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.     

The NADH-dehydrogenase subunit 5 gene in Oenothera mitochondria contains two introns and is co-transcribed with the 5 S rRNA gene

Summary The gene encoding subunit 5 of the NADH dehydrogenase complex (ND 5) has been identified in Oenothera mitochondria from a cDNA clone. The coding region is interrupted by a type II intron of 850 nucleotides and a second intervening sequence of 357 nucleotides. Genomic sequence rearrangement within the first intron creates a nontranscribed partial copy of the gene. The intact ND 5 gene is transcribed in a complex pattern with mRNAs including the 5 S rRNA sequence. Excision of the two introns appears to proceed slowly in vivo since the steady state mitochondrial RNA contains significant proportions of unprocessed precursor molecules.     

RNA editing in trans-splicing intron sequences of nad2 mRNAs in Oenothera mitochondria.

The complete open reading frame of subunit 2 of the NADH dehydrogenase in Oenothera mitochondria is split into five exons. The first two and the last three exons are encoded in distant genomic locations and are transcribed separately. Three tRNA genes coding for tRNA(Cys), tRNA(Asn), and tRNA(Tyr) are located upstream of the terminal three exons c, d, and e. The genomic distance, the interspersed tRNA genes, and the group II intron sequences flanking the two separated exons suggest trans-splicing to be required to connect exons b and c. Maturation of the mRNA includes RNA editing at 36 sites in the open reading frame. Three RNA editing events are observed in the split group II intron sequences. Two of these events allow after editing additional base pairings in the secondary structure, one in the stem of domain I, the other in the putative trans-pairing region of domain IV. These RNA editings may thus be involved in the trans-splicing reaction.     

The nad4L-orf25 gene cluster is conserved and expressed in sugar beet mitochondria

We have found that a gene coding for NADH dehydrogenase subunit 4L and a presumed gene, orf25, are linked and co-transcribed with each other in sugar beet mitochondria. Ten and twelve C-to-U editing events were observed in the mRNAs of nad4L and orf25, respectively; the amino-acid sequence specified after editing is better-conserved in comparison with the homologues of other organisms. It is interesting to note that the translation initiation codon of nad4L is created by editing. The conservation of the nad4L-orf25 linkage was examined by PCR-amplification of the intergenic region. We obtained successful PCR products from five dicots (spinach, apple, snapdragon, petunia and tobacco) and two monocots (tulip and pineapple), but not in two poaceous plants, rice and maize. The intergenic region, when present, was found to be well-conserved in its sequence, suggesting a monophyletic origin of this linkage. Our result, together with previous reports of Arabidopsis and four poaceous species, favour the argument that the nad4L-orf25 linkage is conserved throughout angiosperms except in the Poaceae. Received: 12 April 1999 / Accepted: 22 June 1999     

A RESTORER OF FERTILITY-like PPR gene is required for 5'-end processing of the nad4 mRNA in mitochondria of Arabidopsis thaliana

Processing of 5'-ends is a frequently observed step during maturation of plant mitochondrial mRNAs. Up to now, very little is known about the biochemistry of this process and the proteins involved in the removal of 5' leader sequences. Based on natural genetic variation we have used linkage mapping and complementation studies to identify a nuclear gene required for the efficient generation of a 5'-end 228 nucleotides upstream of the mitochondrial nad4 gene encoding subunit 4 of the NADH dehydrogenase complex. This nuclear gene, At1g12700, that we designate RNA PROCESSING FACTOR 1 (RPF1), encodes a pentatricopeptide repeat (PPR) protein of the P-class containing canonical PPR-repeats. RPF1 belongs to a subgroup of PPR proteins, which includes the RESTORER OF FERTILITY (RF) gene products restoring cytoplasmic male sterility (CMS) in various plant species. CMS is a mitochondrially inherited trait caused by the expression of aberrant, chimeric genes, which has not been observed in the predominantly inbreeding species Arabidopsis thaliana. The here reported results are a further step towards the characterization of the plant mitochondrial RNA processing machinery and provide additional insights into the function of RF-like PPR proteins.     

Ribosomal protein S24 gene is mutated in Diamond-Blackfan anemia

Diamond-Blackfan anemia (DBA) is a rare congenital red-cell aplasia characterized by anemia, bone-marrow erythroblastopenia, and congenital anomalies and is associated with heterozygous mutations in the ribosomal protein (RP) S19 gene (RPS19) in approximately 25% of probands. We report identification of de novo nonsense and splice-site mutations in another RP, RPS24 (encoded by RPS24 [10q22-q23]) in approximately 2% of RPS19 mutation-negative probands. This finding strongly suggests that DBA is a disorder of ribosome synthesis and that mutations in other RP or associated genes that lead to disrupted ribosomal biogenesis and/or function may also cause DBA.     

Frequent mitochondrial gene rearrangements at the hymenopteran nad3-nad5 junction

Abstract We characterized the organization of mitochondrial genes from a diverse range of hymenopterans. Of the 21 taxa characterized, 12 had distinct, derived organizations. Some rearrangements were consistent with the duplication–random loss mechanism, while others were not. Local inversions were relatively common, i.e., rearrangements characterized by the movement of genes from one mitochondrial strand to the other, opposite or close to their ancestral position. This type of rearrangement is inconsistent with the duplication/random loss model of mitochondrial gene rearrangement. Instead, they are best explained by the operation of recombination. Taxa with derived organizations were restricted to a single, monophyletic group of wasps, the Apocrita, which comprise about 90% of all hymenopterans.     

Ribosomal protein S3 is stabilized by sumoylation

Human ribosomal protein S3 (rpS3) acts as a DNA repair endonuclease. The multiple functions of this protein are regulated by post-translational modifications including phosphorylation and methylation. Using a yeast-two hybrid screen, we identified small ubiquitin-related modifier-1 (SUMO-1) as a new interacting partner of rpS3. rpS3 interacted with SUMO-1 via the N- and C-terminal regions. We also observed sumoylation of rpS3 in Escherichia coli and mammalian cell systems. Furthermore, we discovered that one of three lysine residues, Lys18, Lys214, or Lys230, was sumoylated in rpS3. Interestingly, sumoylated rpS3 was resistant to proteolytic activity, indicating that SUMO-1 increased the stability of the rpS3 protein. We concluded that rpS3 is covalently modified by SUMO-1 and this post-translational modification regulates rpS3 function by increasing rpS3 protein stability.     

Trans splicing in Oenothera mitochondria: nad1 mRNAs are edited in exon and trans-splicing group II intron sequences.

The complete NADH dehydrogenase subunit 1 (nad1) ORF in Oenothera mitochondria is encoded by five exons. These exons are located in three distant locations of the mitochondrial genome. One genomic region encodes exon a, the second encodes exons b and c, and the third specifies exons d and e. Cis-splicing group II introns separate exons b and c and d and e, while trans-splicing reactions are required to link exons a and b and c and d. The two parts of the group II intron sequences involved in these trans-splicing events can be aligned in domain IV. Exon sequences and the maturase-related ORF in intron d/e are edited by numerous C to U alterations in the mRNA. Two RNA editing events in the trans-splicing intron a/b improve conservation of the secondary structure in the stem of domain VI. RNA editing in intron sequences may thus be required for the trans-splicing reaction.