Electromyographic patterns in children with cerebral palsy: do they change after surgery?

The purpose of this study was to investigate the changes in electromyographic (EMG) patterns after multilevel surgical treatment in children with spastic cerebral palsy. Children with diplegia (n=18) and hemiplegia (n=16) aging from 6 to 16 years participated in the study. Twenty healthy children within the same age span are presented as reference. Gait analysis and surface electromyograms of seven major lower limb muscles were assessed before and 1-5 years after the multilevel surgery. The most frequent procedures were equinus correction, distal rectus femoris transfer, femoral derotation osteotomy and hamstrings lengthening. The results showed that the EMG pattern of the soleus, lateral gastrocnemius and tibialis anterior muscles became closer to normal after the surgery, while no differences were detected between diplegic and hemiplegic patients. Furthermore, a subgroup of 10 patients showed an increase in medial hamstrings activation during preswing that decreased postoperatively. These findings indicate that changes in EMG patterns should not be ruled out after surgical treatment, although the extent of these changes is limited compared to changes in the kinematics. Abnormal muscle activation before the operation can be related to a compensatory response in some patients and this can be manipulated after surgery.

Plant growth in elevated CO2 alters mitochondrial number and chloroplast fine structure

With increasing interest in the effects of elevated atmospheric CO(2) on plant growth and the global carbon balance, there is a need for greater understanding of how plants respond to variations in atmospheric partial pressure of CO(2). Our research shows that elevated CO(2) produces significant fine structural changes in major cellular organelles that appear to be an important component of the metabolic responses of plants to this global change. Nine species (representing seven plant families) in several experimental facilities with different CO(2)-dosing technologies were examined. Growth in elevated CO(2) increased numbers of mitochondria per unit cell area by 1.3-2.4 times the number in control plants grown in lower CO(2) and produced a statistically significant increase in the amount of chloroplast stroma (nonappressed) thylakoid membranes compared with those in lower CO(2) treatments. There was no observable change in size of the mitochondria. However, in contrast to the CO(2) effect on mitochondrial number, elevated CO(2) promoted a decrease in the rate of mass-based dark respiration. These changes may reflect a major shift in plant metabolism and energy balance that may help to explain enhanced plant productivity in response to elevated atmospheric CO(2) concentrations.

Assays for investigating RNA editing in plant mitochondria

In plant organelles transcripts are modified posttranscriptionally by RNA editing. This modification process changes almost every protein-coding RNA at specific cytidine and uridine positions. Therefore, mitochondrially encoded protein sequences differ from the genomically fixed information and show, after editing, a higher conservation. To investigate this unusual processing step in plant mitochondria, several assays have been developed. However, compared with the progress made in other RNA editing fields, knowledge about the factors involved in plant mitochondrial editing is limited. One reason for this is the lack of a reliable in vitro system for mitochondria. To reveal the biochemical nature of the RNA editing reaction in plant mitochondria, we developed an in vitro system by which we were able to show that cytidine is specifically modified to uridine by a deamination or transamination process. Here we describe the development of a pea in vitro system and discuss assays to follow the editing process.

Loss of RNA editing of rps1 sequences in Oenothera mitochondria

We have analysed a region downstream from the atp9 gene in Oenothera mitochondrial DNA which contains an open reading frame of 224 codons. This open reading frame, designated orf224, is co-transcribed with the atp9 gene. In wheat mitochondria, a homologous reading frame (orf174) has been described which is considerably shorter at the N-terminus compared to the putative Oenothera gene. The deduced polypeptides from both species show high similarity to the N-terminal third of ribosomal protein S1 of bacteria. Transcripts of orf174 are edited in wheat mitochondria whereas the similarly conserved cytidine positions in orf224 mRNAs of Oenothera are silent. On the other hand, atp9 sequences, which are located upstream on the same co-transcript, are fully edited. Because of this, we conclude that editing sites are selected independently for mRNA sections. Our results suggest that orf224 represents a transcribed pseudogene in Oenothera. The active gene for a functional ribosomal protein S1 for mitochondria is therefore expected to be present in the nucleus. A nuclear localization for this gene is likewise suggested for Arabidopsis due to the fact that rps1 sequences are absent from the mitochondrial genome.

