Hans Kössel

RNA editing in plant mitochondria and chloroplasts

In the mitochondria and chloroplasts of higher plants there is an RNA editing activity responsible for specific C-to-U conversions and for a few U-to-C conversions leading to RNA sequences different from the corresponding DNA sequences. RNA editing is a post-transcriptional process which essentially affects the transcripts of protein coding genes, but has also been found to modify non-coding transcribed regions, structural RNAs and intron sequences. RNA editing is essential for correct gene expression: proteins translated from edited transcripts are different from the ones deduced from the genes sequences and usually present higher similarity to the corresponding non-plant homologues. Initiation and stop codons can also be created by RNA editing. RNA editing has also been shown to be required for the stabilization of the secondary structure of introns and tRNAs.The biochemistry of RNA editing in plant organelles is still largely unknown. In mitochondria, recent experiments indicate that RNA editing may be a deamination process. A plastid transformation technique showed to be a powerful tool for the study of RNA editing. The biochemistry as well as the evolutionary features of RNA editing in both organelles are compared in order to identify common as well as organelle-specific components.

RNA editing in tobacco chloroplasts leads to the formation of a translatable psbL mRNA by a C to U substitution within the initiation codon

The psbL gene which codes for a 38 amino acid peptide of photosystem II, together with the photosynthetic genes psbE and psbF, is contained in a conserved position of many species of higher plant plastomes. The alignment of the psbL nucleotide sequences from ten species shows strong conservation, which is indicative of a functional gene. The tobacco and spinach psbL genes have, however, an ACG codon instead of the initiator ATG codon observed in the homologous position of the other eight species. Evidence is presented that in tobacco chloroplasts a translatable psbL mRNA containing an AUG initiator codon is formed by a C to U editing of the ACG codon. This observation, following the previously reported editing of an rpl2 gene in maize chloroplasts, underlines a more widespread occurrence of this type of posttranscriptional mRNA modification and demonstrates its presence in a dicotyledon plant.

Mutations of cytochrome b6 in Chlamydomonas reinhardtii disclose the functional significance for a proline to leucine conversion by petB editing in maize and tobacco.

We have introduced a proline codon in place of a leucine codon at position 204 of the petB gene of Chlamydomonas reinhardtii. This gene modification mimics the presence of proline codons at the same position in the petB genes of maize and tobacco, which are subsequently edited to leucine codons at the RNA level. Following transformation, we observed no editing at this position in C. reinhardtii, independent of the type of proline codon we have used: the CCA codon, edited in maize, or a CCT codon. Strains carrying the introduced mutation were non phototrophic and displayed a block in photosynthetic electron transfer, consistent with a lack of cytochrome b6f activity. Thus the presence of a proline residue at position 204 in cytochrome b6 is detrimental to photosynthesis. We show that the mutant phenotype arose from a defective assembly of cytochrome b6f complexes and not from altered electron transfer properties in the assembled protein complex. Biochemical comparison of the proline-containing transformants with a cytochrome b6 mutant deficient in heme-attachment indicates that their primary defect is at the level of assembly of apocytochrome b6 with the bh heme, thereby preventing assembly of the whole cytochrome b6f complex.

Tissue- and stage-specific modulation of RNA editing of the psbF and psbL transcript from spinach plastids — a new regulatory mechanism?

The psbE operon of spinach chloroplasts, which includes the genes psbE, psbF, psbL and psbJ, encodes two RNA editing sites. One site corresponds to the initiation codon of the psbL transcript, as has been described earlier for the homologous transcript from tobacco, while at a second editing site, newly reported here, an internal phenylalanine codon of the psbF transcript is restored. Both these sites were investigated with respect to the extent of editing in spinach plastids at various developmental stages. The apparent existence of only completely edited transcripts in etioplasts and chloroplasts, indicates that light-induced processes are not acting as determinants in eliciting the editing process. Reduced editing is, however, observed in the psbF and psbL transcript from seeds and roots. This finding suggests that the RNA editing process is differentially down-regulated in leucoplasts and proplastids and that editing may, therefore, function as a regulatory device in lastid gene expression.

Internal editing of the maize chloroplast ndhA transcript restores codons for conserved amino acids.

The NADH dehydrogenase subunit A (ndhA) gene from maize chloroplasts encodes a highly conserved peptide, which at several positions could be restored to consensus sequences by potential C-to-U editing of the codons involved. This gene was, therefore, chosen for analysis of its mRNA sequence in the form of amplified cDNA. A comparison of this cDNA sequence with the plastome-encoded ndhA sequence reveals four C-to-U editing sites, thereby demonstrating as a novel finding that chloroplast editing can also affect internal mRNA positions. All the edited codons restore amino acids that are conserved in the ndhA-encoded peptides of other chloroplast species. Alignment with homologous mitochondrial NADH-ubiquinone reductase subunit 1 (nad1) sequences of plant and even nonplant species shows that two of the editing positions restore universally conserved amino acids and that one editing site is even shared with nad1 mRNA of plant mitochondria. No editing sites could be detected in the cDNA derived from transcripts of the maize chloroplast RNA polymerase alpha-subunit (rpoA) gene.

