Transcriptional and posttranscriptional regulation of maize mitochondrial gene expression

Comparisons among two fertile and three male-sterile mitochondrial genomes of maize

We have sequenced five distinct mitochondrial genomes in maize: two fertile cytotypes (NA and the previously reported NB) and three cytoplasmic-male-sterile cytotypes (CMS-C, CMS-S, and CMS-T). Their genome sizes range from 535,825 bp in CMS-T to 739,719 bp in CMS-C. Large duplications (0.5-120 kb) account for most of the size increases. Plastid DNA accounts for 2.3-4.6% of each mitochondrial genome. The genomes share a minimum set of 51 genes for 33 conserved proteins, three ribosomal RNAs, and 15 transfer RNAs. Numbers of duplicate genes and plastid-derived tRNAs vary among cytotypes. A high level of sequence conservation exists both within and outside of genes (1.65-7.04 substitutions/10 kb in pairwise comparisons). However, sequence losses and gains are common: integrated plastid and plasmid sequences, as well as noncoding "native" mitochondrial sequences, can be lost with no phenotypic consequence. The organization of the different maize mitochondrial genomes varies dramatically; even between the two fertile cytotypes, there are 16 rearrangements. Comparing the finished shotgun sequences of multiple mitochondrial genomes from the same species suggests which genes and open reading frames are potentially functional, including which chimeric ORFs are candidate genes for cytoplasmic male sterility. This method identified the known CMS-associated ORFs in CMS-S and CMS-T, but not in CMS-C.

Mapping of mitochondrial mRNA termini in Arabidopsis thaliana: t-elements contribute to 5' and 3' end formation

With CR–RT–PCR as primary approach we mapped the 5′ and 3′ transcript ends of all mitochondrial protein-coding genes in Arabidopsis thaliana. Almost all transcripts analyzed have single major 3′ termini, while multiple 5′ ends were found for several genes. Some of the identified 5′ ends map within promoter motifs suggesting these ends to be derived from transcription initiation while the majority of the 5' termini seems to be generated post-transcriptionally. Assignment of the extremities of 5′ leader RNAs revealed clear evidence for an endonucleolytic generation of the major cox1 and atp9 5′ mRNA ends. tRNA-like structures, so-called t-elements, are associated either with 5′ or with 3′ termini of several mRNAs. These secondary structures most likely act as cis-signals for endonucleolytic cleavages by RNase Z and/or RNase P. Since no conserved sequence motif is evident at post-transcriptionally derived ends, we suggest t-elements, stem–loops and probably complex higher order structures as cis-elements for processing. This analysis provides novel insights into 5′ and 3′ end formation of mRNAs. In addition, the complete transcript map is a substantial and important basis for future studies of gene expression in mitochondria of higher plants.

Gene expression in isolated plant mitochondria: high fidelity of transcription, splicing and editing of a transgene product in electroporated organelles

Mitochondrial gene expression was studied using an electrotransformation protocol to introduce foreign DNA into purified wheat mitochondria. Optimal conditions for DNA uptake and transient gene expression were determined. We show here that a DNA plasmid containing either a cognate or a non-cognate gene under the control of a plant mitochondrial promoter is incorporated into the organelle and faithfully recognized by the transcription machinery. Transcripts generated by a plasmid bearing the intron-containing cox II gene were correctly spliced. Moreover, the transcripts were edited at the expected target C residues. The expression and maturation process of the transgene is dependent on the integrity of functional elements such as the promotor or the presence of structural domains necessary for splicing. The mitochondrial transformation described in this report is an important tool to study the multiple steps involved in plant mitochondrial gene expression at conditions closer to those found in vivo.

