Sequence and transcription analysis of the Petunia mitochondrial gene for the ATP synthase proteolipid subunit

Cytoplasmic male sterility (CMS) in Lolium perenne L. 2. The mitochondrial genome of a CMS line is rearranged and contains a chimaeric atp 9 gene

The most striking difference between the mtDNAs of the fertile L. perenne line LPSB21 and the male-sterile line CMS9B290, is the presence in the former and the absence in the latter of a 5.6-kb HindIII fragment. This difference between fertile and sterile lines was the starting point for a detailed molecular analysis of the mitochondrial genome in the region spanning the 5.6-kb HindIII fragment in fertile L. perenne and the corresponding region in CMS9B290. Restriction mapping and Southern-blot analyses indicated that rearrangement of the mitochondrial genome consistent with a deletion/insertion event had occurred in the sterile line. Nucleotide-sequence analysis of the rearranged region in CMS9B290 revealed the presence of (1) a novel chimaeric gene, orf-C9, comprising the first six codons of atp9 fused to a further 118 codons of an unknown sequence and (2) a truncated version of an open reading frame, orf-L, originally identified in LPSB21 mtDNA. Northern-blot analysis confirmed the absence of orf-L transcripts and the presence of orf-C9 transcripts in the mtRNA of CMS9B290.

Sorghum mitochondrial orf25 and a related chimeric configuration of a male-sterile cytoplasm

We describe fundamental characteristics of sorghum mitochondrial orf25, urf209, and a related chimeric configuration, orf265/130, which is restricted to the IS1112C source of cytoplasmic male sterility in sorghum. Transcripts of urf209 are edited at ten nucleotides, resulting in nine amino-acid changes predicted from genomic sequences. The cDNA-predicted polypeptide product is 23.6 kDa, while Western blot analyses identify a product of 20k Da. Transcription of urf209 is characterized by one or two transcripts, dependent on nuclear background, but this difference is not related to male fertility status. The orf265/130 chimeric region includes 288 bp 95% identical to sequences 5' to maize T-cytoplasm T-urf13 and atp6, which includes a common transcription initiation site, and terminates with a recombinational event involving urf209. The urf209 similarity extends 189 bp, followed by sequences duplicated 5' to sorghum atp6-2. Sequences immediately 3' to the atp6-2 similarity include a second in-frame start codon, defining orf130. Structural features 5' to orf130 are shared with motifs found 5' to several translated mitochondrial open reading frames. The orf265/orf130 configuration is uniquely transcribed, and transcripts of orf130 exhibit one silent RNA editing event. Transcription in somatic cells is not altered by male fertility status.

Molecular and ultrastructural analysis of a nonchromosomal variegated mutant. Tomato mitochondrial mutants that cause abnormal leaf development

Mutants were recovered in a population of cybrids formed following protoplast fusion between tomato (Lycopersicon esculentum Mill.) cv UC82 and Lycopersicon pennellii Corr. The cybrids were identified as individuals with recombinant cytoplasmic genomes but only tomato nuclear genomes. The mutants were identified based on two features, a variegated sectoring of light and dark green regions on their leaves, stems, and fruit, and reduced growth in the field. The mutants produced 50% of the shoot fresh weight and 20% of the fruit fresh weight of the parental type, UC82. The variegated sectoring was maternally inherited. The chloroplast genome in the mutants was indistinguishable from the chloroplast genome in UC82, when distribution of restriction endonuclease sites was used as an assay. The mitochondrial genome in the mutants, however, was recombinant, containing genes from UC82 and L. pennellii. Light microscopic analysis of the leaves of the mutants demonstrated an absence of the palisade layer in the variegated sectors. Electron microscopic analysis of these same regions demonstrated an absence of normal inner membranes in the mitochondria of these cells.

A novel pea mitochondrial in vitro transcription system recognizes homologous and heterologous mRNA and tRNA promoters

To elucidate the mechanism involved in the transcription initiation process in mitochondria of dicotyledonous plants, an in vitro transcription system was established for pea (Pisum sativum L.). The partially purified mitochondrial protein extract initiates transcription on homologous pea templates as well as on heterologous mitochondrial DNA from other dicot plant species. In vitro transcription begins within the nonanucleotide 5'-(-7)CRTAAGAGA(+2)-3' (transcription start site is underlined) conserved at most of the identified transcription initiation sites in dicot plant mitochondria. The in vitro initiation at promoters of protein as well as of tRNA coding genes indicates a common mode of transcription initiation for different types of RNA. The competent recognition of different heterologous templates supports a general functional role of the conserved nonanucleotide within mitochondrial promoters of dicotyledonous plants. Initial studies of the promoter structure by deletion analysis in the 5' region of the pea atp9 promoter show that in addition to the conserved nonanucleotide, which is essential for transcription initiation in vitro, sequences up to 25 nucleotides upstream of the transcription start site are necessary for an efficient initiation event.

