Transcription of the gene coding for subunit 9 of ATP synthase in rice mitochondria

Transcript mapping and processing of mitochondrial RNA in the chlorophyte alga Prototheca wickerhamii

The detailed transcript map of the circular 55328 bp mitochondrial (mt) genome from the colourless chlorophycean alga Prototheca wickerhamii has been determined. On each half of this genome the genes are encoded only on one DNA strand, forming transcriptional units comprising variable numbers of genes. With the exception of four genes coding for ribosomal proteins, transcripts of the three rRNA genes and all protein-coding genes have been detected by both northern analysis and primer extension experiments. Polycistronic transcripts of protein coding and tRNA genes were verified by northern analyses, primer extension and RNAse mapping experiments. The 5' and 3' ends of different RNA species are often located in close proximity to putative stem-loop structures and some 5' termini of mRNAs coincide with the 3' end of tRNAs located immediately upstream. Transcript mapping in a putative promoter region revealed two different possible transcription initiation sites; no significant sequence homology to putative mt promoters from higher plants could be found. In addition, two out of three group I introns residing in the cox1 gene were found to be self-splicing in vitro under reaction conditions developed for related mt introns from a filamentous fungus. Mitochondrial gene expression of P. wickerhamii and of filamentous fungi has several features in common, such as intron splicing and the processing of longer polycistronic transcripts. The similarities in RNA maturation between higher-plant and P. wickerhamii mitochondria are less pronounced, since plants rarely use tRNAs as processing signals for their relatively short mitochondrial co-transcripts.

The mitochondrial atpA/atp9 co-transcript in wheat and triticale: RNA processing depends on the nuclear genotype

The gene region coding for subunits alpha and 9 of the mitochondrial ATP synthase exhibit an identical DNA sequence in wheat, rye, and the intergeneric hybrid triticale (xTriticosecale Wittmack). However, co-transcripts containing both genes show different sizes depending on the nuclear genotype. To investigate nuclear-mitochondrial interactions leading to this variation, we performed a comparative transcript analysis with various lines carrying defined nuclear and cytoplasmic genotypes. Northern analyses showed that all wheat lines investigated possess a single atpA/atp9 mRNA of 2.6kb, whereas in rye and five independent triticale lines an additional transcript of 2.35kb appeared. Primer-extension and RNase-protection analyses indicate that the co-transcripts of this gene have staggered 5' termini in some lines, whereas the 3' termini seem to be similar in wheat, rye, and triticale. Transcription is initiated at position -338/-339 upstream of the atpA gene in all lines investigated, giving rise to a 2.6-kb mRNA. In rye and triticale, staggered 5' termini were observed closer to the translational start. The DNA sequences upstream of these termini exhibit homology to plant mitochondrial-processing sites, therefore the proximal 5' ends are most probably generated by RNA processing. As the processing event occurs more frequently in triticale carrying the Triticum timopheevi cytoplasm, trans-acting factors from rye are likely to interact with other cytoplasmic factors resulting in the observed RNA modification. Most interestingly, the T. timopheevi cytoplasm inducing male sterility in alloplasmic wheat, fails to generate the CMS phenotype in triticale. The data support our hypothesis that nuclear factors affect mitochondrial gene expression and thus control sexual fertility in wheat and triticale.

The Tokumasu radish mitochondrial genome contains two complete atp9 reading frames

Two copies of the gene atp9, encoding subunit 9 of the mitochondrial F1F0-ATPase, have been cloned from the Tokumasu radish (Raphanus sativus L.) cytoplasm. The genomic DNA and the corresponding cDNA sequences of the coding regions were determined. Both alleles contain a 222 bp long and well conserved atp9 reading frame, coding for a 74 amino acid polypeptide. The Tokumasu atp9-1 gene may have a unique N-terminal extension of 11 amino acid residue relative to other plant atp9 genes. In comparison of cDNA and genomic sequences four RNA editing events were found in both atp9 genes. Northern experiments indicate different transcription patterns for the two genes.