The integrated forms of the S1 and S2 DNA elements of maize male sterile mitochondrial DNA are flanked by a large repeated sequence

Molecular heterogeneity in mitochondrial and chloroplast DNAs from normal and male sterile cytoplasms in sugar beets

Mitochondrial (mt) and chloroplast (ct) DNAs were prepared from normal (N) and male sterile (S) cytoplasmic lines of sugar beet. The DNAs were cleaved with BamHI, EcoRI, HindIII and SalI enzymes, and the resultant fragments were fractionated by agarose gel electrophoresis. The results showed that N and S cytoplasms contained distinct mtDNA. Although most of the DNA fragments were common to these two cytoplasms, each cytoplasm was readily characterized by bands specific to that cytoplasm. In addition, these distinctive cleavage patterns were invariant in different nuclear backgrounds. In contrast to the marked variation in mtDNA, restriction fragment analyses of ctDNA demonstrated little difference between both cytoplasms. Only HindIII digestion showed one band missing in the S genome. The data presented here provides circumstantial evidence for mitochondrial involvement in the inheritance of cytoplasmic male sterility in sugar beet.

Mitochondrial DNA rearrangement associated with fertility restoration and cytoplasmic reversion to fertility in cytoplasmic male sterile Phaseolus vulgaris L

Restoration of pollen fertility to cytoplasmic male sterile (CMS) Phaseolus vulgaris by a nuclear restorer gene provides a system for studying nuclear-cytoplasmic interactions. Introduction of a nuclear restorer gene to this CMS line of P. vulgaris (CMS-Sprite) results in a mitochondrial genome rearrangement similar to that observed upon spontaneous cytoplasmic reversion to fertility. Three spontaneous heritable cytoplasmic revertants were derived from CMS-Sprite. Five fully fertile restored lines were also produced by using restorer line R-351 (BC(3)F(3) populations). Comparison of the mitochondrial DNA restriction patterns of CMS-Sprite, the three fertile revertants, and the five restored lines revealed loss of a 6.0-kilobase (kb) Pst I fragment in all restored and revertant lines. Southern hybridizations with a 1.3-kb BamHI clone, internal to the 6.0-kb Pst I fragment, as a probe revealed two configurations of 6.0-kb homologous sequences in the sterile cytoplasm; one of the configurations was lost upon reversion or restoration. Mitochondrial DNA rearrangement has thus been observed upon restoration by a nuclear restorer gene in this CMS system.

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.

Mutation to male fertility and toxin insensitivity in Texas (T)-cytoplasm maize is associated with a frameshift in a mitochondrial open reading frame

Tissue culture-derived mutants of male-sterile and disease toxin-sensitive Texas (T)-cytoplasm maize that exhibit male fertility and toxin insensitivity carry numerous alterations in mitochondrial DNA. In these mutants, a 6.7-kilobase Xho I fragment characteristic of parental T cytoplasm has been rearranged. In the mutant T-4, the parental 6.7-kilobase Xho I fragment contains a guanine to adenine transition adjacent to a 5-base-pair insertion not found in T cytoplasm. The insertion, internal to a 345-base-pair open reading frame (T ORF13), generates a frameshift, resulting in a premature stop codon that terminates the open reading frame at base pair 222. In other mutants, the 345-base-pair ORF is part of a 3-kilobase deletion, which extends into a 5-kilobase repeat characteristic of mtDNA from T but not N male-fertile cytoplasm. Clones specific to T ORF13 hybridize to eight transcripts in T and T-4, yet only hybridize to three transcripts in T-7, a deletion mutant. Transcription of the T ORF13 region appears not to be altered in T-4, but the frameshift mutation in the T ORF13 reading frame indicates that a biologically inactive gene product could be associated with the mutational events. The results suggest that cytoplasmic male sterility and disease toxin sensitivity may be associated with presence of T ORF13 in T-cytoplasm maize.

