Partial Sequence Analysis of the 5S to 18S rRNA Gene Region of the Maize Mitochondrial Genome

De Novo Hybrid Assembly Unveils Multi-Chromosomal Mitochondrial Genomes in Ludwigia Species, Highlighting Genomic Recombination, Gene Transfer, and RNA Editing Events

Biological invasions have been identified as the fifth cause of biodiversity loss, and their subsequent dispersal represents a major ecological challenge. The aquatic invasive species Ludwigia grandiflora subsp. hexapetala (Lgh) and Ludwigia peploides subsp. montevidensis (Lpm) are largely distributed in aquatic environments in North America and in Europe. However, they also present worrying terrestrial forms that are able to colonize wet meadows. To comprehend the mechanisms of the terrestrial adaptation of Lgh and Lpm, it is necessary to develop their genomic resources, which are currently poorly documented. We performed de novo assembly of the mitogenomes of Lgh and Lpm through hybrid assemblies, combining short reads (SR) and/or long reads (LR) before annotating both mitogenomes. We successfully assembled the mitogenomes of Lgh and Lpm into two circular molecules each, resulting in a combined total length of 711,578 bp and 722,518 bp, respectively. Notably, both the Lgh and Lpm molecules contained plastome-origin sequences, comprising 7.8% of the mitochondrial genome length. Additionally, we identified recombinations that were mediated by large repeats, suggesting the presence of multiple alternative conformations. In conclusion, our study presents the first high-quality mitogenomes of Lpm and Lgh, which are the only ones in the Myrtales order found as two circular molecules.

Nucleotide sequence of F(0)-ATPase proteolipid (subunit 9) gene of maize mitochondria

The F(0)-ATPase proteolipid, also referred to as subunit 9 or the dicyclohexylcarbodiimide-binding protein, is encoded by a mitochondrial gene in maize that we have designated atp 9. The clone containing atp 9 was selected for investigation from a mitochondrial DNA library because of its abundant transcript in total maize mitochondrial RNA preparations. Sequence analysis of the clone revealed an open reading frame that was readily identified by its nucleotide homology with the ATPase subunit 9 gene of yeast. As deduced from the nucleotide sequence, the maize ATPase subunit 9 protein contains 74 amino acids with a molecular weight of 7368. Substantial amino acid sequence homology is conserved among maize, yeast, bovine, and Neurospora mitochondrial ATPase subunit 9 proteins, regardless of whether the gene is nuclearly encoded (bovine and Neurospora) or mitochondrially encoded (yeast and maize). RNA transfer blot analysis indicated that the gene sequence is actively transcribed, producing an initial transcript that is large and extensively processed.

S2 episome of maize mitochondria encodes a 130-kilodalton protein found in male sterile and fertile plants

The mitochondrial genome of the S-type male-sterile cytoplasm of maize contains two linear episomes, S1 (6397 base pairs) and S2 (5453 base pairs). The S2 episome contains two large unidentified open reading frames, URF1 (3512 base pairs) and URF2 (1017 base pairs). We have demonstrated that a polypeptide with an apparent molecular mass of 130 kDa is the gene product of URF1. This polypeptide was first detected in Coomassie blue-stained protein gels of cms-S (where cms = cytoplasmic male sterile) but not in those of cms-T, cms-C, or normal mitochondrial proteins. The protein product of a translational fusion containing the 5' end of Escherichia coli lacZ and an internal segment from URF1 of S2 was recognized by antisera raised against the 130-kDa variant polypeptide. The mitochondria of fertile F(1) hybrids of cms-S x Ky21 (the male parent carrying nuclear fertility restoration genes) contain as much of the 130-kDa protein as is found in cms-S mitochondria of sterile plants. Spontaneous fertile cytoplasmic revertants from cms-S in a WF9 nuclear background also synthesized the 130-kDa polypeptide. Therefore, the mere presence or absence of the URF1 gene product of S2 does not determine the fertility status of maize plants, because male sterile and male fertile (nuclear restored and revertant) plants can contain equivalent amounts of the 130-kDa polypeptide.