How do alterations in plant mitochondrial genomes disrupt pollen development?

Cytoplasmic male sterility arises when mitochondrial activities are disrupted that are essential for pollen development. Rearrangements in the mitochondrial genome that create novel open reading frames are strongly correlated with CMS phenotypes in a number of systems. The morphological aberrations which indicate CMS-associated degeneration are frequently restricted to the male sporogenous tissue and a limited number of vegetative tissues. In several cases, this tissue specificity may result from interactions between the mitochondrial genome and nuclear genes that regulate mitochondrial gene expression. A molecular mechanism by which CMS might be caused has not been conclusively demonstrated for any system. Several hypotheses for general mechanisms by which mitochondrial dysfunction might disrupt pollen development are discussed, based on similarities between the novel CMS-associated genes from a number of systems.

Transcription of potato mitochondrial 26S rRNA is initiated at its mature 5' end

Transcription initiation sites in plant mitochondria can be located by in vitro capping of primary 5' transcript termini. Direct sequencing of a cap-labelled mitochondrial RNA from potato shows its sequence to be identical to the 5' terminal part of the 26S rRNA. Primer extension analysis indicates the mature 5' end to be the sole detectable 5' transcript terminus. In potato mitochondria the mature 5' end of the 26S rRNA is thus created by transcription initiation without any further 5' processing. The nucleotide sequence surrounding this transcription initiation site shows only limited similarity to other putative promoter sequences from dicot plant mitochondria suggesting the possibility that divergent RNA polymerases, and/or transcription initiation factors, are present in plant mitochondria.

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.

Occurrence and transcription of genes for nad1, nad3, nad4L, and nad6, coding for NADH dehydrogenase subunits 1, 3, 4L, and 6, in liverwort mitochondria

The genes encoding subunits 1, 3, 4L, and 6 of NADH dehydrogenase (nad1, nad3, nad4L, nad6) in the mitochondrial genome of a liverwort, Marchantia polymorpha, were characterized by comparing homologies of the amino-acid sequences of the subunits with those of other organisms. The nad3 and nad4L genes are split by single and double group II introns, respectively. The 5'-half portion of the nad6 gene was repeated at an identity of 89% to form a reading frame consisting of 100 amino-acid residues. The Northern hybridization analysis showed that all four genes are transcribed in the liverwort mitochondria.

A truncated recombination repeat in the mitochondrial genome of a Petunia CMS line

Repeated sequences known as recombination repeats are present in the majority of plant mitochondrial genomes. Two recombination repeat sequences from Petunia have been analyzed. The two repeats are virtually identical over 1.42 kb. One of the repeats is truncated and is likely to have arisen from a rare recombination event in the full-length repeat. Two sequence-blocks within the Petunia repeat are highly similar to sequences in the 5' flank of several plant mitochondrial genes. No sequence motifs are shared by the Petunia repeat and other sequenced plant mitochondrial recombination repeats, suggesting that the recombination occurs by an homologous, rather than a site-specific, mechanism.

RNA editing of rapeseed mitochondrial atp9 transcripts: RNA editing changes four amino acids, but termination codon is already encoded by genomic sequence

The gene encoding subunit 9 of Fo-ATPase of rapeseed mitochondria has been isolated. The complete genomic DNA sequence and cDNA sequence corresponding to the atp9 gene transcript have been determined by a method involving cDNA synthesis, using specific oligonucleotides as primers, followed by PCR amplification, cloning and sequencing of the amplification products. In comparison of cDNA sequences to genomic one, four modifications, C-to-U conversions, have been found. When compared with RNA editing patterns of atp9 transcripts among plant mitochondria, that of rapeseed atp9 transcript is more simple; there are only four editing sites on the coding region, and its termination codon is already encoded by genomic sequence.

Prediction of transmembrane topology of F0 proteins from Escherichia coli F1F0 ATP synthase using variational and hydrophobic moment analyses

The a subunit, a membrane protein from the E. coli F1F0 ATP synthase has been examined by Fourier analysis of hydrophobicity and of amino-acid residue variation. The amino-acid sequences of homologous subunits from Vibrio alginolyticus, Saccharomyces cerevisiae, Neurospora crassa, Aspergillus nidulans, Schizosaccharomyces pombe and Candida parapsilosis were used in the variability analysis. By Fourier analysis of sequence variation, two transmembrane helices are predicted to have one face in contact with membrane lipids, while the other spans are predicted to be more shielded from the lipids by protein. By Fourier analysis of hydrophobicity, six amphipathic alpha-helical segments are predicted in extra-membrane regions, including the region from Glu-196 to Asn-214. Fourier analysis of sequence variation in the b- and the c-subunits of the Escherichia coli F1F0 ATP synthase indicates that the single transmembrane span of the b-subunit and the C-terminal span of the c subunit each have a face in contact with membrane lipids. On the basis of this analysis topographical models for the a- and c-subunits and for the F0 complex are proposed.