Comparison of the Restriction Endonuclease Digestion Patterns of Mitochondrial DNA from Normal and Male Sterile Cytoplasms of ZEA MAYS L

High resolution gel electrophoresis has allowed the assignment of fragment number and molecular weight to EcoRI, SalI and PstI restriction fragments of mitochondrial DNA from B37 normal (N) and B37 T, C and S male sterile cytoplasmic types of maize. A minimum complexity of 450-475 kb has been established. Hybridization of cloned EcoRI fragments to restriction digests of total mitochondrial DNA suggests that at least 80% of the genome is composed of unique sequences. Restriction fragments of identical size in N, T, C and S contain similar sequence information as evidenced by their hybridization behavior.-The total SalI digest and the larger PstI fragments representing 80% of the total complexity were used to calculate the fraction of shared fragments of each pairwise combination of cytoplasmic types. The C type mtDNA is most closely allied with the other mtDNAs and shares 67% of fragments with S, 65% with N, and 60% with T. The S type mtDNA is quite divergent from N (53% shared fragments) and T (56% shared fragments). N and T share 59% of the fragments. These results are discussed in terms of the origin of mtDNA diversity in maize.

Mitochondria of Protists

Over the past several decades, our knowledge of the origin and evolution of mitochondria has been greatly advanced by determination of complete mitochondrial genome sequences. Among the most informative mitochondrial genomes have been those of protists (primarily unicellular eukaryotes), some of which harbor the most gene-rich and most eubacteria-like mitochondrial DNAs (mtDNAs) known. Comparison of mtDNA sequence data has provided insights into the radically diverse trends in mitochondrial genome evolution exhibited by different phylogenetically coherent groupings of eukaryotes, and has allowed us to pinpoint specific protist relatives of the multicellular eukaryotic lineages (animals, plants, and fungi). This comparative genomics approach has also revealed unique and fascinating aspects of mitochondrial gene expression, highlighting the mitochondrion as an evolutionary playground par excellence.

Pulsed-field gel mapping of maize mitochondrial chromosomes

Pulsed-field gel electrophoresis (PFGE) in combination with infrequently cutting restriction enzymes was used to investigate the structure of the mitochondrial (mt) genome of the maize variety Black Mexican Sweet (BMS). The mt genome of this variety was found to resemble that of the closely related B37N variety, with one recombination and five insertion/deletion events being sufficient to account for the differences observed between the two genomes. The majority of the BMS genome is organized as a number of subgenomic chromosomes with circular restriction maps. Several large repeated sequences are found in the BMS mt genome, but not all appear to be in recombinational equilibrium. No molecules large enough to contain the entire mt genome were discernible using these techniques. The mapping approach described here provides a means of quickly analyzing the large and complex mt genomes of plants.

Characterization of two minicircular plasmid-like DNAs isolated from date-palm mitochondria

We report here the identification and characterization of two minicircular plasmid-like DNAs isolated from mitochondria of a moroccan date-palm variety. Both molecules were cloned and used as probes in Southern analyses of mitochondrial and total-cellular DNA. Evidence was obtained that these plasmid-like DNAs cross-hybridized but did not show any homology to nuclear, chloroplastic, or main mitochondrial genomes. Sequence analysis revealed that both minicircles, 1,346- and 1,160-bp long, share several stretches of homology, the most important consisting of three identical clusters of lengths 42, 47 and 38 bp. In contrast, no major homology was observed with the other higher-plant plasmid-like DNAs reported so far. Sequence analysis also revealed the presence, in the same strand of one of the minicircles, of two open reading frames potentially encoding proteins 89 and 86 amino acids in length. Interestingly, Northern analyses, using single strands of each minicircle as probes, showed the presence of two transcripts hybridizing only with the strand bearing these two open reading frames. However, computer-assisted comparison of the predicted polypeptide sequences with a protein-sequence library failed to detect any significant homology to known sequences.

Genetic organization and structural features of maranhar, a senescence-inducing linear mitochondrial plasmid of Neurospora crassa

The nucleotide sequence of maranhar, a senescence-inducing linear mitochondrial plasmid of Neurospora crassa, was determined. The termini of the 7-kb plasmid are 349-bp inverted repeats (TIRs). Each DNA strand contains a long open reading frame (ORF) which begins within the TIR and extends toward the centre of the plasmid. ORF-1 codes for a single-subunit RNA polymerase that is not closely related to that encoded by another Neurospora plasmid, kalilo. The ORF-2 product may be a B-type DNA polymerase resembling those encoded by terminal protein-linked linear genetic elements, including linear mitochondrial plasmids and linear bacteriophages. A separate coding sequence for the terminal protein could not be identified; however, the DNA polymerase of maranhar has an amino-terminal extension with features that are also present in the terminal proteins of linear bacteriophages. The N-terminal extensions of the DNA polymerases of other linear mitochondrial plasmids contain similar features, suggesting that the terminal proteins of linear plasmids may be comprised, at least in part, of these cryptic domains. The terminal protein-DNA bond of maranhar is resistant to mild alkaline hydrolysis, indicating that it might involve a tyrosine or a lysine residue. Although maranhar and the senescence-inducing kalilo plasmid of N. intermedia are structurally similar, and integrate into mitochondrial DNA by a mechanism thus far unique to these two plasmids, they are not closely related to each other and they do not have any nucleotide sequence features, or ORFs, that distinguish them clearly from mitochondrial plasmids which are not associated with senescence and most of which are apparently non-integrative.