Extensive and widespread homologies between mitochondrial DNA and chloroplast DNA in plants

We used hybridization techniques to demonstrate that numerous sequence homologies exist between cloned mung bean and spinach chloroplast DNA (ctDNA) restriction fragments and mtDNAs from corn, mung bean, spinach, and pea. The strongest cross-homologies are between clones derived from the ctDNA inverted repeat and mtDNA from corn and pea, although all the ctDNA clones tested hybridized to at least one mtDNA restriction fragment. Known chloroplast genes showing strong mtDNA homologies include those for the large subunit of ribulosebisphosphate carboxylase, which hybridizes to corn mtDNA, and the beta subunit of the chloroplast ATPase, which hybridizes to mung bean mtDNA. Certain of these homologies were confirmed by using cloned spinach mtDNA restriction fragments as probes in reciprocal hybridizations to ctDNA. Several of these ctDNA-homologous mtDNA sequences were shown to be much more closely related to ctDNA from the same species than to that of a distantly related species. We interpret these differential homologies as evidence for relatively recent DNA sequence transfer events, suggesting that transpostion between the two genomes is an ongoing evolutionary process.

Phylogenetic origins of the plant mitochondrion based on a comparative analysis of 5S ribosomal RNA sequences

The complete nucleotide sequences of 5S ribosomal RNAs from Rhodocyclus gelatinosa, Rhodobacter sphaeroides, and Pseudomonas cepacia were determined. Comparisons of these 5S RNA sequences show that rather than being phylogenetically related to one another, the two photosynthetic bacterial 5S RNA sequences show that rather than being phylogenetically related to one another, the two photosynthetic bacterial 5S RNAs share more sequence and signature homology with the RNAs of two nonphotosynthetic strains. Rhodobacter sphaeroides is specifically related to Paracoccus denitrificans and Rc. gelatinosa is related to Ps. cepacia. These results support earlier 16S ribosomal RNA studies and add two important groups to the 5S RNA data base. Unique 5S RNA structural features previously found in P. denitrificans are present also in the 5S RNA of Rb. sphaeroides; these provide the basis for subdivisional signatures. The immediate consequence of our obtaining these new sequences is that we are able to clarify the phylogenetic origins of the plant mitochondrion. In particular, we find a close phylogenetic relationship between the plant mitochondria and members of the alpha subdivision of the purple photosynthetic bacteria, namely, Rb. sphaeroides, P. denitrificans, and Rhodospirillum rubrum.

Intergeneric protoplast fusion between Brassica carinata and Camelina sativa

Camelina sativa is a wild crucifer that is reported to be resistant to Alternaria blight. Polyethylene glycol mediated fusion was attempted between protoplasts from etiolated hypocotyls of Brassica carinata and mesophyll protoplasts of Camelina sativa. The mean frequency of heterokaryons was 6.8%. Three hybrid shoots were regenerated, each from a single fusionderived callus. These shoots failed to produce roots capable of withstanding transplantation. Confirmation of hybridity was obtained from the morphology of in vitro produced leaves, somatic chromosome number in leaf tips, and restriction fragment length polymorphism for a nuclear rDNA probe. Analysis for organelle constitution using RFLPs indicated that the hybrid contained chrloroplasts derived from the wild species and mitochondria from the cultivated Brassica species.

A unique sequence located downstream from the rice mitochondrial atp6 may cause male sterility

Asymmetric cell-fusion of the japonica cultivar of Oryza sativa (rice) with cytoplasmic-male-sterile (CMS) plants bearing cytoplasm derived from Chinsurah Boro II, resulted in two classes of cytoplasmic hybrids (cybrids), fertile and CMS. Southern-blot analysis of the mitochondrial DNA (mtDNA) indicates recombination events around a number of genes; however, the appearance of the CMS character is tightly correlated to reorganization around the atp6 gene, suggesting recombination downstream from the atp6 gene is involved in CMS. The nucleotide sequence downstream from atp6 contains a pseudogene which was probably created by recombination of the mitochondrial genome. Sense and antisense transcripts of the downstream region of atp6 were found in CMS- and restored CMS (fertile)-lines, but not in the normal (fertile) line. In the CMS line, several antisense transcripts of the atp6 gene were also found. However, in the restored line which contains a nuclear-encoded gene, Rf-1, the levels of these transcripts were lower than in the CMS line. These results suggest abnormal transcripts of the atp6 gene produced in the antisense direction may be involved in CMS, and that products of the nuclear-encoded restorer gene may reduce abnormal transcription in this region of the mitochondrial genome.

