Synthesis and turnover of mitochondrial ribonucleic acid in HeLa cells: the mature ribosomal and messenger ribonucleic acid species are metabolically unstable.

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Mol Cell Biol. 1981 June; 1(6): 497-511

Synthesis and turnover of mitochondrial ribonucleic acid in HeLa cells: the mature ribosomal and messenger ribonucleic acid species are metabolically unstable.

R Gelfand and G Attardi

Division of Biology, California Institute of Technology, Pasadena 91125.

ABSTRACT

The synthesis rates and half-lives of the individual mitochondrialribosomal ribonucleic acid (RNA) and polyadenylic acid-containingRNA species in HeLa cells have been determined by analyzingtheir kinetics of labeling with [5-3H]-uridine and the changesin specific activity of the mitochondrial nucleotide precursorpools. In one experiment, a novel method for determining thenucleotide precursor pool specific activities, using nascentRNA chains, has been utilized. All mitochondrial RNA speciesanalyzed were found to be metabolically unstable, with half-livesof 2.5 to 3.5 h for the two ribosomal RNA components and between25 and 90 min for the various putative messenger RNAs. A cordycepin"chase" experiment yielded half-life values for the messengerRNA species which were, in general, larger by a factor of 1.5to 2.5 than those estimated in the labeling kinetics experiments.On the basis of previous observations, a model is proposed wherebythe rate of mitochondrial RNA decay is under feedback controlby some mechanism linked to RNA synthesis or processing. A shorthalf-life was determined for five large polyadenylated RNAs,which are probably precursors of mature species. A rate of synthesisof one to two molecules per minute per cell was estimated forthe various H-strand-coded messenger RNA species, and a rateof synthesis 50 to 100 times higher was estimated for the ribosomalRNA species. These data indicate that the major portion of theH-strand in each mitochondrial deoxyribonucleic acid moleculeis transcribed very infrequently, possibly as rarely as onceor twice per cell generation. Furthermore, these results areconsistent with a previously proposed model of H-strand transcriptionin the form of a single polycistronic molecule.

Mol Cell Biol. 1981 June; 1(6): 497-511

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