Addition of non-genomically encoded nucleotides to the 3'-terminus of maize mitochondrial mRNAs: truncated rps12 mRNAs frequently terminate with CCA

The 3'-termini of maize mitochondrial RNAs were characterized by ligation of an anchor oligonucleotide, reverse transcription and amplification. DNA sequence analysis of cDNA clones for tRNA(Ser) and 18S rRNA confirmed the expected 3'-terminal nucleotides and demonstrated the accuracy and fidelity of the protocol. Analysis of cDNAs for rps12, cox2 and atp9 indicated that non-genomically encoded nucleotides were present at the 3'-terminus. rps12 cDNAs exhibited the highest degree of modification, with 94% of 35 cDNA clones analyzed containing one to four non-genomically encoded C or A residues; 83% of these cDNAs terminated with the trinucleotide CCA. DNA sequence and transcript mapping analyses demonstrated that four positions exhibited modified 3'-termini within a small region of the 3' flank of rps12 transcripts. These transcript termini represented low abundance, truncated forms of rps12 mRNAs which may be intermediates in degradation. cox2 mRNAs are also modified at a truncated position. Sixty percent of the cox2 cDNAs were modified with 1-5 nt that most frequently included A and C residues, but also included a few G and T residues. Non-genomically encoded nucleotides were detected in 27% of the atp9 cDNAs as a single C or A residue.

Genomic context influences the activity of maize mitochondrial cox2 promoters

Plant mitochondrial genomes are highly recombinogenic, with a variety of species-specific direct and inverted repeats leading to in vivo accumulation of multiple DNA forms. In maize, the cox2 gene, which encodes subunit II of cytochrome c oxidase, lies immediately downstream of a 0.7-kilobase direct repeat, which is present in two copies in the 570-kilobase master chromosome. Promoters for cox2 exist upstream of both of these copies, in regions we have termed A and B. Three region B promoters are active for cox2 transcription in the master chromosome, whereas two region A promoters are active for cox2 transcription after recombination across the direct repeats. We have measured the proportion of genomes carrying region A or B upstream of cox2 in maize seedlings and found a ratio of approximately 1:6. Promoter strength, based on run-on transcription assays, shows a ratio of 1:4 for region A to region B promoters. These data allowed us to predict the relative contributions of region A and B to mitochondrial transcript accumulation, based on a simple product of genome-form abundance and promoter strength. When promoter use was determined by using quantitative reverse transcriptase-PCR, however, we found that region A promoters were used at an unexpectedly high rate when upstream of cox2 and used less than expected when not upstream of cox2. Thus, the use of this set of promoters seems to respond to genomic context. These results suggest a role for intragenomic and intergenomic recombination in regulating plant mitochondrial gene expression.

In vitro characterization of the tobacco rpoB promoter reveals a core sequence motif conserved between phage-type plastid and plant mitochondrial promoters

We report here the in vitro characterization of PrpoB-345, the tobacco rpoB promoter recognized by NEP, the phage-type plastid RNA polymerase. Transcription extracts were prepared from mutant tobacco plants lacking PEP, the Escherichia coli-like plastid-encoded RNA polymerase. Systematic dissection of a approximately 1 kb fragment determined that the rpoB promoter is contained in a 15-nucleotide segment (-14 to +1) upstream of the transcription initiation site (+1). Point mutations at every nucleotide reduced transcription, except at the -5 position which was neutral. Critical for rpoB promoter function was a CRT-motif (CAT or CGT) at -8 to -6 (transcription <30%), defining it as the promoter core. The core CAT sequence is also present in the maize rpoB promoter, which is faithfully recognized by tobacco extracts. Alignment of NEP promoters identified a CATA or TATA (=YATA) sequence at the rpoB core position, also present in plant mitochondrial promoters. Furthermore, NEP and the phage T7 RNA polymerase exhibit similar sensitivity to inhibitors of transcription. These data indicate that the nuclear RpoZ gene, identified by sequence conservation with mitochondrial RNA polymerases, encodes the NEP catalytic subunit.