Comparative analysis of a recombining-repeat-sequence family in the mitochondrial genomes of wheat (Triticum aestivum L.) and rye (Secale cereale L.)

The mitochondrial genomes of wheat and rye each contain a three-member family of recombining repeat sequences (the "18S/5S repeat") that encode genes for 18S and 5S rRNAs (rrn18 and rrn5) and tRNA(fMet) (trnfM). Here we present, for wheat and rye, the sequence and boundaries of the "common sequence unit" (CSU) that is shared between all three repeat copies in each species. The wheat CSU is 4,429 base-pairs long and contains (in addition to trnfM, rrn18 and rrn5) a putative promoter, three tRNA-like elements ("t-elements"), and part of a pseudogene ("psi atpAc") that is homologous to chloroplast atpA, which encodes the alpha subunit of chloroplast F1 ATPase. The rye CSU is somewhat smaller (2,855 base pairs) but contains much the same genic and other sequence elements as its wheat counterpart, except that two of the three t-elements as well as psi atpAc are found in only one of the three downstream flanks of the 18S/5S repeat, outside the CSU boundaries. In interpreting the sequence data in terms of the evolutionary history of the 18S/5S-repeat family of wheat and rye, we conclude that: (1) the wheat-rye form of the 18S/5S repeat most likely originated between 3 and 14 million years ago, in a lineage that gave rise to wheat and rye but not to barley, oats, rice or maize; (2) the close linkage (1-bp apart) between trnfM and rrn18 is similarly limited in its taxonomic distribution to the wheat/rye lineage; (3) the trnfM-rrn18 pair arose via a single mutation that inserted a sequence block containing trnfM immediately upstream of rrn18; and (4) the presence of a putative promoter upstream of rrn18 in all wheat and rye repeats is consistent with all three repeat copies being transcriptionally active. We discuss these conclusions in the light of the possible functional significance of recombining-repeats in plant mitochondrial genomes.

Somatic hybridization between Brassica juncea and Moricandia arvensis by protoplast fusion

Intergeneric somatic hybrids have been produced between Brassica juncea (2n=36, AABB) cv. RLM-198 and Moricandia arvensis (2n=28, MM) by protoplast fusion. Hypocotyl protoplasts of B. juncea were fused with mesophyll protoplasts of M. arvensis using polyethylene glycol. Fusion frequency, estimated on the basis of differential morphological characterstics of parental protoplasts was about 5%. Of the 156 calli obtained, four calli produced shoots intermediate in morphology between the parents. Hybrid nature of the plants was confirmed using wheat nuclear rDNA probe. Hybridization of total DNA with a mitochondrial DNA probe carrying 5s-18s rRNA genes of maize showed that the mitochondria of the somatic hybrids were derived from the wild species M. arvensis. Meiosis in the only hybrid that produced normal flowers revealed the occurrence of 64 chromosomes, the sum of chromosomes of parental species. Inspite of complete pollen sterility, siliquas were produced in this hybrid by back-crossing with B. juncea. These siliquas on in vitro culture produced 12 seeds.

Nucleotide sequence of the mitochondrial 5S rRNA gene from lupine (Lupinus luteus)

A lupine mitochondrial clone containing 5S rRNA gene is characterized. The gene is located on the same strand as 18S rRNA and separated from it by 190 nucleotides. The intergenic region in different plants shows high degree of homology. In the case of lupine and soybean 43 nucleotides upstream of 5S rRNA gene exhibits 100% of homology. Comparisons of lupine 5S rRNA gene sequence with other plant mitochondrial 5S rRNA genes displays high degree of homology (from 89.8% to 95.8%).