Structure and expression of the rice mitochondrial apocytochrome b gene (cob-1) and pseudogene (cob-2)

Rice mitochondrial DNA contains an intact copy and a pseudogene copy of a apocytochrome b gene (cob-1 and cob-2, respectively). Using primer extension and capping analyses, the transcriptional start site has been mapped; an 11-base motif at the transcription start site closely matches the consensus promoter motifs proposed for maize, wheat and soybean mitochondrial genes. Although both copies are identical in the 5' upstream region and through most of the coding region, only cob-1-specific mRNA is detected on RNA gel-blots. Run-on transcription analysis indicates, however, that both cob-1 and cob-2 mRNAs are synthesized in vivo but less cob-2 is accumulated. At its mapped 3' terminus the cob-1 transcript possesses a sequence that could fold into a double stem-loop structure. The possible roles of a double stem-loop structure in mitochondrial gene expression are discussed.

Interaction of the mitochondrial S-Pcf locus for cytoplasmic male sterility in Petunia with multiple fertility-restoration genes in somatic hybrid plants

The Cytoplasmic Male Sterility (CMS)-associated region in Petunia, the S-Pcf locus, was defined by the analysis of recombinant mitochondrial genomes of somatic hybrid plants resulting from a fusion of protoplasts from CMS and fertile lines. The presence of the S-Pcf locus was shown to correlate with the CMS trait in stable somatic hybrids and in other CMS Petunia lines. A small population of unstable, sterile somatic hybrids was also generated in this fusion, most of which underwent cytoplasmic segregation in subsequent generations. Stable revertants of such sterile somatic hybrids were shown to lose the S-Pcf locus. In this paper we present a molecular and genetic analysis of unstable progenies of an unstable, sterile somatic hybrid plant derived from the same fusion experiment. Both male-sterile and fertile progenies of this somatic hybrid plant have shown continuous segregation of fertile and male-sterile progenies. All segregants in this line contained, and transcribed, the S-Pcf locus. Genetic analysis indicated the presence of various levels of multiple nuclear fertility-restoration genes in this group of progenies. These findings consolidate the association between the S-Pcf locus and the CMS trait in Petunia. It also shows that the restoration of fertility by the multiple nuclear gene system does not affect the transcription of the S-Pcf locus and that the presence of an intact S-Pcf locus is necessary in order to maintain the potential sterility in the cytoplasm.

Conserved sequence blocks 5' to start codons of plant mitochondrial genes

Three sequence blocks of 10-12 bp are conserved in sequence and order 5' to putative start codons of several higher-plant mitochondrial genes. At least 25 examples were found, primarily associated with coxII, atp6, and orf25, in monocotyledons and dicotyledons. The proximal block can be 9 bp from start codons, and the three blocks generally occur within 100 bp 5' of start codons. In three examples 5' termini of the blocks represent recombination breakpoints, resulting in conservation of the blocks in resultant configurations. The two proximal blocks can form a secondary structure motif. The occurrence of the blocks near start codons, and conserved sequence and order, is consistent with a possible role in translation initiation or regulation.

ATP synthase subunit c/III/9 gene sequences as a tool for interkingdom and metaphytes molecular phylogenies

The 38 sequences of the ATPase c/III/9 gene determined in bacteria, fungi, mammals, and higher plants have been used to construct phylogenetic trees by distance matrix and parsimony methods (checked by bootstrapping); alignments have been performed on the deduced amino-acid sequences and then transferred back to the nucleotide sequences. Three lineages stand out: (1) eubacteria (except cyanobacteria and alpha purple bacteria), (2) chloroplasts, together with cyanobacteria, and (3) mitochondria together with nuclei and alpha purple bacteria. The clear monophyly of the mitochondrial/nuclear lineage, taken all together, strongly suggests that the nuclear copies of the gene now residing in the eukaryotic nucleus originate from a mitochondrial transfer. Within this lineage, metaphytes emerge late and as a cohesive group, after fungi (as a dispersed group) and metazoa, yielding an order that markedly differs from that obtained through typical RNA nuclear molecules. The possible biphyletic origin of mitochondria based on mitochondrial rRNA sequences is not evidenced by these sequences. Internal branches within both the chloroplastic and the mitochondrial lineages are consistent with botanical evolutionary schemes based on morphological characters. In spite of its relatively small size, the ATPase c/III/9 gene therefore displays remarkable properties as a phylogenetic index and adds a new tool for molecular evolutionary reconstructions, especially within the metaphytes.

