Genomic context influences the activity of maize mitochondrial cox2 promoters

Homologous recombination changes the context of Cytochrome b transcription in the mitochondrial genome of Silene vulgaris KRA

Background

Silene vulgaris (bladder campion) is a gynodioecious species existing as two genders – male-sterile females and hermaphrodites. Cytoplasmic male sterility (CMS) is generally encoded by mitochondrial genes, which interact with nuclear fertility restorer genes. Mitochondrial genomes of this species vary in DNA sequence, gene order and gene content. Multiple CMS genes are expected to exist in S. vulgaris, but little is known about their molecular identity.

Results

We assembled the complete mitochondrial genome from the haplotype KRA of S. vulgaris. It consists of five chromosomes, two of which recombine with each other. Two small non-recombining chromosomes exist in linear, supercoiled and relaxed circle forms. We compared the mitochondrial transcriptomes from females and hermaphrodites and confirmed the differentially expressed chimeric gene bobt as the strongest CMS candidate gene in S. vulgaris KRA. The chimeric gene bobt is co-transcribed with the Cytochrome b (cob) gene in some genomic configurations. The co-transcription of a CMS factor with an essential gene may constrain transcription inhibition as a mechanism for fertility restoration because of the need to maintain appropriate production of the necessary protein. Homologous recombination places the gene cob outside the control of bobt, which allows for the suppression of the CMS gene by the fertility restorer genes. We found the loss of three editing sites in the KRA mitochondrial genome and identified four sites with highly distinct editing rates between KRA and another S. vulgaris haplotypes (KOV). Three of these highly differentially edited sites were located in the transport membrane protein B (mttB) gene. They resulted in differences in MttB protein sequences between haplotypes.

Conclusions

Frequent homologous recombination events that are widespread in plant mitochondrial genomes may change chromosomal configurations and also the control of gene transcription including CMS gene expression. Posttranscriptional processes, e.g. RNA editing shall be evaluated in evolutionary and co-evolutionary studies of mitochondrial genes, because they may change protein composition despite the sequence identity of the respective genes. The investigation of natural populations of wild species such as S. vulgaris are necessary to reveal important aspects of CMS missed in domesticated crops, the traditional focus of the CMS studies.

Electronic supplementary material

The online version of this article (10.1186/s12864-018-5254-0) contains supplementary material, which is available to authorized users.

Mitochondrial transcript length polymorphisms are a widespread phenomenon in Arabidopsis thaliana

Natural genetic variation affects development, physiology, biochemical properties as well as mitochondrial transcripts of the model species Arabidopsis thaliana (Arabidopsis). In a previous study, we identified mitochondrial transcript end polymorphisms in Arabidopsis accessions Columbia, C24 and Landsberg erecta. The polymorphic transcript species could either be assigned to differences in the mitochondrial DNA or to natural genetic variation in the nucleus. To analyze the distribution and to identify additional 5' end polymorphisms we now analyzed 19 mitochondrial transcription units in 26 different accessions. We found additional 5' end polymorphisms indicating that such transcript length differences are a widespread phenomenon in Arabidopsis. The new polymorphisms affect cox1, cox2, nad2 as well nad3-rps12 transcript species. While the cox2 polymorphism can be attributed to a recombination event in the mitochondrial DNA, the nad2 transcript polymorphism is linked to differences in the nuclear DNA. A complex pattern is found for nad3-rps12 mRNA whose 5' ends differ between several accessions. These new polymorphisms provide an important basis for a more detailed characterization of mitochondrial 5' end processing.

The transcription machineries of plant mitochondria and chloroplasts: Composition, function, and regulation

Although genomes of mitochondria and plastids are very small compared to those of their bacterial ancestors, the transcription machineries of these organelles are of surprising complexity. With respect to the number of different RNA polymerases per organelle, the extremes are represented on one hand by chloroplasts of eudicots which use one bacterial-type RNA polymerase and two phage-type RNA polymerases to transcribe their genes, and on the other hand by Physcomitrella possessing three mitochondrial RNA polymerases of the phage type. Transcription of genes/operons is often driven by multiple promoters in both organelles. This review describes the principle components of the transcription machineries (RNA polymerases, transcription factors, promoters) and the division of labor between the different RNA polymerases. While regulation of transcription in mitochondria seems to be only of limited importance, the plastid genes of higher plants respond to exogenous and endogenous cues rather individually by altering their transcriptional activities.

Unique changes in mitochondrial genomes associated with reversions of S-type cytoplasmic male sterility in maizemar

Cytoplasmic male sterility (CMS) in plants is usually associated with the expression of specific chimeric regions within rearranged mitochondrial genomes. Maize CMS-S plants express high amounts of a 1.6-kb mitochondrial RNA during microspore maturation, which is associated with the observed pollen abortion. This transcript carries two chimeric open reading frames, orf355 and orf77, both unique to CMS-S. CMS-S mitochondria also contain free linear DNA plasmids bearing terminal inverted repeats (TIRs). These TIRs recombine with TIR-homologous sequences that precede orf355/orf77 within the main mitochondrial genome to produce linear ends. Transcription of the 1.6-kb RNA is initiated from a promoter within the TIRs only when they are at linear ends. Reversions of CMS-S to fertility occur in certain nuclear backgrounds and are usually associated with loss of the S plasmids and/or the sterility-associated region. We describe an unusual set of independently recovered revertants from a single maternal lineage that retain both the S plasmids and an intact orf355/orf77 region but which do not produce the 1.6-kb RNA. A 7.3-kb inversion resulting from illegitmate recombination between 14-bp microrepeats has separated the genomic TIR sequences from the CMS-associated region. Although RNAs containing orf355/orf77 can still be detected in the revertants, they are not highly expressed during pollen development and they are no longer initiated from the TIR promoter at a protein-stabilized linear end. They appear instead to be co-transcribed with cytochrome oxidase subunit 2. The 7.3-kb inversion was not detected in CMS-S or in other fertile revertants. Therefore, this inversion appears to be a de novo mutation that has continued to sort out within a single maternal lineage, giving rise to fertile progeny in successive generations.