Organization of ATPA coding and 3' flanking sequences associated with cytoplasmic male sterility in Phaseolus vulgaris L

A region of the mitochondrial genome associated with cytoplasmic male sterility (CMS) in Phaseolus vulgaris was flanked by two different repeated sequences designated x and y. The DNA sequence of the CMS-unique region and a portion of each flanking repeat was determined. Repeat x contained a complete coding copy of the F1 ATPase subunit A (atpA) gene, as well as an open reading frame (orf) predicting a protein of 209 amino acids. The TGA termination codon of the atpA gene and the ATG initiation codon of orf209 were overlapping. These reading frames were oriented with their 3' ends proximal to the CMS-unique region. The CMS-unique region of 3736 nucleotides contained numerous orfs. The longest of these predicted proteins being of 239, 98 and 97 amino acids. The 3' coding and 3' flanking regions of orf98 were derived from an internal region of the higher plant chloroplast tRNA alanine intron. The region of repeat y immediately adjacent to the CMS-unique region contained the 111 carboxy-terminal coding residues of the apocytochrome b (cob) gene. This segment was oriented with its 5' end proximal to the CMS-unique region, but cob gene sequences were not fused to an initiation codon within the unique region.

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.

The kalilo linear senescence-inducing plasmid of Neurospora is an invertron and encodes DNA and RNA polymerases

The nucleotide sequence of kalilo, a linear plasmid that induces senescence in Neurospora by integrating into the mitochondrial chromosome, reveals structural and genetic features germane to the unique properties of this element. Prominent features include: (1) very long perfect terminal inverted repeats of nucleotide sequences which are devoid of obvious genetic functions, but are unusually GC-rich near both ends of the linear DNA; (2) small imperfect palindromes that are situated at the termini of the plasmid and are cognate with the active sites for plasmid integration into mtDNA; (3) two large, non-overlapping open-reading frames, ORF-1 and ORF-2, which are located on opposite strands of the plasmid and potentially encode RNA and DNA polymerases, respectively, and (4) a set of imperfect palindromes that coincide with similar structures that have been detected at more or less identical locations in the nucleotide sequences of other linear mitochondrial plasmids. The nucleotide sequence does not reveal a distinct gene that codes for the protein that is attached to the ends of the plasmid. However, a 335-amino acid, cryptic, N-terminal domain of the putative DNA polymerase might function as the terminal protein. Although the plasmid has been co-purified with nuclei and mitochondria, its nucleotide composition and codon usage indicate that it is a mitochondrial genetic element.

DNA restriction fragment length polymorphisms correlate with isozyme diversity in Phaseolus vulgaris L

Genetic variation in Phaseolus vulgaris L. (P. vulgaris) was investigated at the isozyme and DNA levels. We constructed a library of size-selected Pst I clones of P. vulgaris nuclear DNA. Clones from this library were used to examine 14 P. vulgaris accessions for restriction fragment length polymorphisms (RFLPs). DNAs from each accession were analyzed with three restriction enzymes and 18 single copy probes. The same accessions were also examined for variability at 16 isozyme loci. Accessions included four representatives of the T phaseolin group and five representatives each of the C and S phaseolin groups. One member of the S group (the breeding line XR-235-1-1) was derived from a cross between P. vulgaris and P. coccineus. Isozymes and RFLPs revealed very similar patterns of genetic variation. Little variation was observed among accessions with C and T phaseolin types or among those with the S phaseolin type. However, both isozyme and RFLP data grouped accessions with S phaseolin separately from those accessions with C or T phaseolin. The highest degree of polymorphism was observed between XR-235-1-1 and members of the C/T group. RFLP markers will supplement isozymes, increasing the number of polymorphic loci that can be analyzed in breeding, genetic, and evolutionary studies of Phaseolus.

