C to U editing of apt9, nad3, and cox2 mRNAs was investigated in maize seedlings at various developmental stages as well as in suspension-cultured cells. Heterogeneity of mRNAs that result from incomplete editing was analyzed for each gene and from five tissues or developmental conditions. The editing status of approximately 30 cDNA clones was determined by digestion with a restriction enzyme that discriminates between unedited and edited DNA sequences. The atp9 and spliced cox2 cDNAs were essentially completely edited in all samples examined. Analysis of three editing sites of nad3 cDNAs indicated that incompletely edited cDNAs were detected in all tissues and treatments with a temporal increase in the overall editing status, from 50% at 3 days to about 75% at 7 days. These results indicate that incompletely edited mRNAs are prevalent for some plant mitochondrial genes, and can change with developmental or growth conditions.
The distribution of maize mitochondrial transcripts in polysomal RNA fractions obtained from root tissue, shoot tissue, or isolated intact mitochondria was analyzed. The distribution of cox3 transcripts that differ in 5' untranslated RNA sequence was similar in total polysomal and total mitochondrial RNA fractions, suggesting that 5' heterogeneity does not affect recruitment of transcripts into the polysomal RNA. The distribution of spliced and unspliced cox2 transcripts was also analyzed in polysomes from total tissue or isolated mitochondria, and both precursor and mature mRNAs were present in the high-molecular-weight RNA fraction. These results suggest that ribosomal association with mitochondrial transcripts is not selective.
Cytidine to uridine (C-to-U) editing occurs in plant mitochondria with very high specificity such that only specific cytidines are converted to uridines. The mechanisms for editing site selection in plant mitochondria are unknown. In order to examine the determinants of editing site recognition, repeated mitochondrial DNA sequences that include edited nucleotides have been evaluated as editing substrates. During evolution the maize mitochondrial ribosomal protein subunit 12 (rps12) gene recombined with intron 1 of the ribosomal protein subunit 3 (rps3) gene and a region of the S1-like sequence of the 2.3 kb plasmid. These recombinations created a second copy of an internal portion of the rps12 gene, known as rps12b, which includes the first four editing sites of rps12 transcripts. The duplicated sequence extends seven nucleotides upstream of editing site 1 and six nucleotides downstream from editing site 4. The sequences of rps12 and rps12b are identical between these sites except for a single change at -5 from editing site 1. These modifications did not effect C-to-U conversion at editing sites 2, 3, or 4 in rps12b; however, no editing was detected at editing site 1 in rps12b cDNAs. Thus, the 5' recombination abolished editing at site I, while the 3' recombination modified the downstream RNA sequence, but did not effect editing at site IV. Secondary structure prediction suggests that changes in editing site recognition do not correlate with differences in secondary structures, and that primary RNA sequence may be responsible for editing site specification.
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