In organello gene expression and RNA editing studies by electroporation-mediated transformation of isolated plant mitochondria

Plant mitochondrial gene expression is a complex process involving multiple steps such as transcription, cis- and trans-splicing, RNA trimming, RNA editing, and translation. One of the main hurdles in understanding more about these processes has been the inability to incorporate engineered genes into mitochondria. We recently reported an in organello approach on the basis of the introduction of foreign DNA into isolated plant mitochondria by electroporation. This procedure allows the investigation of transcriptional and posttranscriptional processes, such as splicing and RNA editing, by use of site-directed mutagenesis. Foreign gene expression in organello is strongly dependent on the functional status of mitochondria, thus providing relevant information in conditions closer to the situation found in vivo. The study of mutants that affect RNA splicing and editing provides a novel and powerful method to explain the role of specific sequences involved in these processes. Here we describe a protocol to "transform" isolated plant mitochondria that has allowed us to investigate successfully some aspects of RNA editing.

Comparison of promoters controlling on the sunflower mitochondrial genome the transcription of two copies of the same native trnK gene reveals some differences in their structure

Two copies of native trnK (UUU) gene are encoded on the sunflower mitochondrial DNA. They lie within two 12-kb direct repeats, presumably generated by a duplication event. During an investigation aimed at detecting DNA regions activating the trnK1 and trnK2 genes, three distinct promoters have been identified. Their locations were deduced using standard procedures (RT-PCR, RNA capping and 5'RACE) usually employed for the detection of transcription initiation sites (TISs). Promoters P3 and P2 control two independent partially overlapping transcription units containing the trnK2 and ccb206 genes, respectively. Promoter P1 has been mapped about 5200 bp upstream of the trnK1 gene which is part of a transcription unit also containing exons c, d and e of the nad2 gene, 5' to the tRNA gene. Most probably this promoter is not alone in controlling this transcription unit because this DNA region could be cotranscribed, at least partially, starting from other two promoters located upstream of the trnC and trnN genes, respectively. These genes have been previously mapped in a 5' region adjacent to the cluster containing nad2 exons c, d and e and the trnK1 gene. The comparative analysis of promoters P3 and P1 suggests that the difference between them could be related to the duplication event generating the second copy of trnK gene. The availability of a high number of new promoters belonging to dicot mitochondrial genomes makes possible to note some of their specific features.

Variable structures of promoters regulating transcription of cp-like tRNA genes and of some native genes on the sunflower mitochondrial genome

Promoter regions regulating the transcription of all cp-like tRNA genes encoded by the sunflower chondriome have been identified. Some of these genes are part of clusters where the first gene is a typical mitochondrial isoform. Promoters regulating the transcription of single cp-like tRNA genes have a variable structure whereas those regulating the transcription of native genes or clusters with typical mitochondrial genes in the first position conform to a similar common structure. The variability of promoter regions described in this paper could be the result of modifications of regions having, at the moment of the cpDNA insertion event, only minimal structural features as promoters.

Electroporation of isolated higher-plant mitochondria: transcripts of an introduced cox2 gene, but not an atp6 gene, are edited in organello

To facilitate the analysis of RNA processing in plant mitochondria, a method was established for introducing foreign DNA into mitochondria isolated from maize and sorghum. This method permits the uptake of DNA of up to 11 kb into the mitochondrial matrix. In vitro incubation of maize mitochondria in a specific buffer system was found to permit splicing and editing of newly synthesized RNAs for a period of at least 7 h. This was shown both for transcripts of endogenous mitochondrial genes (atp6, cox2) and for transcripts derived from an introduced Arabidopsis thaliana cox2 gene. In contrast, when a Sorghum bicolor atp6 gene was introduced into isolated maize mitochondria, the gene was transcribed, but the RNA was not edited, although all the editing sites in maize and sorghum atp6 RNA are identical. This may indicate the presence of transcript-specific cis -acting regions in the up- or downstream untranslated sequences of the mRNA. The system described here should allow further dissection of the mechanism of RNA editing in plant mitochondria.

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.

Nuclear gene dosage effects upon the expression of maize mitochondrial genes

Each mitochondrion possesses a genome that encodes some of its own components. The nucleus encodes most of the mitochondrial proteins, including the polymerases and factors that regulate the expression of mitochondrial genes. Little is known about the number or location of these nuclear factors. B-A translocations were used to create dosage series for 14 different chromosome arms in maize plants with normal cytoplasm. The presence of one or more regulatory factors on a chromosome arm was indicated when variation of its dosage resulted in the alteration in the amount of a mitochondrial transcript. We used quantitative Northern analysis to assay the transcript levels of three mitochondrially encoded components of the cytochrome c oxidase complex (cox1, cox2, and cox3). Data for a nuclearly encoded component (cox5b) and for two mitochondrial genes that are unrelated to cytochrome c oxidase, ATP synthase alpha-subunit and 18S rRNA, were also determined. Two tissues, embryo and endosperm, were compared and most effects were found to be tissue specific. Significantly, the array of dosage effects upon mitochondrial genes was similar to what had been previously found for nuclear genes. These results support the concept that although mitochondrial genes are prokaryotic in origin, their regulation has been extensively integrated into the eukaryotic cell.