Mitochondrial DNA patterns are similar in gametosomatic and somatic hybrids of two Nicotiana species

The segregation and recombination patterns of mitochondrial genome in the somatic hybrids of Nicotiana tabacum and N. rustica were studied by RFLP analysis using four heterologous mitochondrial DNA probes, namely cytochrome oxidase subunit I (COI), cytochrome oxidase subunit II (COII), 26s rDNA and 5s-18s rDNA. These RFLP patterns were compared with those of the gametosomatic hybrids of these two species. A preponderance of N. rustica type patterns was observed in the somatic hybrids. One of the somatic hybrids had N. rustica type pattern with COI probe, novel pattern with COII, and 26s rDNA probe and N. tabacum type pattern with 5s-18s rDNA probe. These patterns are identical to those of some of the gametosomatic hybrids and could only be due to the recombination of mitochondrial genomes of the two parents. The extent and the nature of recombination of mitochondrial genomes is similar in gametosomatic and somatic hybrids.

Characterization of pearl millet mitochondrial DNA fragments rearranged by reversion from cytoplasmic male sterility to fertility

Cloned pearl millet [Pennisetum glaucum (L.) R. Br.] mitochondrial (mt) DNA fragments rearranged by spontaneous reversion from cytoplasmic male sterility (cms) to fertility were characterized by restriction mapping, hybridization with maize mt genes, and transcription analyses. The clones characterized were a 4.7-kb fragment found only in the male-sterile cytoplasm and lost upon reversion to fertility, a 10.9-kb fragment found in all cytoplasms and not changed by reversion, a 13.6-kb fragment found in the male-sterile and -fertile normal cytoplasms and lost in seven of the eight revertants studied, and a 9.7-kb fragment not found in the male-sterile cytoplasm but produced by reversion from male sterility to fertility. The restriction maps verified that the four cloned pearl millet fragments contained two sets of repeated sequences, one on the 4.7-, 10.9-, and 13.6-kb fragments, the other on the 13.6- and 9.7-kb fragments. The rrn18, rrn5, and coxI genes were located in the repeated regions of the 4.7-, 10.9-, and 13.6-kb cloned fragments. The correlation of reversion (eight independent events) with the loss of fragments containing the rrn18, rrn5, and coxI genes suggests that those lost fragments and their gene content could be responsible for the expression of cms. Transcriptional analyses using both Northern blots and end-labeled mtRNA probes verified that transcripts homologous to the rrn18 and coxI genes were present in pearl millet total mtRNA. However, no transcript differences were detected among cms, revertant, and fertile normal cytoplasms, suggesting that the reversion process involves mutational changes that may not affect transcript size. Transcript analyses indicated that the 10.9-kb clone contained an unidentified gene on the end opposite the rrn18 gene; however, since it was present in all cytoplasms, it is not believed to be involved in cms.

Structural analysis of mature and dicistronic transcripts from the 18 S and 5 S ribosomal RNA genes of maize mitochondria

Analysis of the 18 S and 5 S ribosomal RNA transcripts of maize mitochondria is described. The 5' and 3' ends of both mature rRNAs were defined by S1 nuclease protection analysis, which also showed that a small fraction of the total 18 S and 5 S rRNA population resides on common transcripts. The 5' termini of many of these RNAs are upstream from the mature 18 S 5' endpoint. Northern hybridization detected several high molecular weight RNAs that were homologous to the 5 S and 18 S genes and their flanking sequences. Because the two rRNAs share a number of transcripts, we propose that these genes are transcribed as one or more large dicistronic RNAs that are subsequently processed to mature ribosomal RNA molecules. A model for the processing of the large putative precursors is presented.