Different organization and altered transcription of the mitochondrial atp6 gene in the male-sterile cytoplasm of rapeseed (Brassica napus L.)

The Fo-ATPase subunit 6 gene (atp6) of rapeseed mitochondria has been isolated from both pol male-sterile and normal (fertile) cytoplasms in order to determine whether the rearrangements around the atp6 locus in pol male-sterile cytoplasm play a role in cytoplasmic male-sterility (cms). The pol cms and normal atp6 genes are identical and encode a 261-amino acid polypeptide. As a result of extensive rearrangement, a novel reading frame (pol-urf) was generated upstream of the atp6 gene only in pol cms mitochondria, which encoded 105 amino acids and might be co-transcribed with atp6. A 5'-portion of pol-urf shows sequence homology to the Oenothera ORFB gene associated with coxIII. A 5'-flanking region of the pol-urf also shows homology to that of ORF105 in Ogura cms radish mitochondria. These DNA rearrangements which give rise to pol-urf in the vicinity of the atp6 locus may be responsible for cms in rapeseed.

Two potential Petunia hybrida mitochondrial DNA replication origins show structural and in vitro functional homology with the animal mitochondrial DNA heavy and light strand replication origins

Four Petunia hybrida mitochondrial (mt) DNA fragments have been isolated, sequenced, localized on the physical map and analyzed for their ability to initiate specific DNA synthesis. When all four mtDNA fragments were tested as templates in an in vitro DNA synthesizing lysate system, developed from purified P. hybrida mitochondria, specific initiation of DNA synthesis could only be observed starting within two fragments, oriA and oriB. When DNA synthesis incubations were performed with DNA templates consisting of both the A and B origins in the same plasmid in complementary strands, DNA synthesis first initiates in the A-origin, proceeds in the direction of the B-origin after which replication is also initiated in the B-origin. Based on these observations, a replication model for the P. hybrida mitochondrial genome is presented.

Editing of mitochondrial atp9 transcripts from two sorghum lines

Genomic and cDNA sequences of the ATP synthase complex subunit 9 (atp9) genes from two sorghum lines were determined. Sequences of cDNAs revealed eight C to U transcript editing events resulting in six amino acid changes and a new stop codon which eliminated 12 carboxy-terminal residues, compared to the genomic sequence. Sorghum atp9 has a unique five-residue amino-extension relative to other higher plants. The resulting predicted 79-residue gene product has a molecular weight of 8.179 kDa. The predicted phe-val-phe carboxy-terminus is identical to that from cDNA sequences of wheat, Oenothera, and petunia. Partial editing of transcripts was detected in each sorghum line.

The male sterility-associated pcf gene and the normal atp9-1 gene in Petunia are located on different mitochondrial DNA molecules

A mitochondrial DNA (mtDNA) region termed the S-pcf locus has previously been correlated with cytoplasmic male sterility (CMS) in Petunia. In order to understand the relationship of the S-pcf locus to homologous sequences found elsewhere in mtDNAs of both CMS and fertile lines, the structure of the mitochondrial genome of CMS Petunia line 3688 was determined by cosmid walking. The S-pcf locus, which includes the only copies of genes for NADH dehydrogenase subunit 3 (nad3) and small ribosomal subunit protein 12 (rps12) was found to be located on a circular map of 396 kb, while a second almost identical circular map of 407 kb carries the only copies of the genes for 18S and 5S rRNA (rrn18 and rrn5), the only copy of a conserved unidentified gene (orf25), and the only known functional copy of atp9. Three different copies of a recombination repeat were found in six genomic environments, predicting sub-genomic circles of 277, 266 and 130 kb. The ratio of atp9 to S-pcf mtDNA sequences was approximately 1.5 to 1, indicating that sub-genomic molecules carrying these genes differ in abundance. Comparison of the mtDNA organization of the CMS line with that of the master circle of fertile Petunia line 3704 reveals numerous changes in order and orientation of ten different sectors.

Higher plant mitochondrial DNA expression : 1. Variant expression of the plant mitochondrial open reading frame, ORF25, in B37N and B73N maize lines

In studying the process of mitochondrial transcription, mutants that show altered gene expression as evidenced from transcript pattern differences are a valuable resource. However, such mutants are difficult to find since changes in mitochondrial gene expression will most likely be lethal. Several laboratories have been investigating cytoplasmic male-sterile mutants in maize and have reported changes in transcription patterns due to nuclear background influences on the complex chimeric gene region TURF-2H3 in T-cms. There have been no reports of altered transcription patterns for N cytoplasm that can be attributed to nuclear background differences. Through a Northern hybridization analysis of ORF25 transcription in a number of N lines, we reported invariant expression of this region. Subsequently, we have discovered a line B37N, which shows the presence of a single ORF25-specific transcript of 3,400 nucleotides, in contrast to the transcript sizes of 3,400, 2,300 and 1,600 displayed by most of the cytoplasms we have examined. Experiments presented in this communication demonstrate that the differences in the B37N, ORF25 transcript pattern map to the 5' flanking sequences of the reading frame. Using restriction enzyme mapping and Southern hybridization analysis, no detectable differences were found in the transcription unit structure for this reading frame in B37N and B73N, which shows the standard, three-transcript pattern. Analysis of nuclear background influences indicates that the transcript patterns for this open reading frame are dependent on nuclear background. These data are presented in part 2 of this study.