A conserved core element is functionally important for maize mitochondrial promoter activity in vitro

We have previously used a homologous in vitro transcription system to define functional elements of the maize mitochondrial atpA promoter. These elements comprise a central domain extending from -7 to +5, relative to the transcription start site, and an upstream domain of 1-3 bp that is purine rich and centered around positions -11 to -12. Within the central domain lies an essential 5 bp core element. These elements are conserved in many mitochondrial promoters, but their functionality has only been tested for atpA. In this study we have introduced mutations into the corresponding elements of two cox3 promoters and show that while the core element is essential for cox3 promoter activity, upstream element mutations have little or no effect. To define the minimal sequence required for in vitro promoter activity a series of short cloned oligonucleotides corresponding to the atpA promoter was used. While some activity was seen with a 14 bp sequence, full activity required 26 bp, suggesting that elements other than the core and upstream region can influence promoter strength. Another series of clones showed that altered spacing between the upstream and core elements of atpA had a significant effect on promoter activity. These results further define important features of the plant mitochondrial transcriptional machinery.

The steady-state level of mRNA from the Ogura cytoplasmic male sterility locus in Brassica cybrids is determined post-transcriptionally by its 3' region

We have investigated the control of the expression of three different configurations of the mitochondrial gene orf138, whose expression is correlated with Ogura cytoplasmic male-sterility in rapeseed cybrids. These configurations, termed Nco2.5/13S, Nco2.7/13F and Bam4.8/18S, specific to the 13S (sterile), 13F (fertile) and 18S (sterile) cybrids respectively, have the same 5' regions but different 3' regions. The orf138 transcript from Bam4.8/18S is 10-fold more abundant than the one from Nco2.5/13S, while no orf138 transcript from Nco2.7/13F accumulates. However, transcriptional activity measurements show that the rate of transcription is equivalent for the three configurations. These results strongly suggest that the steady-state level of mRNA from the orf138 locus is determined post-transcriptionally, most likely by its 3' region. To determine the role of these 3' regions, we have established an in vitro decay and processing system. In the presence of rapeseed mitochondrial lysate, synthetic RNAs corresponding to the 3' region of the Nco2.7/13F transcript are, as expected, less stable than RNAs corresponding to the 3' regions of the Nco2.5/13S and Bam4.8/18S transcripts. We have also observed in vitro processing of synthetic RNAs at the sites corresponding to the 3' ends of the natural mRNAs from Nco2.5/13S and Bam4.8/18S. Further analysis of the role of these 3' regions in in vitro RNA stability should help us to better understand post-transcriptional control in plant mitochondria.

3'-Inverted repeats in plant mitochondrial mRNAs are processing signals rather than transcription terminators

A number of mRNAs in plant mitochondria contain inverted repeats at their 3'-termini. These have been discussed as potential transcription terminators or, alternatively, as post-transcriptional processing and stability signals of longer precursor RNAs. In vitro transcription in a pea mitochondrial lysate now shows that transcription proceeds almost unimpeded through these inverted repeat structures. To investigate their potential function in mRNA processing, we developed an in vitro processing system from pea mitochondria. This in vitro system correctly processes synthetic precursor mRNAs containing the pea atp9 double stem-loop structure, yielding the same 3'-termini observed in vivo. Analysis of the in vitro-generated products and of the processivity of the reaction suggests exonucleolytic degradation up to the stem-loop. The inverted repeat structures found at the 3'-termini of mRNAs in plant mitochondria are thus recognized as processing and most likely also stabilizing signals in transcript maturation, but do not terminate transcription.

A promoter element active in run-off transcription controls the expression of two cistrons of nad and rps genes in Nicotiana sylvestris mitochondria

The expression of two mitochondrial gene clusters (orf87-nad3-nad1/A and orf87-nad3-rps12) was studied in Nicotiana sylvestris. 5' and 3' termini of transcripts were mapped by primer extension and nuclease S1 protection. Processing and transcription initiation sites were differentiated by in vitro phosphorylation and capping experiments. A transcription initiation site, present in both gene clusters, was found 213 nucleotides upstream of orf87. This promoter element matches the consensus motif for dicotyledonous mitochondrial promoters and initiates run-off transcription in a pea mitochondrial purified protein fraction. Processing sites were identified 5' of nad3, nad1/A and rps12 respectively. These results suggest that (i) the expression of the two cistrons is only controlled by one duplicated promoter element, and (ii) multiple processing events are required to produce monocistronic nad3, nad1/A and rps12 transcripts.