A new senescence-inducing mitochondrial linear plasmid in field-isolated Neurospora crassa strains from India

Several field-collected strains of Neurospora crassa from the vicinity or Aarey, Bombay, India, are prone to precocious senescence and death. Analysis of one strain, Aarely-1e, demonstrated that the genetic determinants for the predisposition to senescence are maternally inherited. The senescence-prone strains contain a 7-kb, linear, mitochondrial DNA plasmid, maranhar, which is not present in long-lived isolates from the same geographical location. The maranhar plasmid has inverted terminal repeats with protein covalently bound at the 5' termini. Molecular hybridization experiments have demonstrated no substantial DNA sequence homology between the plasmid and the normal mitochondrial (mtDNA) and nuclear genomes of long-lived strains of N. crassa. Integrated maranhar sequences were detected in the mtDNAs of two cultures derived from Aarey-1e, and mtDNAs with the insertion sequences accumulated during subculturing. Nucleotide sequence analysis of cloned fragments of the two insertion sequences demonstrates that they are flanked by long inverted repeats of mtDNA. The senescence syndrome of the maranhar strains, and the mode of integration of the plasmid, are reminiscent of those seen in the kalilo strains of N. intermedia. Nonetheless, there is no detectable nucleotide sequence homology between the maranhar and kalilo plasmids.

Integrated R2 sequence in mitochondria of fertile B37N maize encodes and expresses a 130 kD polypeptide similar to that encoded by the S2 episome of S-type male sterile plants

Expression of a 130 kDa protein from open reading frame 1 of the integrated form of the R2 mitochondrial plasmid in normal mitochondria of B37 and other inbred lines is described. The protein appears identical to that synthesized by the closely related S2 episome found in cytoplasmic male sterile maize of the S type. Protein was detected using antisera raised against a beta-galactosidase:ORF1 fusion product containing the most antigenic region of the ORF1 product. Detection of this protein is in contrast to previous reports that mitochondria of normal, male-fertile lines either do not contain this protein, or that there are 11 in-frame stop codons in the reading frame. The integrated R2 of B37N was cloned and this region sequenced, confirming that a continuous open reading frame existed. These results are discussed in relation to the possible role of the S-type episomes in causing cytoplasmic male sterility.

Location and nucleotide sequence of two tRNA genes and a tRNA pseudo-gene in the maize mitochondrial genome: evidence for the transcription of a chloroplast gene in mitochondria

We report the nucleotide sequence of three tRNA genes from maize mitochondria. The genes are located in two BamHI fragments, 3.55 and 5.7 kb long, adjacent to the S2 sequence in the maize mitochondrial genome. On the 3.55 kb BamHI fragment, we have characterized a tRNA(Cys)(GCA) gene. A strong sequence homology of this tRNA(Cys)(GCA) gene with its chloroplast counterpart in wheat suggests that it may be part of a chloroplast DNA insertion into the mitochondrial genome. This gene has been found to be transcribed in the mitochondrion. Two tRNA genes are located on the 5.7 kb BamHI fragment, separated from each other by 250 bp. One is a mitochondrial tRNA(Ser)(GCU) gene. The other, a non-transcribed tRNA(Phe)-like gene, is interrupted by a 49 base-pair inserted DNA sequence in the variable loop and has a Leu (UAA) anticodon.

Mitochondrial DNA duplication/deletion events and polymorphism of the C group of male sterile maize cytoplasms

Five accessions of members of the C group of male sterile maize cytoplasms (BB, C, ES, PR, and RB) in two nuclear backgrounds (A619 and A632) were examined to elucidate the nature of mitochondrial genome diversity within a related group of cytoplasms. Cosmid and plasmid clones carrying single copy and recombinationally active sequences from N and S cytoplasms of maize were used as probes. Although restriction patterns are quite similar, each of the five could be discriminated by evidence of sequence duplication and recombination, deletion of recombinationally active sequences of N, normal cytoplasm, population of mini-circular DNAs, and by restriction patterns. Each member of the group carried a 1,913 bp minicircular mtDNA, while all entries but RB carried a 1,445 bp minicircular mtDNA. Members of the C group clearly are not molecularly identical; evolution of the group included principal genome reorganization involving sequence duplication/deletion events, apparently independent of the cms trait.