Characterization of transcription initiation sites on the soybean mitochondrial genome allows identification of a transcription-associated sequence motif

Transcription initiation sites on the soybean mitochondrial genome have been characterized by sequence analysis of in vitro-capped soybean mtRNAs and corresponding mtDNA regions. The most abundant, discrete soybean mtRNA species labeled by guanylyltransferase and [alpha-32P]GTP are shown to correspond to the major transcript of the atp9 gene and to a group of small RNAs consisting of a discrete 80 nucleotide (nt) species plus heterogeneous species ranging in size from 133 to 148 nt. The 133-148 nt RNAs represent a set of transcripts with a common 5' terminus and ragged 3' ends, while the 80 nt RNA corresponds to positions 53-133 of the 133 nt species. The major, discrete in vitro-capped RNA species thus correspond to primary transcripts originating at three sites located in two regions of the soybean mitochondrial genome. The sequences extending from 13 nucleotides upstream to 8 nucleotides downstream of the initiation sites for the atp9 and 133-148 nt transcripts are identical at 18 of 21 positions. Sequences closely resembling this motif are located at some other 5' transcript termini of dicot plant mitochondria. Less closely related sequences are found at transcription initiation sites of wheat and maize mitochondria.

Sequence analysis of wheat mitochondrial transcripts capped in vitro: definitive identification of transcription initiation sites

To identify transcription initiation sites in wheat mitochondria, the nascent 5'-ends of transcripts were specifically labeled by incubation of wheat mitochondrial RNA with [alpha-32P]GTP in the presence of the enzyme guanylyltransferase. After separation of the resulting capped transcripts by electrophoresis in polyacrylamide gels, individual RNAs were recovered and directly sequenced. Four RNA sequences obtained in this way were localized upstream of the protein-coding genes atpA, coxII, coxIII and orf25. Comparison of mRNA and gene sequences allowed precise positioning of transcription initiation sites for these four genes. Sequence similarities immediately upstream of these sites define a conserved motif that we suggest as a candidate regulatory element in wheat mtDNA. The relationship between this motif and putative mitochondrial promoters in other plant species is discussed.

Transcription of the Petunia mitochondrial CMS-associated Pcf locus in male sterile and fertility-restored lines

Transcripts of the Petunia mitochondrial cytoplasmic male sterility (CMS)-associated S-Pcf locus, which consists of three co-transcribed genes (pcf, NADH dehydrogenase subunit 3, and ribosomal protein S12), have been characterized in reproductive tissues of CMS and fertility restored (Rf) Petunia lines by nuclease protection experiments and by RNA blot hybridization. Three 5' transcript termini have been previously described. Two 3' transcript termini and an additional S-Pcf locus transcript have now been identified. The relative abundance of the three 5' transcript termini is influenced by the presence of the nuclear Rf gene. A decrease in the abundance of the -121 5' transcript terminus relative to the -266 and -522 termini is consistently seen in Petunia lines which are restored to fertility by the Rf gene, compared to CMS Petunia lines. An additional transcript with a 5' terminus within the urf-s region of pcf is much more abundant in immature bud and anther tissue than in leaf or suspension cells. The total abundance of pcf transcripts varies greatly between plants of different nuclear backgrounds which lack the nuclear Rf allele, indicating that other nuclear genes also influence expression of the S-Pcf locus.

Nucleotide sequence and transcriptional analysis of a mitochondrial plasmid from a cytoplasmic male-sterile line of sunflower

A mitochondrial plasmid of 1,939 bp (P2) from a cytoplasmic male-sterile line of sunflower has been cloned and sequenced. It presents 437 bp of near-perfect homology to the 1.4-kb mitochondrial plasmid P1 from sunflower. Sequences homologous to P2 were found in nuclear DNA. P2 was transcribed into a major 980-nucleotide (nt) RNA molecule and two minor transcripts of 570 and 520 nt. They were all transcribed from the same strand and within the region nonhomologous to P1. A single 5' boundary and three 3' termini were determined for P2 transcripts. The 5' end is similar to a consensus sequence for plant mitochondrial genes. No evidence of translation products can be provided.