Transcriptional and Post-Transcriptional Regulation of RNA Levels in Maize Mitochondria

Relatively little is known about the mechanisms that govern the expression of plant mitochondrial genomes. We have addressed this problem by analyzing the transcriptional activity of different regions of the maize mitochondrial genome using both in vivo and isolated mitochondrial pulse-labeling systems. The regions examined included the protein genes atpA, atp6, and coxII, the 26S, 18S, and 5S rRNA genes, and sequences surrounding the rRNA genes. The rRNAs were found to be transcribed at rates fivefold to 10-fold higher than the protein genes. These rate differences are comparable with the differences in abundance of these species in the total or steady-state RNA population. Pulse-labeled RNA unexpectedly detected transcription of all regions examined, including approximately 21 kilobases of presumed noncoding sequences flanking the rRNA genes for which stable transcripts were not detected. The results obtained with RNA labeled for short pulses in vivo and in isolated mitochondria were similar, suggesting that isolated mitochondria provide a faithful run-on transcription assay. Our results indicate that the absence in total RNA of transcripts homologous to a given region of maize mitochondrial DNA does not necessarily exclude transcriptional activity of that region and that both transcriptional and post-transcriptional processes play important roles in maize mitochondrial genome expression.

Transmission of organelles in triploid hybrids produced by gametosomatic fusions of two Nicotiana species

Gametosomatic hybrids produced by the fusion of microspore protoplasts of Nicotiana tabacum Km(+)Sr(+) with somatic cell protoplasts of N. rustica were analysed for their organelle composition. For the analysis of mitochondrial (mt)DNA, species-specific patterns were generated by Southern hybridization of restriction endonuclease digests of total DNA and mtDNA with four DNA probes of mitochondrial origin: cytochrome oxidase subunit I, cytochrome oxidase subunit II, 26s rDNA and 5s-18s rDNA. Of the 22 hybrids analyzed, some had parental-type pattern for some probes and novel-type for the others, indicating interaction between mtDNA of the two parent species. For chloroplast (cp)DNA analysis, species-specific patterns were generated by Southern hybridization of restriction endonuclease digests of total DNA with large subunits of ribulose bisphosphate carboxylase and cpDNA as probes. All the hybrids had N. rustica-specific patterns. Hybrids were not resistant to streptomycin, a trait encoded by the chloroplast genome of N. tabacum. In gametosomatic fusions of the two Nicotiana species, mitochondria but not the chloroplasts are transmitted from the parent contributing microspore protoplasts.

Paternal inheritance of chloroplast DNA and maternal inheritance of mitochondrial DNA in loblolly pine

The inheritance of organelle DNAs in loblolly pine was studied by using restriction fragment length polymorphisms. Chloroplast DNA from loblolly pine is paternally inherited in pitch pine x loblolly pine hybrids. Mitochondrial DNA is maternally inherited in loblolly pine crosses. The uniparental inheritance of organelle genomes from opposite sexes within the same plant appears to be unique among those higher plants that have been tested and indicates that loblolly pine, and possibly other conifers, must have special mechanisms for organelle exclusion or degradation or both. This genetic system creates an exceptional opportunity for the study of maternal and paternal genetic lineages within a single species.

Sequence of the 18S-5S ribosomal gene region and the cytochrome oxidase II gene from mtDNA of Zea diploperennis

The coding and flanking sequences of the 18S-5S ribosomal RNA genes and the cytochrome oxidase subunit II gene of Zea diploperennis mitochondrial DNA have been determined and compared to the corresponding sequences of normal maize (Zea mays L.) Both length and substitution mutations are found in the coding region of the 18S rRNA gene, whereas only one substitution mutation is found in the coding region of cytochrome oxidase II. Sequence divergence between maize and Zea diploperennis is about one-tenth of that between wheat and maize. The rate of nucleotide divergence by base substitution is less for plant mitochrondrial genes than for comparable genes in animal mitochondria.

On the evolution of ribosomal RNA

Despite the availability of a rapidly growing ribosomal RNA database that now includes organisms in all three primary lines of descent (eubacteria, archaebacteria, and eukaryotes), theoretical treatment of the evolution of the ribosomal RNAs has lagged behind that of the protein genes. In this paper a theory is developed that applies current views of protein gene evolution to the ribosomal RNAs. The major topics addressed are the variability in size, gene arrangement, and processing of the rRNAs among the three primary lines of descent. Among the conclusions are that the rRNAs of eukaryotes retain some primitive features that were probably present in the rRNAs of the earliest cell (the progenote) and that the genes coding for the three major rRNA species were probably originally unlinked.