Toxin resistance and/or male fertility reversion is correlated with defined transcription changes in the 1.5 kb AvaI region of cmsT

Reversion of T type cytoplasmic male sterility (cmsT) to fertility is correlated with sequence changes in a 1.5 kb AvaI fragment. This 1.5 kb AvaI fragment is composed of 5' flanking sequences of ATPase subunit 6, one complete open reading frame (ORF 13) and part of the another (ORF 25). The sequence of the 1.5 kb AvaI fragment was compared to the sequences of homologous regions in the N (male fertile) and T revertant V3 mitochondrial DNA. Sequences were found to diverge between ORF 13 and ORF 25 coding regions. To further characterize the transcription of these rearranged sequences, specific probes for ORF 13, ORF 25 and 5' flanking sequences of ATPase 6 were hybridized to Northern blots of N, cmsT and the T revertant V3 and V18 mtRNAs. Each revertant has a single ORF 25 homologous transcript in contrast to the multitranscript pattern in cmsT. ORF 13 homologous transcripts were not detected in either revertant cytoplasm. The loss of ORF 13 and/or altered ORF 25 transcription in the fertile revertants may be responsible for the male fertility and/or toxin resistance in these plants.

Northern hybridization analysis of mitochondria gene expression in maize cytoplasm with varied nuclear backgrounds

Type T cytoplasmic male sterility in Zea mays is associated with mitochondrial RNA (mtRNA) coding sequences found on a 1.5 kb AvaI mitochondrial DNA (mtDNA) fragment not found in other cytoplasms (N, C, or S) (Abbott and Fauron 1986). Three probes (pH3.2N, pH2.7N, and ORF 13) specific to different parts of the 1.5 AvaI T region were used in a Northern blot analysis of N mtDNAs from lines with diverse nuclear backgrounds (Rf1, Rf2 included). The N mtDNA clone pH 3.2N shows homology with the right-hand boundary of the 1.5 AvaI T region and includes a portion of an open reading frame (ORF 25). Southern blots of AvaI and BamH1 digestions of N, T, S, and C mtDNA, probed with pH3.2N demonstrate that sequences in or adjacent to this region are highly active in recombination. The clone pH 2.7N is homologous to an untranscribed region of ATPase 6 and the structural gene; and ORF 13 is a portion of the 1.5 AvaI region derived predominantly from 26S 3' flanking sequences. pH3.2N and 1.5 AvaI sequences showed identical hybridization patterns on Northern blots of N, T, Trev and Tres mtRNAs. Transcript sizes of mtRNAs homologous to the pH 3.2N probe in all of these lines were different, however, there was no variation in transcript sizes when pH 2.7N was used as a probe. Northern blots of mtRNA from N cytoplasms with various nuclear restored backgrounds showed no difference in expression when probed with pH 3.2N or pH 2.7N; however, transcripts homologous to an ORF 13 specific probe can be detected in N cytoplasm with a particular nuclear background. This may suggest activity of nuclear restorer alleles in N cytoplasm.

Mitochondrial DNA diversity in the genera of Triticum and Aegilops revealed by southern blot hybridization

Southern blot hybridization of total DNA to defined mitochondrial DNA sequences provides a sensitive assay for mtDNA variation in the genera of Triticum and Aegilops. A clear distinction between cytoplasms of tetraploid species sharing the "AG" haploid genome is reported for the first time. The Sitopsis section of the genus Aegilops showed the most extensive intra- and inter-specific variation, whereas no variation could be detected among the cytoplasms of polyploid Triticum species (wheats) sharing the AB haploid genome. Extensive cytoplasmic intraspecific diversity was revealed in Ae. speltoides.

The Partial Purification and Characterization of Nuclear and Mitochondrial Uracil-DNA Glycosylase Activities from Zea mays Seedlings

Uracil-DNA glycosylase activities from etiolated Zea mays seedling nuclei and mitochondria were partially purified and characterized. Nuclei and mitochondria were separated using sucrose differential and step gradient centrifugation. Experiments with osmotically shocked organelles indicated that enzyme activity from mitochondria was soluble, whereas nuclear enzyme activity was only partially soluble under the conditions tested. Purification using DEAE-cellulose and Affigel Blue column chromatography yielded distinct elution profiles from both columns for each of the organellar enzyme activities. Final purification was 490- and 850- fold for the nuclear and mitochondrial uracil-DNA glycosylase, respectively. Characterization studies demonstrated significant differences between the nuclear and mitochondrial uracil-DNA glycosylase with respect to K(m), temperature, and pH activity optimum, the effect of salts, and substrate preference. Molecular weight as determined by gel filtration was 18,000 for enzymes from both sources. Both were also sensitive to the sulfhydryl group-blocking agent N-ethylmaleimide. A number of uracil analogs were tested for their ability to inhibit nuclear and mitochondrial uracil-DNA glycosylase activities. 5-Azauracil, uracil, 6-aminouracil, 6-azauracil, 5-aminouracil, and 5-fluorouracil all inhibited both activities to variable degrees.