Correlation of nonanucleotide motifs with transcript initiation of 18S rRNA genes in mitochondria of pea, potato and Arabidopsis

Transcription initiation sites for the mitochondrial 18S rRNA genes in the dicot plants Arabidopsis thaliana, potato and pea were identified by a combination of in vitro capping, primer extension and S-1 analyses. These promoters contain a nonanucleotide motif and an AT-rich sequence similar to many mRNA and tRNA promoters in dicot mitochondria. In Arabidopsis and potato, active promoters are located within 120 nucleotides upstream of the 18S rRNA genes, as in Oenothera. The nucleotide sequence in the corresponding region in pea mitochondria is well conserved, but is not used as promoter in this plant. Instead a novel promoter sequence is used that lies several hundred nucleotides upstream. These results show that rRNAs can be transcribed from the same promoter types as mRNAs and tRNAs in plant mitochondria. However, the sequence features presently attributed to plant mitochondrial promoters-the conserved nonanucleotide and the upstream AT-rich box-do not allow to deduce the presence of an active promoter from genomic sequence data alone.

Identification of a 4.5S-like ribonucleoprotein in maize mitochondria

Escherichia coli has a ribonucleoprotein complex that is composed of a 114 nucleotide 4.5S RNA and a 48 kDa polypeptide (P48) that has been demonstrated to function in translation and in the secretion of periplasmic polypeptides. A small RNA of approximately 220 nucleotides has been identified in maize mitochondria that includes sequence identity with the highly conserved domain of the bacterial 4.5S RNA. The transcript is mitochondrially encoded and maps to a region upstream of the gene for ATP synthase subunit I. The mitochondrial 4.5S-like RNA has 15 nucleotides of sequence identity with the highly conserved region of the bacterial 4.5S RNA. Sucrose density gradient centrifugation of a maize mitochondrial lysate demonstrated that the 4.5S RNA is a component of a high molecular weight complex under native conditions, and could be disrupted by phenol. Anti-P48 immune serum immuno-precipitated a mitochondrial protein of approximately 48 kDa, and RNA gel blot analysis of the immunoprecipitation reaction indicated that the 4.5S-like RNA co-immuno-precipitated with the 48 kDa polypeptide. The mitochondrial 4.5S ribonucleoprotein complex could function in translation or protein targeting.

Mitochondrial transcription initiation: promoter structures and RNA polymerases

A diversity of promoter structures. It is evident that tremendous diversity exists between the modes of mitochondrial transcription initiation in the different eukaryotic kingdoms, at least in terms of promoter structures. Within vertebrates, a single promoter for each strand exists, which may be unidirectional or bidirectional. In fungi and plants, multiple promoters are found, and in each case, both the extent and the primary sequences of promoters are distinct. Promoter multiplicity in fungi, plants and trypanosomes reflects the larger genome size and scattering of genes relative to animals. However, the dual roles of certain promoters in transcription and replication, at least in yeast, raises the interesting question of how the relative amounts of RNA versus DNA synthesis are regulated, possibly via cis-elements downstream from the promoters. Mitochondrial RNA polymerases. With respect to mitochondrial RNA polymerases, characterization of human, mouse, Xenopus and yeast enzymes suggests a marked degree of conservation in their behavior and protein composition. In general, these systems consist of a relatively non-selective core enzyme, which itself is unable to recognize promoters, and at least one dissociable specificity factor, which confers selectivity to the core subunit. In most of these systems, components of the RNA polymerase have been shown to induce a conformational change in their respective promoters and have also been assigned the role of a primase in the replication of mtDNA. While studies of the yeast RNA polymerase have suggested it has both eubacterial (mtTFB) and bacteriophage (RPO41) origins, it is not yet clear whether these characteristics will be conserved in the mitochondrial RNA polymerases of all eukaryotes. mtTFA-mtTFB; conserved but dissimilar functions. With respect to transcription factors, mtTFA has been found in both vertebrates and yeast, and may be a ubiquitous protein in mitochondria. However, the divergence in non-HMG portions of the proteins, combined with differences in promoter structure, has apparently relegated mtTFA to alternative, or at least non-identical, physiological roles in vertebrates and fungi. The relative ease with which mtTFA can be purified (Fisher et al. 1991) suggests that, where present, it should be facile to detect. mtTFB may represent a eubacterial sigma factor adapted for interaction with the mitochondrial RNA polymerase.(ABSTRACT TRUNCATED AT 400 WORDS)

