the protein-coding genes is identical. Most mitochondrialprotein-coding genes of H. oregonensis have ATN as initiationcodons, as commonly found in arthropod mtDNAs, but cytochromeoxidase subunits 2 and 3 genes apparently use TTG as an initiationcodon. Finally, many of the gene sequences overlap one anotherand are truncated. This 14,381-bp genome, the first mitochondrialgenome of a spider yet sequenced, is one of the smallest arthropodmitochondrial genomes known. We suggest that posttranscriptionalRNA editing can likely maintain function of the tRNAs, whilepermitting the accumulation of mutations that would otherwisebe deleterious. Such mechanisms may have allowed for the minimizationof the spider mitochondrial genome.

Key Words: mitochondrial genome • tRNA editing • aminoacyl acceptor stem • gene rearrangement • genome size • Habronattus oregonensis

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