Nucleotide sequence of the maize chloroplast rpo B/C1/C2 operon : comparison between the derived protein primary structures from various organisms with respect to functional domains

SummaryThe genes (rpo B/C1/C2) coding for the β, β′, β″ subnits of maize (Zea mays) chloroplast RNA polymerase have been located on the plastome and their nucleotide sequences established. The operon is part of a large inversion with respect to the tobacco and spinach chloroplast genomes and is flanked by the genes trnC and rps2. Notable features of the nucleotide sequence are the loss of an intron in rpoC1, and an insertion of approximately 450 by in rpOC2 compared to the dicotyledons tobacco, spinach and liver-wort. The derived amino acid sequence of this additional monocotyledon specific sequence is characterized by acidic heptameric repeat units containing stretches of glutamic acid, tyrosines and leucines with regular spacing. Other structural motifs, such as a nucleotide binding domain in the β subunit and a zinc finger in the β′ subunit, are compared at the amino acid level throughout the RNA polymerase subunits with the enzymes from other organisms in order to identify functionally important conserved regions.

Structure and expression of the gene coding for the alpha-subunit of DNA-dependent RNA polymerase from the chloroplast genome of Zea mays.

The rpoA gene coding for the alpha-subunit of DNA-dependent RNA polymerase located on the DNA of Zea mays chloroplasts has been characterized with respect to its position on the chloroplast genome and its nucleotide sequence. The amino acid sequence derived for a 39 Kd polypeptide shows strong homology with sequences derived from the rpoA genes of other chloroplast species and with the amino acid sequence of the alpha-subunit from E. coli RNA polymerase. Transcripts of the rpoA gene were identified by Northern hybridization and characterized by S1 mapping using total RNA isolated from maize chloroplasts. Antibodies raised against a synthetic C-terminal heptapeptide show cross reactivity with a 39 Kd polypeptide contained in the stroma fraction of maize chloroplasts. It is concluded that the rpoA gene is a functional gene and that therefore, at least the alpha-subunit of plastidic RNA polymerase, is expressed in chloroplasts.

Determination of a nucleotide sequence in bacteriophage f1 DNA by primed synthesis with DNA polymerase.

Abstract A method is described for the determination of nucleotide sequences in DNA by using specific oligonucleotides as primers for copying specific regions by DNA polymerase. The method was applied to bacteriophage f1 DNA using the synthetic octanucleotide A-C-C-A-T-C-C-A as primer and a sequence (sequence A) of 81 nueleotides was determined. Synthesis was carried out in the presence of manganese and with one of the deoxyribotriphosphates (dCTP or dGTP) replaced by the corresponding ribotriphosphate so that mixed oligonucleotides were found which could be specifically split at the ribonucleotide residues by the appropriate ribonuclease or by alkali. The relative order of the digestion products was determined by fractionating the undigested oligonucleotides according to size on a two-dimensional system and digesting the isolated products. In the presence of rGTP the octanucleotide appeared to prime at a second site giving rise to a second sequence (B) besides sequence A. The complementary sequence to sequence A, which corresponds to the plus strand of f1 DNA and to the messenger RNA, contains five nonsense codons, four of which are in the same phase, and two possible initiation codons. It also contains a repetitive sequence which suggests its evolutionary origin by duplication.

Occurrence of silent RNA editing in chloroplasts: its species specificity and the influence of environmental and developmental conditions.

We have identified three new C-to-U RNA editing sites, one in atpF and two in atpA transcripts from tobacco chloroplasts. Two of them lead to amino acid substitutions to restore the conserved amino acid found in the corresponding genes of other plants. However, one editing site in the atpA transcript was found to take place partially at the third base of a serine codon (CUC to CUU), thus not leading to an amino acid substitution. This is the first report of silent editing in chloroplasts. The extent of silent editing depends on plastid stage and light conditions, while editing at another site (found 4 nt upstream from the silent editing site) takes place constitutively even in non-photosynthetic cultured cells and bleached white seedlings grown in the presence of spectinomycin and streptomycin. In pea and spinach, despite a conservation in sequence, no editing at the site corresponding to the silent site in tobacco was found. This observation suggests that the silent editing detected in this study is species-specific.

Purification and properties of peptidyl-tRNA hydrolase from Escherichia coli

Abstract The enzyme peptidyl-tRNA hydrolase has been purified from high-speed supernatant or from ribosomes of Escherichia coli. Starting from a 100 000 ×g supernatant the overall purification achieved by four steps was 1200-fold yielding a virtually homogeneous product as judged by gel electrophoresis. Partial purification was obtained when ribosomes were used as starting material. As judged by substrate specificity towards N-acetylaminoacyl-tRNAs, by the molecular weight determination and by the absorption properties on DEAE- and CM-cellulose, the enzymes derived from the 100 000 ×g supernatant and from ribosomes seem to be identical. The molecular weight of the basic protein is 13 000±2000, as determined by a calibrated Sephadex G-50 column. When ribosomal 30- and 50-S subunits derived from 70-S particles were tested separately, at least 4 times more hydrolytic activity was observed to be associated per mole of 30-S subunit as compared to the 50-S subunit. By treatment with 1 M NH4Cl the activity was released from 70-S particles and from the 30-S subunit. Under conditions where all 20 N-acetylaminoacyl-tRNAs from Escherichia coli including N-acetylmethionyl-tRNAMet are cleaved, resistance of N-acetylmethionyl-tRNAfMet was observed.