Transfer of rps19 to the nucleus involves the gain of an RNP-binding motif which may functionally replace RPS13 in Arabidopsis mitochondria

The discovery of disrupted rps19 genes in Arabidopsis mitochondria prompted speculation about the transfer to the nuclear compartment. We here describe the functional gene transfer of rps19 into the nucleus of Arabidopsis. Molecular cloning and sequence analysis of rps19 show that the nuclear gene encodes a long N-terminal extension. Import studies of the precursor protein indicate that only a small part of this extension is cleaved off during import. The larger part of the extension, which shows high similarity to conserved RNA-binding domains of the RNP-CS type, became part of the S19 protein. In the Escherichia coli ribosome S19 forms an RNA-binding complex as heterodimer with S13. By using immuno-analysis and import studies we show that a eubacterial-like S13 protein is absent from Arabidopsis mitochondria, and is not substituted by either a chloroplastic or a cytosolic homologue of this ribosomal protein. We therefore propose that either a highly diverged or missing RPS13 has been functionally replaced by an RNP domain that most likely derived from a glycine-rich RNA-binding protein. These results represent the first case of a functional replacement of a ribosomal protein by a common RNA-binding domain and offer a new view on the flexibility of biological systems in using well-adapted functional domains for different jobs.

Transfer of rps10 from the mitochondrion to the nucleus in Arabidopsis thaliana: evidence for RNA-mediated transfer and exon shuffling at the integration site

Rps10, a gene coding for ribosomal protein S10 of Arabidopsis mitochondria has been transferred to the nuclear compartment, while in pea and potato the active rps10 is mitochondrially located. The nuclear rps10 gene contains an intron at the junction of the target signal sequence and the mitochondrial-derived sequence, indicating that exon shuffling may have been involved in the addition of the transit peptide signal. Sequence comparison of Arabidopsis rps10 to the plant mitochondrial counterparts shows that the edited version is present in the nucleus of Arabidopsis. This finding corroborates RNA as an intermediate of a functional gene transfer between mitochondria and the nucleus. In vitro-translated RPS10 protein is efficiently imported into potato mitochondria and a presequence of about 7 kDa is removed resulting in a mature protein that is larger compared to organellar and bacterial RPS10 proteins.

Evidence for a site-specific cytidine deamination reaction involved in C to U RNA editing of plant mitochondria

Transcripts of higher plant mitochondria are modified post-transcriptionally by RNA editing. To distinguish between the mechanisms by which the cytidine to uridine transition could occur a combined transcription/RNA editing assay and an in vitro RNA editing system were investigated. Mitochondria isolated from etiolated pea seedlings and potato tubers were supplied with [alpha-32P]CTP to radiolabel the mitochondrial run-on transcripts. High molecular weight run-on transcripts were isolated and hydrolyzed, and nucleotide identities were analyzed by one- and two-dimensional thin layer chromatography. The amount of label comigrating with UMP nucleotides increases with extended incubation times. Analogous products were obtained by incubation of [alpha-32P]CTP or [5-3H]CTP radiolabeled in vitro transcripts with a mitochondrial lysate from pea mitochondria. 5-3H label of the cytosine base was detected in the UMP spot after incubation of in vitro transcripts with mitochondrial lysate. These results are consistent with a deamination reaction involved in this post-transcriptional C to U modification process. To prove that cytidines are deaminated specifically in vitro transcripts were reisolated after incubation and analyzed by reverse transcription-polymerase chain reaction. Sequence analysis clearly shows that only cytidines at editing sites are edited while residual cytidines are not modified and suggests that site-specific factors are involved in RNA editing of plant mitochondria.