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.

Characterization of inverted repeats from plasmid-like DNAs and the maize mitochondrial genome

Integrated inverted repeat (IR) sequences similar to those of the S plasmids have been isolated from the genomes of the normal and S type male-sterile cytoplasms of maize mitochondria. The nucleotide sequences of both the IRs and their flanking regions have distinguished and characterized several different types of repeats. The repeats may be involved in the recombinational process that occurs continuously in the mitochondrial genome. One cloned fragment, derived from a fertile revertant and containing sequences similar to S-2, does not appear to act as a typical transposable element during reversion. Several of the flanking regions examined contain a small repeat of 34 base pairs, in which a nonanucleotide segment is found with similarity to the yeast mitochondrial promoter.

Properties of the linear N1 and N2 plasmid-like DNAs from mitochondria of cytoplasmic male-sterile Sorghum bicolor

The linear N1 and N2 plasmid-like DNAs were recovered from mitochondria of the IS1112C line of cytoplasmic male-sterile (CMS) Sorghum bicolor (S. bicolor). Molecular clones containing internal sequences of these plasmids were constructed. These clones were used to probe Southern blots of mitochondrial genomes from six CMS and five male-fertile (MF) lines of S. bicolor, as well as Southern blots of IS1112C chloroplast, IS1112C nuclear and kafir nuclear genomes. We found no evidence for integrated copies of N1 or N2 in any of the mitochondrial, chloroplast or nuclear genomes probed in this study. Our clones did detect an N1-homologous transcript of 3.1 kb and N2-homologous transcripts of 3.9 and 1.4 kb in IS1112C mitochondrial RNA prepared from lines with and without nuclear, fertility-restoring genes.N1 and N2 DNAs were degraded by exonuclease III but were resistant to lambda exonuclease, presumably due to the presence of 5' terminal proteins. We detected multimeric forms of N1 and N2 in Southern blots of unrestricted, IS1112C mitochondrial DNA (mtDNA). These forms apparently also had associated protein molecules.

Cytoplasmic reversion to fertility in cms-S maize need not involve loss of linear mitochondrial plasmids

Cytoplasmic male sterility of the S type (cms-S) in maize is characterized by the presence of two autonomously replicating plasmid-like elements, S1 and S2. These plasmids have not been found in the mitochondrial genomes of normal (male-fertile) maize nor previously in male-fertile cytoplasmic revertants. This paper reports the discovery of spontaneous cytoplasmic reversion to fertility in cms-S maize not involving the loss of S1 and S2 plasmids. Data are presented showing that loss of the plasmids during cytoplasmic reversion is under nuclear influence and is not a characteristic of the S cytoplasm itself.

Circular plasmid DNAs from mitochondria of Sorghum bicolor

Agarose gel electrophoresis of mitochondrial DNA (mtDNA) from the IS1112C male-sterile cytoplasm of Sorghum bicolor (S. bicolor) revealed plasmid-like DNAs additional to the linear N1 and N2 molecules. Mitochondrial plasmids were separated from the principal mitochondrial genome and used in the construction of molecular clones. Clones with EcoRI inserts of 1.7 and 2.3 kb were recovered. Hybridization of these clones to Southern blots of unrestricted and EcoRI-digested IS1112C mitochondrial plasmids indicated the cloned inserts were complete or nearly-complete copies of minicircular DNA molecules. These clones were used to probe Southern blots of mitochondrial genomes from six cytoplasmic male-sterile (CMS) and five male-fertile (MF) lines of S. bicolor, as well as Southern blots of IS1112C chloroplast, kafir chloroplast, IS1112C nuclear, and kafir nuclear genomes. The 2.3 and 1.7 kb plasmids had a very limited distribution among the sorghum entries we examined. We found no evidence for integrated copies of these sequences in any of the mitochondrial, chloroplast, or nuclear genomes probed in this study. However, the 2.3 kb sorghum minicircle did hybridize to the 1.94 kb minicircle from maize mitochondria. Hybridization of the 1.7 and 2.3 kb clones to IS111L2C mitochondrial RNA reveal a transcript of 1.1 kb from the 1.7 kb minicircle and transcripts of 1.9 and 1.4 kb from the 2.3 kb molecule.

