A Subset of Conserved tRNA Genes in Plastid DNA of Nongreen Plants

A Subset of Conserved tRNA Genes in Plastid DNA of Nongreen Plants

Amanda J. Lohan^a and Kenneth H. Wolfe^a
^a Department of Genetics, University of Dublin, Trinity College, Dublin 2, Ireland

Corresponding author: Kenneth H. Wolfe, Department of Genetics, University of Dublin, Trinity College, Dublin 2, Ireland., khwolfe{at}tcd.ie (E-mail).

Communicating editor: G. B. GOLDING

The plastid genome of the nonphotosynthetic parasitic plantEpifagus virginiana contains only 17 of the 30 tRNA genes normallyfound in angiosperm plastid DNA. Although this is insufficientfor translation, the genome is functional, so import of cytosolictRNAs into plastids has been suggested. This raises the questionof whether the tRNA genes that remain in E. virginiana plastidDNA are active or have just fortuitously escaped deletion. Wereport the sequences of 20 plastid tRNA loci from Orobancheminor, which shares a nonphotosynthetic ancestor with E. virginiana.The two species have 9 intact tRNA genes in common, the othersbeing defunct in one or both species. The intron-containingtrnL_UAA gene is absent from E. virginiana, but it is intact,transcribed, and spliced in O. minor. The shared intact genesare better conserved than intergenic sequences, which indicatesthat these genes are being maintained by natural selection and,therefore, must be functional. For the most part, the tRNA speciesconserved in nonphotosynthetic plastids are also those thathave never been found to be imported in plant mitochondria,which suggests that the same rules may govern tRNA import inthe two organelles. A small photosynthesis gene, psbI, is stillintact in O. minor, and computer simulations show that somesmall nonessential genes have an appreciable chance of escapingdeletion.

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