Oenothera mitochondrial orf454, a gene involved in cytochrome c biogenesis corresponds to orf169 and orf322 of Marchantia

We have characterized a mitochondrial gene in Oenothera, designated orf454, capable of encoding a component of the cytochrome c biogenesis system. This open reading frame is interrupted by an intron of 941 nucleotides showing high similarity to a group II intron residing in the rpl2 gene. RNA editing, which is observed at 18 cytidine positions within the orf454 reading frame, improves the similarity to protein-coding sequences in bacteria and higher plants and removes the last 16 amino acids. orf454 also shows high sequence similarity to two overlapping reading frames (orf169 and orf322) of Marchantia mitochondria. These ORFs belong to an operon-like cluster of genes in the liverwort that is not conserved in Oenothera mitochondria. However, in bacteria these reading frames are organized like the Marchantia gene cluster. It has been shown by genetical analysis in Rhodobacter capsulatus that these genes are essential for cytochrome c biogenesis. Genes of bacterial operons-ccl1 in Rhodobacter and yejR and nrfE in Escherichia coli - show high sequence similarity to the mitochondrial reading frames orf577 and orf454 of Oenothera. orf454, which we describe here, is homologous to the C-terminal region of these bacterial genes, while the previously described orf577 is homologous to the N-terminal region.

Potato mitochondrial manganese superoxide dismutase is an RNA-binding protein

An RNA-binding protein present in potato mitochondrial lysates was purified and identified as manganese-containing superoxide dismutase (MnSOD). Using a gel mobility shift assay we found that proteins from mitochondrial lysates bind with high affinity to in vitro transcripts of mitochondrial orf206, encoding a subunit of the ABC-type heme transporter. By ammonium sulfate fractionation and two subsequent chromatographic steps on MonoQ columns we purified a 28 kDa protein to apparent homogeneity. Protein sequencing identified the purified polypeptide as manganese-containing superoxide dismutase, which is a specific enzymatic scavenger of superoxides in mitochondria. Using gel mobility shift and competition assays, we show that RNA-binding of MnSOD of potato is not influenced by 400 mM KCl or heparin and is specific to heteropolymeric RNAs. The labeled mitochondrial transcript could be competed with low amounts of unlabeled transcript while binding was stable to competition with large amounts of tRNA or high concentrations of NADH and NADPH. The purified MnSOD of potato mitochondria was UV-cross-linked to the mitochondrial transcript. The Mn- and Fe-containing SODs from Escherichia coli showed no binding to the RNA by either gel mobility shift or UV-cross-linking. Enzyme activity assays revealed that binding of RNA to the mitochondrial MnSOD does not significantly influence enzyme activity. This indicates that the RNA-binding feature of MnSOD of potato mitochondria is probably not involved in modulating SOD enzyme activity and suggests a function different from superoxide degradation as ist biological role.

orf250 encodes a second subunit of an ABC-type heme transporter in Oenothera mitochondria

A highly transcribed region in Oenothera mitochondria codes for an open reading frame comprising 250 condons (orf250). This open reading frame shows high sequence similarity to the helC gene of Rhodobacter capsulatus which encodes a subunit of a proposed ABC-type heme transporter. Transcripts of orf250 are edited by cytidine to uridine transitions at 29 sites, altering 10% of all encoded amino acids. Genes homologous to helC have also been found in the bacteria Bradyrhizobium japonicum and Escherichia coli, and are conserved in mitochondria of Marchantia polymorpha, Daucus carota, and Arabidopsis thaliana. In bacteria these genes belong to operons that are involved in the biogenesis of c-type cytochromes. The bacterial gene organization is partly conserved in Marchantia, but altered in the mitochondrial genome of Oenothera.