Variable abundance of a mitochondrial DNA fragment in cultured tobacco cells

The relative abundance of a cloned 4.5 kilobase (kb) pair mitochondrial DNA sequence in two suspension cultures of tobacco (Nicotiana tabacum cv Turkish samsun and Nicotiana tabacum NT-1) has been examined. This sequence is 70-fold reduced in NT-1 relative to Turkish samsun; the reduction is correlated with an increase in supercoiled mitochondrial DNA. This sequence does not hybridize with mitochondrial DNA from watermelon, maize, or Saccharomyces cerevisiae, nor with several cloned mitochondrial genes and is thus probably not a gene. It may represent most of the plant mitochondrial genome thought to be non-essential for mitochondrial function. The sequence complexity of supercoiled mitochondrial DNA from NT-1 cells is about one-third that found for the entire mitochondrial genome and does not include the cytochrome oxidase subunit II gene.

Tripartite mitochondrial genome of spinach: physical structure, mitochondrial gene mapping, and locations of transposed chloroplast DNA sequences

A complete physical map of the spinach mitochondrial genome has been established. The entire sequence content of 327 kilobase pairs (kb) is postulated to occur as a single circular molecule. Two directly repeated elements of approximately 6 kb, located on this "master chromosome", are proposed to participate in an intragenomic recombination event that reversibly generates two "subgenomic" circles of 93 kb and 234 kb. The positions of protein and ribosomal RNA-encoding genes, determined by heterologous filter hybridizations, are scattered throughout the genome, with duplicate 26S rRNA genes located partially or entirely within the 6 kb repeat elements. Filter hybridizations between spinach mitochondrial DNA and cloned segments of spinach chloroplast DNA reveal at least twelve dispersed regions of inter-organellar sequence homology.

The wheat mitochondrial gene for apocytochrome b: absence of a prokaryotic ribosome binding site

The wheat mitochondrial gene for apocytochrome b (CYB) has been identified by its hybridization to a yeast CYB probe and its nucleotide sequence has been determined. The wheat CYB sequence predicts a cytochrome b apoprotein of 398 amino acids; it is almost identical to that of maize but has ten additional amino acids at the carboxy terminus. No introns are present in the wheat CYB gene, but an internal segment of the gene is repeated at another genomic location. Transcript analysis reveals a single wheat CYB mRNA of approximately 2.4 kb with a long untranslated leader. Sequences upstream of the CYB coding region are very similar in wheat and maize but the stretch proposed to be a ribosome binding site in maize is not conserved in wheat. The corresponding leader regions of the wheat mitochondrial mRNAs for cytochrome oxidase subunits I and II also lack complementarity to the 3'-end of the small subunit rRNA. We conclude that alternative signals are involved in the initiation of translation in plant mitochondria.

Comparison of the mitochondrial genome of Nicotiana tabacum with its progenitor species

Mitochondrial DNAs from Nicotiana tabacum, an amphiploid, and its putative progenitor species, N. sylvestris and N. tomentosiformis were compared in structure and organization. By using DNA transfer techniques and cloned fragments of known genes from maize and N. sylvestris as labeled probes, the positions of homologous sequences in restriction digests of the Nicotiana species were analyzed. Results indicate that the mitochondrial DNA of N. tabacum was inherited from N. sylvestris. Conservation in organization and sequence homology between mtDNAs of N. tabacum and the maternal progenitor, N. sylvestris, provide evidence that the mitochondrial genome in these species is evolutionarily stable. Approximately one-third of the probed restriction fragments of N. tomentosiformis mtDNA showed conservation of position with the other two species. Pattern variations indicate that extensive rearrangement of mtDNA has occurred in the evolution of these Nicotiana species.

