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

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.

Selective DNA amplification regulates transcript levels in plant mitochondria

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

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.

Mapping complementary genes in maize: positioning the rf1 and rf2 nuclear-fertility restorer loci of Texas (T) cytoplasm relative to RFLP and visible markers

There are three major groups of cytoplasmic male-sterile cytoplasms in maize; C (Charrua), S (USDA), and T (Texas). These cytoplasms can be classified by the unique nuclear genes that suppress the male-sterility effects of these cytoplasms and restore pollen fertility. Typically, plants that carry Texas (T) cytoplasm are male fertile only if they carry dominant alleles at two unlinked nuclear restorer loci,rf1 andrf2. To facilitate analysis of T-cytoplasm-mediated male sterility and fertility restoration, we have mappedrf1 andrf2 relative to closely-linked RFLP markers using five populations. Therf1 locus and/or linked visible markers were mapped in four populations; therf2 locus was mapped in two of the populations. Data from the individual populations were joined with the aid of JoinMap software. The resulting consensus maps placerf1 between umc97 and umc92 on chromosome 3 andrf2 between umc153 andsus1 on chromosome 9. Markers that flank therf1 andrf2 loci have been used to identify alleles atrf1 andrf2 in segregating populations. These analyses demonstrate the possibility of tracking separate fertility restorer loci that contribute to a single phenotype.

RFLP analysis of mitochondrial DNA from cytoplasmic male-sterile lines of pearl millet

Mitochondrial DNA (mtDNA) from 13 cytoplasmic male-sterile (cms) lines from diverse sources were characterized by Southern blot hybridization to pearl millet and maize mtDNA probes. Hybridization patterns of mtDNA digested with PstI, BamHI, SmaI or XhoI and probed with 13.6-, 10.9-, 9.7- or 4.7-kb pearl millet mtDNA clones revealed similarities among the cms lines 5141 A and ICMA 1 (classified as the S-A1 type of cytoplasm based on fertility restoration patterns), PMC 30A and ICMA 2. The remaining cms lines formed a distinct group, within which three subgroups were evident. Among the maize mitochondiral gene clones used, the coxI probe revealed two distinct groups of cytoplasms similar to the pearl millet mtDNA clones. The atp9 probe differentiated the cms line 81 A4, derived from P. glaucum subsp. monodii, while the coxII gene probe did not detect any polymorphism among the cms lines studied. MtDNA digested with BamHI, PstI or XhoI and hybridized to the atp6 probe revealed distinct differences among the cms lines. The maize atp6 gene clone identified four distinct cytoplasmic groups and four subgroups within a main group. The mtDNA fragments hybridized to the atp6 gene probe with differing intensities, suggesting the presence of more than one copy of the gene in different stoichiometries. Rearrangements involving the coxI and/or rrn18-rrn5 genes (mapped within the pearl millet clones) probably resulted in the S-A1 type of sterility. Rearrangements involving the atp6 gene (probably resulting in chimeric form) may be responsible for male sterility in other cms lines of pearl millet.

Cytoplasmic male sterility (CMS) in Lolium perenne L.: 1. Development of a diagnostic probe for the male-sterile cytoplasm

Analysis of reciprocal crosses between nonrestoring fertile genotypes and restored male-sterile genotypes of Lolium perenne confirmed the cytoplasmic nature of the sterility trait. This prompted a search for a molecular probe that could be used to distinguish between fertile and cytoplasmic male-sterile (CMS) cytoplasms. We describe the identification and cloning of a 4.5-kb BamHI-HindIII restriction fragment from the mtDNA of the CMS line. The cloned fragment (pCMS45) failed to hybridise to sequences in the mtDNA of fertile lines and was thus capable of unambiguously distinguishing between fertile and CMS cytoplasms. The use of pCMS45 as a diagnostic probe provided a simple test for positive identification of young non-flowering plants carrying the CMS cytoplasm and also permitted confirmation at the molecular level of the maternal transmission of the CMS trait suggested by the genetic data.