RNA editing in higher plant mitochondria: analysis of biochemistry and specificity

RNA editing alters genomically encoded cytidines to uridines posttranscriptionally in higher plant mitochondria. Most of these editing events occur in translated regions and consequently alter the amino acid sequence. In Oenothera berteriana more than 500 editing sites have been detected and the total number of editing sites exceeds 1000 sites in this mitochondrial genome. To identify the components involved in this process we investigated the factors determining the specificity of RNA editing and the apparent conversion of cytidine to uridine residues. The possible biochemical reactions responsible for RNA editing in plant mitochondria are de- or transamination, base substitution and nucleotide replacement. In order to discriminate between these different biochemical mechanisms we followed the fate of the sugar-phosphate backbone by analysing radiolabeled nucleotides after incorporation into high molecular mass RNA. Plant mitochondria were supplied with [alpha-32P]CTP to radiolabel CMP residues in newly synthesized transcripts. Radiolabeled mtRNA was extracted and digested with nuclease P1 to hydrolyse the RNA to monophosphates. The resulting monophosphates were analysed on one- and two-dimensional TLC systems to separate pC from pU. Radiolabeled pU was detected in increasing quantities during the course of incubation. These results suggest that RNA editing in plant mitochondria involves either a deamination or a transglycosylation reaction. The editing product was identified as uridine and not as a hypermodified nucleotide which is recognized as uridine. Similar results have been obtained by incubating in vitro transcribed mRNAs with mitochondrial lysates indicating that RNA editing and transcription is not directly linked in plant mitochondria.(ABSTRACT TRUNCATED AT 250 WORDS)

Physical mapping of the mitochondrial genome of Arabidopsis thaliana by cosmid and YAC clones

As part of the worldwide efforts at molecular analysis of Arabidopsis thaliana as a model plant the complete structure of the mitochondrial genome has been determined. The mitochondrial DNA molecules were mapped by restriction fragment analysis of more than 300 cosmid clones and purified mitochondrial DNA. The entire genome of 372 kb is contained in three different configurations of circular molecules and is split into two additional subgenomic molecules of 234 kb and 138 kb, respectively. These arrangements result from recombinations of the two sets of repeats present in combinations of inverted and/or direct orientation. Alignment of YAC clones confirms the in vivo presence of continuous DNA molecules of more than 300 kb in A. thaliana mitochondria. The presence of this comparatively large mitochondrial genome in a plant with one of the smallest nuclear genomes shows that different size constraints act upon the different genomes in plant cells.

The highly edited orf206 in Oenothera mitochondria may encode a component of a heme transporter involved in cytochrome c biogenesis

A highly transcribed region in Oenothera mitochondria codes for a reading frame (orf206) which shows high homology to the Marchantia encoded mitochondrial open reading frame orf277 and is also conserved in the mitochondrial genomes of Arabidopsis thaliana and Daucus carota. Transcripts of orf206 are modified by cytidine to uridine changes in 46 positions by RNA editing, affecting 30% of all cytidines and 15% of the total encoded amino acids. This ORF is cotranscribed with an upstream reading frame and with the downstream rps 14 gene. The orf206 deduced protein shows high similarity to polypeptides which are proposed to be part of an ABC-type heme transporter involved in cytochrome c biogenesis in Bradyrhizobium and Rhodobacter.

Rps3 and rpl16 genes do not overlap in Oenothera mitochondria: GTG as a potential translation initiation codon in plant mitochondria?

Characterization of the Oenothera mitochondrial ribosomal gene cluster rps19-rps3-rpl16 shows the two genes rps3 and rpl16 to be separated by 9 nucleotides. The first codon of rpl16 is a GTG codon for valine and the only potential translational start. This GTG codon is conserved at the same position in maize, Petunia and Marchantia mitochondria, while sequences diverge upstream. These observations suggest that GTG at least at this position may act as translation initiation codon in plant mitochondria. Analysis of RNA editing suggests both genes to code for functional ribosomal proteins in Oenothera mitochondria. A duplication/recombination event at a decanucleotide in the intron of rps3 created a pseudogene missing part of the intron and the 3' exon.