The maize cytochrome c oxidase subunit I gene: sequence, expression and rearrangement in cytoplasmic male sterile plants

The single copy of the gene for cytochrome c oxidase subunit I (COX I) present in the mitochondrial genome of fertile maize (Zea mays L.) is encoded by a continuous open reading frame of 1584 nucleotides. The predicted polypeptide encoded by the gene has a mol. wt. of 58 219 daltons and shows >60% amino acid sequence homology with the corresponding fungal and animal polypeptides. Two major transcripts of 2400 and 2300 nucleotides can be detected and the 5' end of the larger transcript maps to a sequence from -161 to -153 (relative to the initiator codon) which shows high homology to the yeast mitochondrial promoter. In mitochondrial DNA from the S male-sterile cytoplasm of maize, which also characteristically contain two low mol. wt. linear DNAs (S1 and S2), rearrangements just 5' (at -175) to the COX I gene, generate additional DNA restriction fragments containing entire copies of the gene. These rearrangements involve a sequence identical to the terminal 186 bp of the 208-bp inverted repeat sequence found at either end of the S1 and S2 DNAs.

A rapid screening technique for the detection of repeated DNA sequences in plant tissues

DNA sequences cloned from nuclear and mitochondrial chromosomes have been used as hybridisation probes to distinguish different plant genotypes. The probes are hybridised to squashed segments of tissue e.g. root tips. The 'squash-dot' method is rapid and suitable for screening large numbers of individual plants. One probe, specific for a rye repeated sequence family, enables rye chromosomes to be detected in wheat plants. A probe for ribosomal DNA enables plants with high or low numbers of ribosomal RNA genes to be distinguished. A maize mitochondrial DNA probe is used to distinguish plants with N, T or S cytoplasms.

Nucleotide sequence of the S-1 mitochondrial DNA from the S cytoplasm of maize

Mitochondria from the S male-sterile cytoplasm of maize contain unique DNA-protein complexes, designated S-1 and S-2. These complexes consist of double-stranded linear DNAs with proteins covalently attached to the 5' termini. To learn more about these unusual DNAs we have determined the complete nucleotide sequence of the S-1 DNA molecule (6397 bp). The sequence of S-2 has been previously determined. S-1 and S-2 are structurally similar and contain 1.7kb of sequence homology. S-1 is terminated by exact 208-bp inverted repeats that are identical with the terminal inverted repeats of S-2. S-1 and S-2 also contain a 1462-bp region of nearly perfect homology, which includes one of the terminal inverted repeats. The homology between the two molecules may be maintained, in part, by homologous recombination. S-1 has three long unidentified open reading frames, URF2 (1017 bp), URF3 (2787 bp) and URF4 (768 bp). URF2 occurs in the 1462-bp region of homology and is identical in length and location in both S-1 and S-2. Based on their structural organization and their viral-like characteristics, we propose that S-1 and S-2 code for functions involved with their maintenance and replication.

Variable presence of the 1.94kb mitochondrial plasmid in maize S cytoplasm and its relationship to cytoplasmic male sterility

Mitochondrial DNA (mtDNA) was isolated from over 100 different maize nucleo-cytoplasmic combinations. DNA preparations were assayed for the presence of the 1.94kb mitochondrial plasmid by agarose gel electrophoresis and hybridization to a recombinant clone of the plasmid. The plasmid was present in all tested inbreds which carried N, male fertile, cytoplasm or the cytoplasmically male sterile (cms) groups,cms-T andcms-C. However, members of thecms-S group differed with respect to the presence of the plasmid. Cytoplasms I, J and S possessed the plasmid, whereas cytoplasms B, CA, D, G, H, IA, ME, ML, PS, RD and VG did not.Cms-S group lines which had spontaneously reverted to fertility (nuclear and cytoplasmic revertants) did not exhibit a concomitant change in 1.94kb plasmid levels, although all such lines showed the previously reported alteration in levels of the linear mtDNAs, S1 and S2. The presence or absence of the plasmid was not correlated with (i) frequency of reversion to fertility, (ii) the degree of male sterility expressed, (iii) the presence or absence of standard nuclear restorer to fertility genes and (iv) nuclear genotype. Latin American races carrying RU cytoplasm possessed the plasmid, as did sweet corn varieties. The relevance of the data tocms and evolution of thecms-S group is discussed.