Variation in mitochondrial translation products in fertile and cytoplasmic male-sterile sugar beets

Intact and functional mitochondria were isolated from sugar beet plants (Beta vulgaris L.) containing normal fertile (F) or cytoplasmic male-sterile (S1-S4) cytoplasms. Incorporation of (35)S-methionine by mitochondria isolated from both roots and leaves showed approximately 20 major and ten minor translation products. Comparison of the polypeptide synthesis patterns produced by leaf mitochondria from fertile plants of three different species within the genus Beta revealed several taxonomically related differences. Contrary to this, the patterns of polypeptides synthesized by mitochondria from roots and leaves of sugar beet plants containing the F and S1-S4 cytoplasms were very similar; in the S1 and S2 cytoplasms no qualitative, and only a few quantitative, differences from the F cytoplasm were observed. Thus, in these cases, cytoplasmic male sterility in sugar beet is not correlated with the constitutive expression of variant polypeptides. In the S3 cytoplasm, however, an additional 6 kDa polypeptide was synthesized and in the S4 cytoplasm an additional 10 kDa polypeptide was observed when compared with the F cytoplasm. The expression of cytoplasmic male sterility in sugar beet may be associated with these variant polypeptides. The mitochondrial polypeptides synthesized were identical in plants with different nuclear backgrounds but with identical S1 cytoplasms. Mitochondria from plants with variants of the S4 cytoplasm in the same nuclear genotype also showed identical patterns of polypeptide synthesis, including the synthesis of the 10 kDa S4-specific polypeptide. Pulse-chase experiments did not affect the synthesis of this polypeptide.

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.

The mitochondrial genome of safflower: isolation and restriction fragment analysis of DNA from CMS and restorer lines

Mitochondria were isolated and purified from paired lines of safflower (Carthamus tinctorius L.) restorer and cytoplasmic male sterile plants using isopycnic gradient centrifugation in isoosmotic Percoll. Agarose gel electrophoresis of restriction endonuclease digested DNAs showed characteristic polymorphism. Restriction fragments representing about 75% of the mitochondrial genome were common to both the fertile and CMS plants, but differed significantly in stoichiometric amounts. The remaining 25% could be accounted for by unique restriction fragments observed in only one or the other plant types.

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.

Cytoplasmic male sterility in beta is associated with structural rearrangements of the mitochondrial DNA and is not due to interspecific organelle transfer

Chloroplast (ct) and mitochondrial (mt) DNAs from four cytoplasmic male sterile (cms) and 22 normal fertile sugar beet lines and accessions of wild beets from the genus Beta have been compared with restriction analyses and Southern hybridizations. We have used restriction analyses of ctDNA as a phylogenetic marker to confirm the taxonomic relationships between the different cytoplasms. According to the ctDNA data, all four cms cytoplasms belong to the same taxonomic section, Beta. Restriction patterns of ct and mtDNA from fertile accessions produced analogous trees of similarity and showed a close correlation between the organellar DNA diversity and the accepted taxonomic classification of the species studied. However, the mt-DNA restriction profiles of the four cms types differed dramatically from each other and from those of all fertile accessions from the genus. No indication of cytoplasmic introgression was found in any of the four investigated cms types. Southern hybridization to mtDNA revealed variant genomic arrangements in the different fertile and cms cytoplasms, indicating that rearrangement of the mitochondrial genome is a common denominator to the different cms systems in Beta. It may, indeed, be a common property to spontaneously occurring cms in all or most species.

The molecular basis of genetic diversity among cytoplasms of Triticum and Aegilops : 7. Restriction endonuclease analysis of mitochondrial DNAs from polyploid wheats and their ancestral species

Many related species and strains of common wheat were compared by matching differences among their mitochondrial genomes with their "parent" nuclear genomes. We examined three species of Aegilops, section Sitopsis (Ae. bicornis, Ae. sharonensis, and Ae. speltoides), emmer wheat (Triticum dicoccoides, T. dicoccum, and T. durum), common wheat (T. spelta, T. aestivum, and T. compaction), and timopheevi wheat (T. araraticum, T. timopheevi, and T. zhukovskyi). A single source of the cytoplasm was used in all the species, except Ae. speltoides (two sources), T. araraticum (two), and T. aestivum (three). Following restriction endonuclease analyses, the mitochondrial genomes were found to comprise seven types, and a dendrogram showing their genetic relatedness was constructed, based upon the percentage of common restriction fragments. MtDNAs from T. dicoccum, T. durum, T. aestivum, and T. compactum yielded identical restriction fragment patterns; these differed from T. dicoccoides and T. spelta mtDNAs in only 2.3% of their fragments. The fragment patterns of T. timopheevi and T. zhukovskyi were identical, and these differed from T. araraticum mtDNA by only one fragment. In both the emmer-dinkel and timopheevi groups, mitochondrial genome differentiation is evident, suggesting a diphyletic origin of each group. MtDNAs from four accessions of the Sitopsis species of Aegilops differ greatly from one another, but those of Ae. bicornis, Ae. sharonensis, and Ae. searsii, belonging to the same subsection Emarginata, are relatively similar. MtDNAs of timopheevi species are identical, or nearly so, to those of Ae. speltoides accession (09), suggesting that the latter was the cytoplasm donor to the former, polyploid group. The origin of this polyploid group seems to be rather recent in that the diploid and polyploid species possess nearly identical mitochondrial genomes. We cannot determine, with precision, the cytoplasm donor to the emmer-dinkel group. However, our results do suggest that mitochondrial DNAs show larger evolutionary divergence than do the ctDNAs from these same strains.