Ribosomal protein gene rpl5 is cotranscribed with the nad3 gene in Oenothera mitochondria

The rpl5 ribosomal protein gene was identified in the mitochondrial genome of the higher plant Oenothera berteriana. The gene is present in a unique genomic location upstream of the gene encoding subunit 3 of the NADH dehydrogenase (nad3). Both genes are cotranscribed, and the mRNA is modified at several cytidine residues by RNA editing. Analysis of the editing profiles of both genes by direct cDNA analysis and polymerase chain reaction (PCR) revealed that not all transcripts are fully edited at all sites. Eight of the nine C to U conversions in the rpl5 reading frame are non-silent and change the deduced amino acid sequence. The genes of the prokaryotic-like cistron that includes the rpsl9, rps3, rpl16, rpl5, and rpsl4 genes, which is at least partially conserved in the mitochondrial genomes of other higher and lower plants, are dispersed in the Oenothera mitochondrial genome.

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 mitochondria.

The mitochondrial genome on its way to the nucleus: different stages of gene transfer in higher plants

The vast majority of mitochondrial proteins are in all eukaryotes encoded in the nuclear genomes by genes which have been transferred from the original endosymbiont. DNA as well as RNA was and is exchanged between organelles. A functionally successful information transfer, however, requires complex structural and regulatory alterations of the concerned gene. The recently identified variations of the information content in mitochondrial genomes of different plant species represent different stages of the transfer process. These evolutionary intermediates allow a definition of requirements and chances of successful gene transfers.

A plant mitochondrial gene encodes a protein involved in cytochrome c biogenesis

Analysis of a transcribed region in the mitochondrial genome of Oenothera revealed an open reading frame (ORF) of 577 codons (orf577) that is also conserved in carrot, here encoding a protein of 579 amino acids (orf579). RNA editing alters the mRNA sequence of orf577 in Oenothera with 46 C to U transitions, many of which improve sequence similarity with the homologous Marchantia gene orf509. The deduced polypeptides show significant similarity with the ccl1-encoded protein involved in cytochrome c biogenesis in the photosynthetic bacterium Rhodobacter capsulatus. A highly conserved domain is also found in plastid ORFs, suggesting that these bacterial, chloroplast and mitochondrial genes encode polypeptides with analogous functions in assembly and maturation of cytochromes c.

RNA editing gives a new meaning to the genetic information in mitochondria and chloroplasts

RNA editing in plant mitochondria and chloroplasts alters mRNA sequences to code for different proteins than the DNA. Most of these C-to-U transitions occur in open reading frames, but a few are observed in intron sequences. Influences of the nuclear genome on editing patterns suggest that cytoplasmic factors participate in this process.

An adenine nucleotide translocator gene from Arabidopsis thaliana

The sequence of an adenine nucleotide translocator (ANT) gene of Arabidopsis contains three introns, the first of which is located upstream of the assumed initiation codon. The presequence characteristic for plant ANTs is processed also in Arabidopsis as suggested by Western blot analysis, most likely at the conserved cleavage site.

The mitochondrial gene encoding ribosomal protein S12 has been translocated to the nuclear genome in Oenothera

The Oenothera mitochondrial genome contains only a gene fragment for ribosomal protein S12 (rps12), while other plants encode a functional gene in the mitochondrion. The complete Oenothera rps12 gene is located in the nucleus. The transit sequence necessary to target this protein to the mitochondrion is encoded by a 5'-extension of the open reading frame. Comparison of the amino acid sequence encoded by the nuclear gene with the polypeptides encoded by edited mitochondrial cDNA and genomic sequences of other plants suggests that gene transfer between mitochondrion and nucleus started from edited mitochondrial RNA molecules. Mechanisms and requirements of gene transfer and activation are discussed.

Regenerating good sense: RNA editing and trans splicing in plant mitochondria

The protein products of plant mitochondrial genes cannot be predicted accurately from genomic sequences, since RNA editing modifies almost all mRNA sequences post-transcriptionally. Furthermore, RNA editing alters leader, trailer and intron sequences, and may be required for processing of these sequences. For several plant mitochondrial transcripts, processing includes trans splicing, which connects exons scattered throughout the genome. The mature transcripts are assembled via split group II intron sequences.