Selective DNA amplification regulates transcript levels in plant mitochondria

Most plant mitochondrial genomes exist as subgenomic-size fragments apparently due to recombination between repetitive sequences. This leads to the possibility that independently replicating subgenomic domains could result in mitochondrial gene copy number variation. We show, through Southern-blot analysis of both restricted and intact mtDNA, that there are gene-specific copy number differences in the monocot Zea mays. Comparison of two different maize genotypes, B37(N) and B37(T), a cytoplasmic male-sterile strain, reveal fewer gene copy number differences for B37(T) than for B37(N). In contrast to maize, significant gene copy number differences are not detected in the dicot Brassica hirta. We also demonstrate that mitochondrial transcriptional rates in both species are apparently dependent on gene copy number since relative rates determined by run-on analysis are proportional to relative gene copy numbers. Thus a direct relationship exists between plant mitochondrial gene copy number and transcriptional rate.

The rps3-rpl16-nad3-rps12 gene cluster in rice mitochondrial DNA is transcribed from alternative promoters

The two gene clusters rps3-rpl16 and nad3-rps12 are separated from each other in the mitochondrial genome and are expressed as the individual transcription units in many plants. In rice mitochondrial DNA (mtDNA), the four genes rps3, rpl16, nad3 and rps12 are located within a region of 6 kbp. Northern-blot analysis revealed that a large transcript (6.6 kb) hybridized to both the rps3-rpl16 and the nad3-rps12 gene clusters. Using RT-PCR, we amplified a fragment of anticipated size (790 bp) from two primers that corresponded to sequences in the coding regions of rpl16 and nad3, demonstrating that at least two of the four genes, namely rpl16 and nad3, were co-transcribed. These results together indicated that all four genes, namely, rps3, rpl16, nad3 and rps12, were co-transcribed in rice mitochondria. Transcription initiation sites were determined by an in vitro capping/ribonuclease protection assay and primer extension analysis. Two initiation sites were identified in the rps3-rpl16-nad3-rps12 gene cluster: one was located upstream of rps3 and the other was located between rpl16 and nad3. This evidence indicates that the rps3-rpl16-nad3-rps12 gene cluster is transcribed from two alternative promoters.

Architecture of the maize mitochondrial atp1 promoter as determined by linker-scanning and point mutagenesis

Plant mitochondrial promoters are poorly conserved but generally share a loose consensus sequence spanning approximately 17 nucleotides. Using a homologous in vitro transcription system, we have previously shown that an 11-nucleotide sequence within this region comprises at least part of the maize mitochondrial atp1 promoter (W. Rapp and D. Stern, EMBO J. 11:1065-1073, 1992). We have extended this finding by using a series of linker-scanning and point mutations to define the atp1 promoter in detail. Our results show that mutations at positions -12 to +5, relative to the major transcription start site, can decrease initiation rates to between < 10 and 40% of wild-type levels. Some mutations, scattered throughout this region, have lesser effects or no effect. Taken together, our data suggest a model in which the atp1 promoter consists of a central domain extending from -7 to +5 and an upstream domain of 1 to 3 bp that is centered around -11 to -12. Because many mutations within this promoter region are tolerated in vitro, the maize atp1 promoter is distinct from the highly conserved yeast mitochondrial promoters.