Essential residues in the polar loop region of subunit c of Escherichia coli F1F0 ATP synthase defined by random oligonucleotide-primed mutagenesis

The conserved, polar loop region of subunit c of the Escherichia coli F1F0 ATP synthase is postulated to function in the coupling of proton translocation through F0 to ATP synthesis in F1. We have used a random mutagenesis procedure to define the essential residues in the region. Oligonucleotide-directed mutagenesis was carried out with a random mixture of mutant oligonucleotides, the oligonucleotide mixture being generated by chemical synthesis by using phosphoramidite nucleotide stocks that were contaminated with the other three nucleotides. Thirty mutant genes coding single-amino-acid substitutions in the region between Glu-37 and Leu-45 of subunit c were tested for function by analyzing the capacity of plasmids carrying the mutant genes to complement a Leu-4----amber subunit c mutant. All substitutions at the conserved Arg-41 residue resulted in loss of oxidative phosphorylation, i.e., transformants could not grow on a succinate carbon source. The other conserved residues were more tolerant to substitution, although most substitutions did result in impaired growth on succinate. We conclude that Arg-41 is essential in the function of the polar loop and that the ensemble of other conserved residues collectively maintain an optimal environment required for that function.

Comparison of the organization of the mitochondrial genome in tomato somatic hybrids and cybrids

The organization of the mitochondrial genome in somatic hybrids and cybrids regenerated following fusion of protoplasts from cultivated tomato, Lycopersicon esculentum, and the wild species, L. Pennellii, was compared to assess the role of the nuclear genotype on the inheritance of organellar genomes. No organellar-encoded traits were required for the recorvery of either somatic hybrids or cybrids. The organization of the mitochondrial genome was characterized using Southern hybridization of restriction digestions of total DNA isolated from ten cybrids and ten somatic hybrids. A bank of cosmid clones carrying tomato mitochondrial DNA was used as probes, as well as a putative repeated sequence from L. pennellii mitchondrial DNA. The seven cosmids used to characterize the mitochondrial genomes are predicted to encompass at least 60% of the genome. The frequency of nonparental organizations of the mitochondrial genome was highest with a probe derived from a putative repeat element from the L. pennellii mitochondrial DNA. There was no difference in the average frequency of rearranged mitochondrial sequences in somatic hybrids (12%) versus cybrids (10%), although there were individual cybrids with a very high frequency of novel fragments (30%). The frequency of tomato-specific mtDNA sequences was higher in cybrids (25%) versus somatic hybrids (12%), suggesting a nuclear-cytoplasmic interaction on the inheritance of tomato mitochondrial sequences.

The role of coxI-associated repeated sequences in plant mitochondrial DNA rearrangements and radish cytoplasmic male sterility

The gene coxI, encoding subunit I of mitochondrial cytochrome c oxidase, has been characterized from the normal (fertile) and Ogura (male-sterile) cytoplasms of radish to determine if a previously identified mitochondrial DNA rearrangement, and its associated transcriptional differences, could play a role in Ogura cytoplasmic male sterility (CMS). The normal and Ogura loci are virtually identical for 2.8 kb, including a 527-codon open reading frame whose product is approximately 95% identical to other plant COXI polypeptides. A rearrangement 120 bp 5' to the coding region results in different 5' transcript termini for the two genes. A comparison of several crucifer mitochondrial DNAs indicates that this rearrangement also occurs in the normal radish cytoplasm and is, therefore, not involved in Ogura CMS. Sequences present at the coxI locus belong to at least two different dispersed repeat families, members of which are also associated with other rearranged genes in radish.

Transcriptional and posttranscriptional regulation of maize mitochondrial gene expression

Lysed maize mitochondria synthesize RNA in the presence of radioactive nucleoside triphosphates, and this assay was utilized to compare the rates of transcription of seven genes. The rates of incorporation varied over a 14-fold range, with the following rank order: 18S rRNA greater than 26S rRNA greater than atp1 greater than atp6 greater than atp9 greater than cob greater than cox3. The products of run-on transcription hybridized specifically to known transcribed regions and selectively to the antisense DNA strand; thus, the isolated run-on transcription system appears to be an accurate representation of endogenous transcription. Although there were small differences in gene copy abundance, these differences cannot account for the differences in apparent transcription rates; we conclude that promoter strength is the main determinant. Among the protein coding genes, incorporation was greatest for atp1. The most active transcription initiation site of this gene was characterized by hybridization with in vitro-capped RNA and by primer extension analyses. The DNA sequences at this and other transcription initiation sites that we have previously mapped were analyzed with respect to the apparent promoter strengths. We propose that two short sequence elements just upstream of initiation sites form at least a portion of the sequence requirements for a maize mitochondrial promoter. In addition to modulation at the level of transcription, steady-state abundance of protein-coding mRNAs varied over a 20-fold range and did not correlate with transcriptional activity. These observations suggest that posttranscriptional processes are important in the modulation of mRNA abundance.