RNA editing makes mistakes in plant mitochondria: editing loses sense in transcripts of a rps19 pseudogene and in creating stop codons in coxI and rps3 mRNAs of Oenothera

An intact gene for the ribosomal protein S19 (rps19) is absent from Oenothera mitochondria. The conserved rps19 reading frame found in the mitochondrial genome is interrupted by a termination codon. This rps19 pseudogene is cotranscribed with the downstream rps3 gene and is edited on both sides of the translational stop. Editing, however, changes the amino acid sequence at positions that were well conserved before editing. Other strange editings create translational stops in open reading frames coding for functional proteins. In coxI and rps3 mRNAs CGA codons are edited to UGA stop codons only five and three codons, respectively, downstream to the initiation codon. These aberrant editings in essential open reading frames and in the rps19 pseudogene appear to have been shifted to these positions from other editing sites. These observations suggest a requirement for a continuous evolutionary constraint on the editing specificities in plant mitochondria.

RNA editing in ATPase subunit 6 mRNAs in Oenothera mitochondria. A new termination codon shortens the reading frame by 35 amino acids

The open reading frame encoding ATPase subunit 6 in Oenothera mitochondria is edited at 21 positions in all cDNA clones investigated. Only one of these events is silent, all others improve similarity between the homologous polypeptides of other species. The introduction of a new UAA termination codon shortens the polypeptide by 35 amino acids to a carboxy terminus conserved in other species. In one of the cDNA clones, an additional editing event was observed resulting in a premature UAA termination codon in the amino terminal region.

Cryptosporidium sp. in stool specimens from diarrhoeic and asymptomatic individuals in the Magdeburg area (East Germany)

Unselected stool specimens from a total of 2,944 individuals with diarrhoea including 1,172 children under 14 years of age were investigated for Cryptosporidium oocysts in the Magdeburg area from 1987 to 1988, 43 (1.46%) were found positive. Three of these were additionally infected with bacterial pathogens (Campylobacter species). In all cases the symptoms of diarrhoea ceased spontaneously after an average of 8 days. The incidence was highest among children and infants under 6 years of age (2.50%). No cryptosporidia were found in stool specimens of 570 healthy individuals of all age groups. Cysts of Giardia sp. were detected more frequently in healthy than in diarrhoeic individuals (3.3% and 2.0%, respectively). The postulation to search for cryptosporidia in all cases of diarrhoea lasting longer than two days is inferred from these results.

Trans splicing integrates an exon of 22 nucleotides into the nad5 mRNA in higher plant mitochondria

The genes coding for NADH dehydrogenase subunit 5 (nad5) in mitochondria of the higher plants Oenothera and Arabidopsis are split into five exons that are located in three distant genomic regions. These encode exons a + b, c and d + e, respectively. Maturation of the mRNAs requires two trans splicing events to integrate exon c of only 22 nucleotides. Both trans splicing reactions involve mitochondrial group II intron sequences that allow base pairings in the interrupted domain IV, demonstrating the flexibility of intron structures. The observation of fragmented intron sequences in plant mitochondria suggests that trans splicing is more widespread than previously assumed. RNA editing by C to U alterations in both Oenothera and Arabidopsis open reading frames improves the evolutionary conservation of the encoded polypeptides. Three C to U RNA editing events were observed in intron sequences.