The physical map and organisation of the mitochondrial genome from the fertile cytoplasm of maize

The size of the mitochondrial genome from the fertile cytoplasm of maize has been determined by restriction mapping to be 570 kb. The entire sequence complexity of the genome can be represented on a single circular DNA species (the 'master circle'). The presence of reiterated sequences, active in recombination, results in a complex multipartite organisation.

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.

Recombination sequences in plant mitochondrial genomes: diversity and homologies to known mitochondrial genes

Several plant mitochondrial genomes contain repeated sequences that are postulated to be sites of homologous intragenomic recombination (1-3). In this report, we have used filter hybridizations to investigate sequence relationships between the cloned mitochondrial DNA (mtDNA) recombination repeats from turnip, spinach and maize and total mtDNA isolated from thirteen species of angiosperms. We find that strong sequence homologies exist between the spinach and turnip recombination repeats and essentially all other mitochondrial genomes tested, whereas a major maize recombination repeat does not hybridize to any other mtDNA. The sequences homologous to the turnip repeat do not appear to function in recombination in any other genome, whereas the spinach repeat hybridizes to reiterated sequences within the mitochondrial genomes of wheat and two species of pokeweed that do appear to be sites of recombination. Thus, although intragenomic recombination is a widespread phenomenon in plant mitochondria, it appears that different sequences either serve as substrates for this function in different species, or else surround a relatively short common recombination site which does not cross-hybridize under our experimental conditions. Identified gene sequences from maize mtDNA were used in heterologous hybridizations to show that the repeated sequences implicated in recombination in turnip and spinach/pokeweed/wheat mitochondria include, or are closely linked to genes for subunit II of cytochrome c oxidase and 26S rRNA, respectively. Together with previous studies indicating that the 18S rRNA gene in wheat mtDNA is contained within a recombination repeat (3), these results imply an unexpectedly frequent association between recombination repeats and plant mitochondrial genes.

Molecular analysis of genomic stability of mitochondrial DNA in tissue cultured cells of maize

Mitochondrial DNA (mtDNA) of the Black Mexican sweet line of maize isolated from tissue cultured cell suspension cultures and young seedlings was examined. Restriction fragments generated by two endonucleases were comparatively analyzed by visualization of ethidium bromide stained gels as well as by membrane hybridization with nick-translated DNA probes of plasmid-like S1 and S2 DNA. Although no major molecular alterations were seen in tissue cultured cells, the samples were clearly not identical. The variation was mainly in the stoichiometry of several restriction fragments. Hybridization analyses with S1 and S2 probes show no evidence of molecular rearrangement in this part of the genome in tissue cultured cells. Minor variations in restriction patterns could reflect alterations in frequency of circular mtDNA molecules, perhaps related to nuclear alterations during the extended period of culture.

A computer program for the management of small cosmid banks

A Fortran program has been written to permit comparative analysis of Grunstein-Hogness hybridisation data from small plasmid or cosmid banks. This program is particularly useful for restriction mapping using genome walking techniques and will facilitate the analysis of genomes in the 200 kb to 5000 kb size range.

Maize mitochondrial DNA contains a sequence homologous to the ribulose-1,5-bisphosphate carboxylase large subunit gene of chloroplast DNA

The mitochondrial genome of maize contains a DNA sequence homologous to the chloroplast gene coding for the large subunit of ribulose-1,5-bisphosphate carboxylase (LS gene). The presence in mitochondrial DNA of both coding and flanking sequences of this gene has been demonstrated first, by cross hybridization between the purified organelle DNAs and between cloned mitochondrial and chloroplast DNA sequences and second, by in vitro transcription-translation of cloned mitochondrial DNA in an E. coli cell free system where a 21,000 dalton polypeptide is synthesized that can be precipitated with antibodies to wheat ribulose-1,5-bisphosphate carboxylase. In contrast to the 12 kb chloroplast homologous sequence found in the mitochondrial genome (Stern and Lonsdale, 1982), the sequence homologous to the LS gene is unaltered in mitochondrial DNA isolated from the male sterile cytoplasms of maize. The LS gene homologous sequence in the mitochondrial genome is located some 65 kb from the 18S mitochondrial rRNA gene and approximately 20 kb from the mitochondrial DNA sequence having homology to the chloroplast 16S rRNA gene.