A termination codon is created by RNA editing in the petunia atp9 transcript

Analysis of the cDNA of the atp9-1 gene transcript from petunia mitochondria has revealed that ten C residues of the gene sequence are edited into U in the mRNA. Seven of these edits result in amino acid changes and one introduces a stop codon before the end of the open reading frame predicted from the gene sequence. The resulting protein is better conserved when compared to the same protein in other organisms. Comparison of the edited petunia sequence with other plant mitochondrial atp9 gene sequences idicates variation in the number and positions of edits required to obtain the same amino acids in ATP9 polypeptides of higher plants.

Transcriptional and posttranscriptional regulation of maize mitochondrial gene expression

Lysed maize mitochondria synthesize RNA in the presence of radioactive nucleoside triphosphates, and this assay was utilized to compare the rates of transcription of seven genes. The rates of incorporation varied over a 14-fold range, with the following rank order: 18S rRNA greater than 26S rRNA greater than atp1 greater than atp6 greater than atp9 greater than cob greater than cox3. The products of run-on transcription hybridized specifically to known transcribed regions and selectively to the antisense DNA strand; thus, the isolated run-on transcription system appears to be an accurate representation of endogenous transcription. Although there were small differences in gene copy abundance, these differences cannot account for the differences in apparent transcription rates; we conclude that promoter strength is the main determinant. Among the protein coding genes, incorporation was greatest for atp1. The most active transcription initiation site of this gene was characterized by hybridization with in vitro-capped RNA and by primer extension analyses. The DNA sequences at this and other transcription initiation sites that we have previously mapped were analyzed with respect to the apparent promoter strengths. We propose that two short sequence elements just upstream of initiation sites form at least a portion of the sequence requirements for a maize mitochondrial promoter. In addition to modulation at the level of transcription, steady-state abundance of protein-coding mRNAs varied over a 20-fold range and did not correlate with transcriptional activity. These observations suggest that posttranscriptional processes are important in the modulation of mRNA abundance.

RNA editing of wheat mitochondrial ATP synthase subunit 9: direct protein and cDNA sequencing

RNA editing of subunit 9 of the wheat mitochondrial ATP synthase has been studied by cDNA and protein sequence analysis. Most of the cDNA clones sequenced (95%) showed that editing by C-to-U transitions occurred at eight positions in the coding region. Consequently, 5 amino acids were changed in the protein when compared with the sequence predicted from the gene. Two edited codons gave no changes (silent editing). One of the C-to-U transitions generated a stop codon by modifying the arginine codon CGA to UGA. Thus, the protein produced is 6 amino acids shorter than that deduced from the genomic sequence. Minor forms of cDNA with partial or overedited sequences were also found. Protein sequence and amino acid composition analyses confirmed the results obtained by cDNA sequencing and showed that the major form of edited atp9 mRNA is translated.

Direct protein sequencing of wheat mitochondrial ATP synthase subunit 9 confirms RNA editing in plants

RNA editing, a process that results in the production of RNA molecules having a nucleotide sequence different from that of the initial DNA template, has been demonstrated in several organisms using different biochemical pathways. Very recently RNA editing was described in plant mitochondria following the discovery that the sequence of certain wheat and Oenothera cDNAs is different from the nucleotide sequence of the corresponding genes. The main conversion observed was C to U, leading to amino acid changes in the deduced protein sequence when these modifications occurred in an open reading frame. In this communication we show the first attempt to isolate and sequence a protein encoded by a plant mitochondrial gene. Subunit 9 of the wheat mitochondrial ATP synthase complex was purified to apparent homogeneity and the sequence of the first 32 amino acid residues was determined. We have observed that at position 7 leucine was obtained by protein sequencing, instead of the serine predicted from the previously determined genomic sequence. Also we found phenylalanine at position 28 instead of a leucine residue. Both amino acid conversions, UCA (serine) to UUA (leucine) and CUC (leucine) to UUC (phenylalanine), imply a C to U change. Thus our results seem to confirm, at the protein level, the RNA editing process in plant mitochondria.

The Pisum sativum mitochondrial gene encoding cytochrome oxidase subunit I has an unusual transcription pattern

We report the transcriptional analysis of the mitochondrial (mt) gene encoding cytochrome oxidase subunit I (COXI). A probe made from the protein-coding region of the pea coxI gene hybridized to four RNA transcripts, two of which are much larger than necessary to encode the COXI polypeptide. The RNA hybridization was repeated with a series of sequential probes made from the 5'-untranslated region. The results of these experiments indicated that all four transcripts initiate between 2.8 and 2.1 kb upstream from the protein-coding region. Furthermore, the pattern of hybridization to these sequential probes was unusual, suggesting that introns are spliced out of the 5'-transcribed, but untranslated, region. A sequence located within one of the sequential probes is repeated elsewhere in the pea mt genome. Transcript termini were mapped for the 5' and 3' ends and putative regulatory sequences were located.