Distribution of RNA editing sites in Oenothera mitochondrial mRNAs and rRNAs

To investigate whether RNA editing in plant mitochondria modifies structural RNAs as well as protein-coding RNAs we compared the genomic-encoded information with the respective transcripts of several genes in Oenothera. The genes analysed are the 5S, 18S and 26 S rRNAs, the alpha-subunit of ATPase (atpA), cytochrome b (cytb), orfB, which is located upstream of cytochrome oxidase subunit III, and the respective leader, trailer and spacer sequences. All open reading frames were found to be edited to some degree. The atpA coding region has the least edited mRNA in Oenothera mitochondria, with only four nucleotides altered in the 1533 nucleotide open reading frame. From this analysis we conclude that frequent RNA editing is indicative of functional protein coding regions in plant mitochondria. The extensive editing in orfB, for example, suggests that this orf codes for a mitochondrial protein. No RNA editing event was found in the 5S rRNA or in the 1824 nucleotides analysed of the 18S rRNA, but two nucleotides were found to be altered in the 1970 nucleotides compared for the 26S rRNA. One nucleotide alteration has changed C to U, the other in reverse U to C. However, only one of five cDNA clones covering this region shows the modifications, similar to many silent editing events in open reading frames. RNA editing in the structural RNAs thus does not seem to be essential for their function in the mitochondrial ribosome.

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.

Species-specific RNA editing patterns in the mitochondrial rps13 transcripts of Oenothera and Daucus

Transcripts from the rps13 locus, which encodes ribosomal protein S13, in Oenothera and Daucus mitochondria are edited by several cytidine to uridine transitions in both plants. Analysis of individual cDNA clones and polymerase chain reaction (PCR)-amplified cDNA from the total mitochondrial mRNA population shows different editing patterns in the two species. Although the same genomic triplet is conserved, nucleotides altered in the mRNA of one species are not necessarily edited in the other. Individual editing sites appear to be modified to varying degrees in the mRNA populations in both plant species, indicating that completely edited transcripts constitute only a minor fraction of the rps13 mRNA molecules.

RNA editing of ATPase subunit 9 transcripts in Oenothera mitochondria

The mRNA for subunit 9 of the ATPase (atp9) in the higher plant Oenothera is edited in four nucleotide positions. Three events alter genomic serine and proline codons to triplets specifying leucine. A UGA termination codon is introduced into the reading frame by modification of a CGA arginine codon. This modification shortens the polypeptide by four amino acids. Direct sequencing of PCR amplified cDNA from the total mitochondrial mRNA population gives no indication of partially edited transcripts suggesting a rapid and efficient modification of atp9 transcripts in Oenothera mitochondria.

RNA editing in the cytochrome b locus of the higher plant Oenothera berteriana includes a U-to-C transition

RNA editing in the cytochrome b locus of Oenothera berteriana mitochondria modified a number of cytidine nucleotides to uridines, mostly altering codon identities. One nucleotide alteration involved a reverse modification changing a genomic thymidine to a cytidine in the cDNA sequence. The enzymatic editing activity in higher-plant mitochondria thus appears to be able to catalyze the interconversion of pyrimidines in both directions at specific nucleotides in the mRNA template.

Genes for tRNA(Gly), tRNA(His), tRNA(Lys), tRNA(Phe), tRNA(Ser) and tRNA(Tyr) are encoded in Oenothera mitochondrial DNA

The genes coding for tRNA(Gly), tRNA(His), tRNA(Lys), tRNA(Phe), tRNA(Ser) and tRNA(Tyr) have been identified in Oenothera mitochondrial DNA. Sequence analysis of these genes and their surrounding sequences are presented and compared with other known tRNA genes from plant mitochondria. All six deduced tRNA sequences can be folded into the classical cloverleaf structure model. Only the tRNA(His) gene shows high homology with the corresponding chloroplast gene and thus appears to be derived from a transfer event of chloroplast sequences into the mitochondrial genome. The sequences surrounding this gene, however, show little similarity with the chloroplast genome. The other five deduced tRNAs display a much lower similarity with their chloroplast counterparts and thus appear to be genuine mitochondrial tRNAs. These tRNAs are highly conserved between monocots and dicots with maximally three nucleotides differing between the Oenothera sequences and their wheat homologues. A purine-rich sequence is found upstream of each tRNA gene in Oenothera, similar to wheat mitochondrial tRNA genes, that could be involved in transcription signalling.

