Polyadenylation Occurs at Multiple Sites in Maize Mitochondrial cox2 mRNA and Is Independent of Editing Status

doi:10.1105/tpc.11.8.1565

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Polyadenylation Occurs at Multiple Sites in Maize Mitochondrial cox2 mRNA and Is Independent of Editing Status

D. Shelley Lupold^a,b, Angelina G. F. S. Caoile^b, and David B. Stern^b
^a Section of Genetics and Development, Cornell University, Ithaca, NY 14853
^b Boyce Thompson Institute for Plant Research, Cornell University, Ithaca, NY 14853-1801

Correspondence to: David B. Stern, ds28{at}cornell.edu (E-mail), 607-255-6695 (fax)

Polyadenylation of nucleus-encoded transcripts has a well-definedrole in gene expression. The extent and function of polyadenylationin organelles and prokaryotic systems, however, are less welldocumented. Recent reports of polyadenylation-mediated RNA destabilizationin Escherichia coli and in vascular plant chloroplasts promptedus to look for polyadenylation in plant mitochondria. Here,we report the use of reverse transcription–polymerasechain reaction to map multiple polyadenylate addition sitesin maize mitochondrial cox2 transcripts. The lack of sequenceconservation surrounding these sites suggests that polyadenylationmay occur at many 3' termini created by endoribonucleolyticand/or exoribonucleolytic activities, including those activitiesinvolved in 3' end maturation. Endogenous transcripts couldbe efficiently polyadenylated in vitro by using maize mitochondriallysates with an activity that added AMP more efficiently thanGMP. Polyadenylated substrates were tested for stability inmaize mitochondrial S100 extracts, and we found that, comparedwith nonpolyadenylated RNAs, the polyadenylated substrates wereless stable. Taken together with the low abundance of polyadenylatedRNAs in maize mitochondria, our results are consistent witha degradation-related process. The fact that polyadenylationdoes not dramatically destabilize plant mitochondrial transcripts,at least in vitro, is in agreement with results obtained foranimal mitochondria but differs from those obtained for chloroplastsand E. coli. Because fully edited, partially edited, and uneditedtranscripts were found among the cloned polyadenylated cox2cDNAs, we conclude that RNA editing and polyadenylation areindependent processes in maize mitochondria.

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