A DNA-polymerase-related reading frame (pol-r) in the mtDNA of Secale cereale

Mitochondrial (mt)DNA of Secale cereale contains an open reading frame (pol-r), the potential translation product of which shows significant homology to the type-B DNA polymerase encoded by the S1 plasmid of Zea mays; it contains the highly-conserved domains IIa to V of family B polymerases. The pol-r ORF is transcribed, as proven by RT-PCR, but the transcript is not edited. Upstream of the putative start codon a potential promoter motif was detected, fitting well into the postulated consensus sequence of the transcription initiation regions of Z. mays and Triticum aestivum. The pol-r ORF occurs in mtDNA of the fertile rye variety "Halo" and the cytoplasmic male-sterile (CMS) line "Pampa". Both ORFs are almost identical, apart from the 3' terminus; pol-r from Halo can code for 289 amino acids, pol-r from Pampa for 312 amino acids. Based on codon usage and the lack of editing, pol-r is considered to be a "young" gene, probably introduced in the mtDNA of rye by recombination with an mt plasmid.

Architecture of the maize mitochondrial atp1 promoter as determined by linker-scanning and point mutagenesis

Plant mitochondrial promoters are poorly conserved but generally share a loose consensus sequence spanning approximately 17 nucleotides. Using a homologous in vitro transcription system, we have previously shown that an 11-nucleotide sequence within this region comprises at least part of the maize mitochondrial atp1 promoter (W. Rapp and D. Stern, EMBO J. 11:1065-1073, 1992). We have extended this finding by using a series of linker-scanning and point mutations to define the atp1 promoter in detail. Our results show that mutations at positions -12 to +5, relative to the major transcription start site, can decrease initiation rates to between < 10 and 40% of wild-type levels. Some mutations, scattered throughout this region, have lesser effects or no effect. Taken together, our data suggest a model in which the atp1 promoter consists of a central domain extending from -7 to +5 and an upstream domain of 1 to 3 bp that is centered around -11 to -12. Because many mutations within this promoter region are tolerated in vitro, the maize atp1 promoter is distinct from the highly conserved yeast mitochondrial promoters.

Characterization of expression of a mitochondrial gene region associated with the Brassica "Polima" CMS: developmental influences

The mitochondrial genome of the Polima (pol) male-sterile cytoplasm of Brassica napus contains a chimeric 224-codon open reading frame (orf224) that is located upstream of, and co-transcribed with, the atp6 gene. The N-terminal coding region of orf224 is derived from a conventional mitochondrial gene, orfB, while the origin of the remainder of the sequence is unknown. We show that an apparently functional copy of orfB is present in the pol mitochondrial genome, indicating that the pol CMS is not caused by the absence of an intact, expressed orfB gene. The 5' termini of orf224/atp6 transcripts present in both sterile and fertility-restored (Rf) pol cytoplasm plants are shown to map to sequences resembling mitochondrial transcription-initiation sites, whereas the 5' termini of two transcripts specific to restored lines map to sequences which resemble neither one another nor mitochondrial promoter motifs. It is suggested that the complex orf224/atp6 transcript pattern of Rf plants is generated by a combination of multiple transcription initiation and processing events and that the nuclear restorer gene acts to specifically alter orf224/atp6 transcripts by affecting RNA processing. Northern analyses demonstrate that the effect of the restorer gene on orf224/atp6 transcripts is not tissue or developmental-stage specific. However, the expression of the atp6 region is developmentally regulated in pol plants, resulting in decreased levels of monocistronic atp6 transcripts in floral tissue relative to seedlings. It is suggested that this developmental regulation may be related to the absence of overt phenotypic effects of the CMS mutation in vegetative tissues.