Cytochrome oxidase subunit II sequences in Petunia mitochondria: two intron-containing genes and an intron-less pseudogene associated with cytoplasmic male sterility

The mitochondrial genome of Petunia hybrida contains two transcribed cytochrome oxidase subunit II (coxII) genes. The coding region of both genes is split by a 1.3 kb group II intron. Unlike coxII-1, which is similar to other sequenced plant coxII genes, the coxII-2 coding region is extended by 48 codons. The cytoplasmic male sterile (CMS) Petunia contains one coxII gene similar in structure and transcript pattern to the coxII-1 gene found in the fertile genome. Comparison of the sequenced coxII genes from the fertile mitochondrial genome with the coxII sequences present in the CMS-associated pcf gene from the CMS genome (Young and Hanson 1987) suggests that pcf is a processed pseudogene. A model for the generation of pcf is presented.

Three copies of a single recombination repeat occur on the 443 kb master circle of the Petunia hybrida 3704 mitochondrial genome

At 443 kb, the map of Petunia hybrida line 3704 mitochondrial DNA is the largest yet produced from a dicot plant. Regions of similarity to known plant mitochondrial genes and to the chloroplast genome have been placed on a master circle. One long repeated sequence, apparently active in recombination, is present in three copies. Two copies of 6.6 kb occur in a direct orientation and are separated by 199 kb. A third truncated copy of 3.5 kb is inverted relative to the other two and is separated from the others by 99 and 145 kb. The presence of the recombination repeats predicts a multipartite molecular organization, consisting of four master circles and three subgenomic circles. Two other repeated regions were found not to be substrates for, or products of recombination. The absence of recombination at certain reiterated regions indicates that there is specificity of recombination at the recombination repeats.

A NADH dehydrogenase subunit gene is co-transcribed with the abnormal Petunia mitochondrial gene associated with cytoplasmic male sterility

DNA sequence analysis 3' to the Petunia S-pcf coding region has resulted in the identification of an open reading frame similar to mammalian mitochondrial genes for subunit 3 of the NADH dehydrogenase complex (nad3). Both the abnormal fused gene S-pcf and S-nad3 fall within the mitochondrial DNA region previously shown to be associated with cytoplasmic male sterility (CMS). The S-nad3 sequence, co-transcribed with S-pcf, is present in only one copy within the Petunia CMS genome. A homologous transcribed sequence from the mitochondrial genome of a fertile Petunia line has been identified. The coding region of the two genes are identical and they share homology for at least 800 bp downstream. The genes diverge 117 bp upstream of the nad3 start codon. Transcripts of the S-pcf/S-nad3 transcripts are similar in tissues of a fertility-restored line and a CMS line.

Ribosomal protein S14 genes in broad bean mitochondrial DNA

Broad bean (Vicia faba) mtDNA contains an open reading frame with a predicted amino acid sequence that is 41% homologous to the ribosomal protein S14 (RPS14) of Escherichia coli, and which is located 1232 ntp upstream from a gene for cytochrome b (cob). A second putative rpS14 gene occurs in broad bean mtDNA, 344 ntp upstream from a gene for ATPase subunit 9 (atp9). However, the atp9-linked rpS14 gene is 12 codons shorter than the cob-linked rpS14 gene. Sequence homology is found upstream (for 218 ntp) but not downstream from the two rpS14 genes. Transcripts were detected in broad bean mtRNA only for the cob-linked rpS14 gene. All RNA molecules that include a transcript of the rpS14 gene also include a transcript of the cob gene. Sequences homologous to the broad bean mitochondrial rpS14 gene were detected in soybean mtDNA, but not in corn mtDNA. Relationships between the amino acid sequences of RPS14s encoded in broad bean mtDNA, in chloroplast DNAs of various angiosperms, and in E. coli are consistent with the view that the ancestral lines of these three kinds of DNA diverged from each other within a relatively short time period.

Chimeric organization of two genes for the soybean mitochondrial ATPase subunit 6

There are two copies of the ATPase subunit 6 (atp6) gene in the soybean mitochondrial genome which differ in their gene organization but share extensive homology with the maize atp6 gene except at their 5' ends. The two soybean genes are chimeric, containing regions with homology to other known mitochondrial genes at their 5' ends. Sequences homologous to the cytochrome oxidase subunit II (coxII) are located in one copy and sequences homologous to the ATPase subunit 9 (atp9) gene are located in the other copy, both of which contain methionine (ATG) codons that are in-frame with the remainder of the atp6 open reading frame. At least the copy of atp6 that contains the coxII sequence at its 5' end is abundantly transcribed to give an RNA of approximately 1,200 nucleotides.