RNA editing in plant mitochondria

RNA editing in plant mitochondria alters nearly all mRNAs by C to U and U to C transitions. In some species more than 400 edited sites have been identified with significant effects on the encoded proteins. RNA editing occurs in higher and lower plants and presumably has evolved before the differentiation of land plants. Current research focuses on the elucidation of the biochemistry and the specificity determinants of RNA editing in plant mitochrondria.     

Ribosomal protein S14 transcripts are edited in Oenothera mitochondria

The gene encoding ribosomal protein S14 (rps14) in Oenothera mitochondria is located upstream of the cytochrome b gene (cob). Sequence analysis of independently derived cDNA clones covering the entire rps14 coding region shows two nucleotides edited from the genomic DNA to the mRNA derived sequences by C to U modifications. A third editing event occurs four nucleotides upstream of the AUG initiation codon and improves a potential ribosome binding site. A CGG codon specifying arginine in a position conserved in evolution between chloroplasts and E. coli as a UGG tryptophan codon is not edited in any of the cDNAs analysed. An inverted repeat 3' of an unidentified open reading frame is located upstream of the rps14 gene. The inverted repeat sequence is highly conserved at analogous regions in other Oenothera mitochondrial loci.     

Neutron scattering study of the 13 S fragment of 16 S RNA and its complex with ribosomal protein S4

A fragment with a molecular weight of 170,000 and a sedimentation coefficient of 13 S which is capable of specifically binding ribosomal protein S4 has been obtained by digestion of Escherichia coli 16 S RNA with ribonuclease A. The 13 S fragment of 16 S RNA and its complex with protein S4 have been studied by different physical methods; in the first place, by neutron scattering. It has been shown that this fragment is very compact in solution. The radii of gyration of this fragment (50 ± 3 Å) and of protein S4 within the complex (17 ± 3 Å) coincide, within the limits of experimental error, with the radii of gyration for the free RNA fragment (47 ± 2 Å) and the free ribosomal protein S4 in solution (18 ± 2 Å). Hence the conclusion is drawn that the compactness of the RNA fragment and the ribosomal protein does not change on complex formation. The compact 13 S fragment of 16 S RNA is shown to be contrast-matched in solvent containing 70% ²H₂O which corresponds to a value for the partial specific volume of RNA of 0.537 cm³/g.     

Characterization of the S7 ribosomal protein gene in wheat mitochondria

Summary By screening a wheat mitoplast cDNA bank, we have identified an open reading frame of 444 by that has a derived amino acid sequence homologous to bacterial-type S7 ribosomal proteins. This gene, designated rps7, is located upstream of one of two 26S rRNA gene copies in the wheat mitochondrial genome and is expressed as an abundant mRNA of approximately 0.7 kb. Its 5 terminus maps to the end of an 80 by element that is closely related to sequences preceding the wheat coxII, orf25 and atp6 genes. Southern hybridization analysis indicates that rps7-homologous sequences are present in the mitochondria of rice and pea, but not soybean.     

Isolation and physical study of the 13S fragment of 16S RNA and its complex with ribosomal protein S4

A fragment of E. coli 16S RNA has been obtained by its hydrolysis with pancreatic RNAase A coupled to Sepharose 4B. This fragment has a molecular weight of 170 000 and a sedimentation coefficient of 13S. It does not aggregate in solution and binds with the ribosomal protein S4. The 13S fragment and it complex with the protein S4 have been studied by different physical methods in the first place, by neutron scattering. It has been shown that this fragment is compact in solution. The radii of gyration of the fragment (50 +/- 3 A) and of the protein S4 within the complex (17 +/- 3 A) coincide, within limits of experimental error, with the radii of gyration for the free RNA fragment (47 +/- 2 A) and the free ribosomal protein S4 in solution (18 +/- 2 A). Hence, the conclusion is made that the compactness of the 13S fragment of the 16S RNA and the ribosomal protein S4 does not change at the complex formation. The compact 13S fragment of the 16S RNA is shown to be contrast matched in the H2O/D2O mixture containing 70% D2O which corresponds to its partial specific volume v equal to 0.537 cm3/g.     

Epitopes ofEscherichia coli ribosomal protein S13

To analyze the immunochemical structure ofEscherichia coli ribosomal protein S13 and its organizationin situ, we have generated and characterized 22 S13-specific monoclonal antibodies. We used a competitive enzyme-linked immunosorbent assay to divide them into groups based on their ability to inhibit binding of one another. The discovery of five groups with distinct binding properties suggested that a minimum of five distinct determinants on S13 are recognized by our monoclonal antibodies. The locations of the epitopes detected by these monoclonal antibodies have been mapped on S13 peptides. Three monoclonal antibodies bind a S13 C-terminal 34-residue segment. All the other 19 monoclonal antibodies bind a S13N-terminal segment of about 80 residues. The binding sites of these 19 monoclonal antibodies have been further mapped to subfragments of peptides. Two monoclonal antibodies recognized S13_1–22; three monoclonal antibodies bound to S13_1–40; the binding sites of three other antibodies have been located in S13_23–80, with epitopes possibly associated with residues 40–80. The remaining 11 monoclonal antibodies did not bind to these subfragments. These data provide molecular basis to the structure of S13 epitopes, whosein situ accessibility may reveal the S13 organization on the ribosome.