Complex organization of the soybean mitochondrial genome: recombination repeats and multiple transcripts at the atpA loci

Identification of the soybean mitochondrial atpA open reading frame (atpA ORF) was based on sequence similarity with atpA genes in other plant mitochondria and partial protein sequencing. The atpA reading frame ends with four tandem UGA codons which overlap four tandem AUG codons initiating an unidentified reading frame, orf214. The atpA-orf214 region is found in multiple sequence contexts in soybean mitochondrial DNA (mtDNA), which can be attributed to the presence of two recombination repeats. A 1-kb repeat spans 600 nucleotides (nt) of atpA N-terminal coding region and 400 nt of upstream sequence. Its four configurations correspond to two full-length atpA-orf214 genes and two truncated pseudogenes. A 2-kb repeat lies 3 kb downstream from the 1-kb repeat. Restriction maps of cosmid clones suggest that a 10-kb segment containing both repeats is itself duplicated in the mt genome. With two recombination repeats present in a total of three copies per genome, soybean mtDNA is expected to consist of a complex population of subgenomic molecules. Transcription of the atpA loci was analysed by Northern blotting and S1 nuclease protection. The atpA genes express multiple transcripts with one major 3' end and heterogeneous 5' sequences extending several kb upstream of the atpA coding region. The atpA gene and orf214 are co-transcribed on all major transcripts. The pseudogenes do not express stable RNAs.

Transcription in maize mitochondria: effects of tissue and mitochondrial genotype

Mitochondrial run-on assays were used to determine transcriptional rates for nine B37(N) maize mitochondrial genes. Quantitation by radiographic imaging detected a 15-fold range in transcriptional rates; the order of apparent promoter strength was rps12 greater than rrn26 greater than atp6 greater than rrn18 greater than cox2 greater than atp alpha greater than atp9 greater than cox3 greater than cob. By probing single-stranded DNAs of both polarities with the run-on-products we showed that gene-specific antisense transcription did not occur. We also tested whether relative transcriptional rates were dependent on either the mitochondrial genotype or the tissue from which the mitochondria were isolated. Although tissue-specific differences in transcriptional rates were not detected, significant variation in apparent promoter strength for at least one gene, rps12, was dependent on the cytoplasmic genotype; rps12 had a five-fold reduced transcriptional rate in B37(T), the Texas male cytoplasmic strain of maize. Pulse-chase experiments suggested that differential transcript stability was not a major determinant of steady state mitochondrial RNA levels. These results indicate not only that promoter strength is an important component of the regulation of transcript levels in maize mitochondria, but also that the strength of a specific gene promoter can be dependent on the cytoplasmic genotype. Finally, the high transcriptional rate of both ribosomal RNA genes and the one mitochondrially encoded ribosomal protein gene studied suggests coordinate transcriptional regulation of both RNA and protein components of the mitochondrial ribosome.

Co-transcription of orf25 and coxIII in rice mitochondria

Southern hybridization analysis using homologous maize probes indicated that orf25 and coxIII are closely linked in the mitochondrial genome of rice (Oryza sativa) cultivar IR36. The two coding regions were found on the same 5.1 kb BamHI fragment, and this fragment was cloned, mapped and partially sequenced. Using probes for each gene derived from the rice clone, a 2.4 kb dicistronic mRNA transcript was found containing both orf25 and coxIII coding regions. Multiple 5' ends were identified by primer extension analysis and a double stem/loop structure was mapped to the 3' end. The orf25 coding region shares greater than 85% identity with orf25 sequences from maize, tobacco and wheat, suggesting that orf25 may code for a conserved protein product.

Chimeric mitochondrial genes expressed in the C male-sterile cytoplasm of maize

Aberrant recombinations involving the mitochondrial atp9, atp6 and coxII genes have created unique chimeric sequences in the C male-sterile cytoplasm (cms-C) of maize. An apparent consequence of the rearrangements is the interchanging of transcriptional and/or translational regulatory signals for these genes, and alterations in the reading frames encoding the atp6 and coxII genes in the C cytoplasm. Particularly unusual is the organization of the atp6 gene in cms-C mitochondria, designated atp6-C. The atp6-C sequence is a triple gene fusion product comprised of DNAs derived from atp9, atp6 and an open reading frame of unknown origin. Although there is no direct evidence indicating that these chimeric genes are responsible for the cytoplasmic male sterility (cms) trait, their novel arrangements and the strong correlation between these genes and the C type of male sterility suggest such a role.