Identification of two methionine transfer RNA genes in the maize mitochondrial genome

Two methionine transfer RNA (tRNA) genes were identified in the maize mitochondrial genome by nucleotide sequence analysis. One tRNA gene was similar in nucleotide sequence and secondary structure to the initiator methionine tRNA genes of eubacteria and higher plant chloroplast genomes. This tRNA gene also had extensive nucleotide homology (99%) with an initiator methionine tRNA gene described for the wheat mitochondrial genome. The other methionine tRNA gene sequence was distinct and more closely resembled an elongator methionine tRNA.

Homology between the ribosomal DNA of Escherichia coli and mitochondrial DNA preparations of maize is principally to sequences other than mitochondrial rRNA genes

E. coli ribosomal DNA has been used to probe maize mitochondrial DNA. It hybridizes primarily with chloroplast ribosomal DNA sequences and with fungal and bacterial sequences which may contaminate the mtDNA preparations. It also hybridizes to the chloroplast 16S ribosomal RNA gene sequence present in the mitochondrial genome (1) as well as to the mitochondrial 18S ribosomal RNA gene sequence. Weak sequence homology was detected between E. coli rDNA and the mitochondrial 26S ribosomal RNA gene.

Nucleotide sequence and evolution of the 18S ribosomal RNA gene in maize mitochondria

The nucleotide sequence of the gene coding for the 18S ribosomal RNA of maize mitochondria has been determined and a model for the secondary structure is proposed. Dot matrix analysis has been used to compare the extent and distribution of sequence similarities of the entire maize mitochondrial 18S rRNA sequence with that of 15 other small subunit rRNA sequences. The mitochondrial gene shows great similarity to the eubacterial sequences and to the maize chloroplast, and less similarity to mitochondrial rRNA genes in animals and fungi. We propose that this similarity is due to a slow rate of nucleotide divergence in plant mtDNA compared to the mtDNA of animals. Sequence comparisons indicate that the evolution of the maize mitochondrial 18S, chloroplast 16S and nuclear 17S ribosomal genes have been essentially independent, in spite of evidence for DNA transfer between organelles and the nucleus.

A novel soybean mitochondrial transcript resulting from a DNA rearrangement involving the 5S rRNA gene

A tissue culture line of soybean cells (SB-1) is shown to have an unusual arrangement of mitochondrial genes. Fusion of the mitochondrial 5S gene to the distal end of an unidentified gene results in the abundant expression of an 800 nucleotide RNA with the 5S rRNA at its 5' end. Since only the fused 5S rRNA gene is found in this cell line, the functional 5S rRNA must arise by processing of the 800 nucleotide RNA or by intermittent termination of transcription. The 800 nucleotide transcript and its DNA arrangement are not detected at comparable levels in other soybean sources, including the parent plant of the SB-1 tissue culture line. The role of recombination in the origin of this gene fusion and in plant mitochondrial DNA in general is discussed.

Pronounced structural similarities between the small subunit ribosomal RNA genes of wheat mitochondria and Escherichia coli

We present here the nucleotide sequence of the small subunit (18S) rRNA gene from wheat mitochondria. Aside from five discrete variable domains, this gene and the analogous (16S) rRNA gene in Escherichia coli show essentially a one-to-one correspondence in their potential secondary structures, with regions accounting for 86% of the bacterial 16S rRNA having a strict secondary structure counterpart in the mitochondrial 18S rRNA. Primary sequence identity between the two rRNAs ranges from 73% to 85% (76% overall) within regions of conserved secondary structure. Within a smaller secondary structure core common to all small subunit rRNAs, the wheat mitochondrial sequence shares substantially more primary sequence identity with the E. coli (eubacterial) sequence (88%) than with the small subunit rRNA sequences of Halobacterium volcanii (an archaebacterium) (71%) or Xenopus laevis cytoplasm (61%). Moreover, the wheat mitochondrial sequence contains a very high proportion of certain lineage-specific residues that distinguish eubacterial/plastid 16S rRNAs from archaebacterial 16S and eukaryotic cytoplasmic 18S rRNAs. These data establish that the ancestry of the wheat mitochondrial 18S rRNA gene can be traced directly and specifically to the eubacterial primary kingdom, and the data provide compelling support for a relatively recent xenogenous (endosymbiotic) origin of plant mitochondria from eubacteria-like organisms.