In vitro processing of mitochondrial and plastid derived tRNA precursors in a plant mitochondrial extract

A lysate of purified mitochondria of the higher plant Oenothera processes in vitro synthesized tRNA precursors to the mature tRNA size. In vitro synthesized transcripts containing genuine plant mitochondrial tRNAs and analogous RNAs from mitochondrial loci with plastid derived tRNA sequences are accurately processed by an RNAase P-like activity to yield the mature 5'-terminus. A four nucleotide deletion in the anticodon stem-loop structure, however, prevents processing. The results show that in vitro transcripts containing tRNAs from sequence fragments of plastid origin integrated in plant mitochondrial genomes can be processed correctly in plant mitochondria, if tRNA sequences and structures are intact.

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.

Transcripts of the NADH-dehydrogenase subunit 3 gene are differentially edited in Oenothera mitochondria

A number of cytosines are altered to be recognized as uridines in transcripts of the nad3 locus in mitochondria of the higher plant Oenothera. Such nucleotide modifications can be found at 16 different sites within the nad3 coding region. Most of these alterations in the mRNA sequence change codon identities to specify amino acids better conserved in evolution. Individual cDNA clones differ in their degree of editing at five nucleotide positions, three of which are silent, while two lead to codon alterations specifying different amino acids. None of the cDNA clones analysed is maximally edited at all possible sites, suggesting slow processing or lowered stringency of editing at these nucleotides. Differentially edited transcripts could be editing intermediates or could code for differing polypeptides. Two edited nucleotides in an open reading frame located upstream of nad3 change two amino acids in the deduced polypeptide. Part of the well-conserved ribosomal protein gene rps12 also encoded downstream of nad3 in other plants, is lost in Oenothera mitochondria by recombination events. The functional rps12 protein must be imported from the cytoplasm since the deleted sequences of this gene are not found in the Oenothera mitochondrial genome. The pseudogene sequence is not edited at any nucleotide position.

RNA editing in plant mitochondria

Comparative sequence analysis of genomic and complementary DNA clones from several mitochondrial genes in the higher plant Oenothera revealed nucleotide sequence divergences between the genomic and the messenger RNA-derived sequences. These sequence alterations could be most easily explained by specific post-transcriptional nucleotide modifications. Most of the nucleotide exchanges in coding regions lead to altered codons in the mRNA that specify amino acids better conserved in evolution than those encoded by the genomic DNA. Several instances show that the genomic arginine codon CGG is edited in the mRNA to the tryptophan codon TGG in amino acid positions that are highly conserved as tryptophan in the homologous proteins of other species. This editing suggests that the standard genetic code is used in plant mitochondria and resolves the frequent coincidence of CGG codons and tryptophan in different plant species. The apparently frequent and non-species-specific equivalency of CGG and TGG codons in particular suggests that RNA editing is a common feature of all higher plant mitochondria.

[Wild domestic pigeons--a public health problem of increasing significance in East Germany]

In many cities of the GDR the number of wild house pigeons is increasing. Because of their distribution, noxious effects and hygienic importance they are considered by law as health pests. Therefore, their populations have to be regulated in such a way to minimize the noxious effects caused by them. The State Hygiene inspectorate is responsible for organization and surveillance of health pest control. At present in the GDR two procedures are allowed applying chemical substance for pest control by specialists. A catching procedure, applicable everywhere, is well proving a success. By restauration of old buildings and closing of lofts in new ones it is possible to take prophylactic measures against the increasing number of pigeons. The municipal administration should coordinate the possible measures in the respective territory.

Conserved sequence elements at putative processing sites in plant mitochondria

About 50 nucleotides are conserved in two distinct sequence elements at the 5' termini of abundant short transcripts from plant mitochondrial genes with complex transcription patterns. These sequence motifs are found in both structural RNA and protein-coding precursor transcripts, for example, upstream of the mature 26S rRNA and the shortest transcript of the ATPase subunit 9 genes in different plant species. The high degree of sequence similarity in these plant mitochondrial loci suggests a common functional significance in 5' processing site determination and selection.