Nuclear genotype affects mitochondrial genome organization of CMS-S maize

A WF9 strain of maize with the RD subtype of the S male-sterile cytoplasm (CMS-S) was converted to the inbred M825 nuclear background by recurrent backcrossing. The organization of the mitochondrial genomes of the F1 and succeeding backcross progenies was analyzed and compared with the progenitor RD-WF9 using probes derived from the S1 and S2 mitochondrial episomes, and probes containing the genes for cytochrome c oxidase subunit I (coxI), cytochrome c oxidase subunit II (coxII) and apocytochrome b (cob). Changes in mitochondrial DNA (mtDNA) organization were observed for S1-, S2-, and coxI-homologous sequences that involve loss of homologous restriction enzyme fragments present in the RD-WF9 progenitor. With the coxI probe, the loss of certain fragments was accompanied by the appearance of a fragment not detectable in the progenitor. The changes observed indicate the effect of the nuclear genome on the differential replication of specific mitochondrial subgenomic entities.

Mitochondrial genome diversity among cultivars of daucus carota (ssp. sativus) and their wild relatives

Restriction fragment patterns of mitochondrial DNAs (mtDNAs) from 13 carrot cultivars (Daucus carota ssp. sativus), wild carrot (ssp. carota), ssp. gummifer, and D. capillifolius were compared with each other using four restriction endonucleases. The mtDNAs of the 13 carrot cultivars could be classified into three distinct types - I, II and III - and were also clearly distinguishable from the mtDNAs of wild carrot (type IV), gummifer (V) and D. capillifolius (VI). The proportions of common restriction fragments (F values) shared by two of the three mtDNA types (I, II and III) of carrot cultivars were approximately 0.5-0.6. The F values were 0.4-0.5 for mitochondrial genomes between wild carrot, ssp. gummifer and D. capillifolius. The mitochondrial genomes between wild carrot and the carrot cultivars showed closer homologies those between wild carrot, ssp. gummifer, and D. capillifolius. The diversity of the mitochondrial genomes among the carrot cultivars is too high to presume that it was generated from the cytoplasm of only one common ancestor during the relatively short history of carrot breeding. These results suggested that the three types of cytoplasms found in the carrot cultivars might have existed in a prototype of D. carota in pre-historical times.

Variant mitochondrial protein and DNA patterns associated with cytoplasmic male-sterile lines of Nicotiana

Variation in mitochondrial protein synthesis and genome organization was investigated. Three different alloplasmic cytoplasmic male-sterile Nicotiana tabacum cultivars, carrying N. repanda, N. suaveolens or N. debneyi cytoplasm, were analysed together with corresponding male-fertile parental and restored material. Although several differences were detected in the proteins synthesized by isolated mitochondria from the male-sterile and male-fertile plants, most of these were related to the origin of the mitochondria. However, a 23 kD protein was synthesized in the male-sterile cultivar carrying N. debneyi mitochondria, but not in other lines containing this cytoplasm. This protein was also present in the male-fertile parent containing N. tabacum mitochondria. Only the enhanced production of a 30 kD protein in the lines carrying mitochondria from N. repanda or N. debneyi was exclusively correlated with CMS. This protein was not present in any of the corresponding male-fertile parental and restored lines. Restriction enzyme analysis of mitochondrial DNA revealed a difference in abundance of a 5.6 kb XhoI fragment between lines containing N. debneyi mitochondria. No rearrangements of mitochondrial DNA was found between male-fertile and male-sterile lines carrying N. repanda or N. suaveolens cytoplasm. These results might indicate that CMS in alloplasmic Nicotiana cultivars is caused by alterations in the expression of mitochondrial genes, rather than by induced changes in the genome.

Molecular analysis of the mitochondrial genome of Helianthus annuus in relation to cytoplasmic male sterility and phylogeny

A circular supercoiled mitochondrial DNA plasmid P1 (1.45 kb) is shown in both normal fertile plants of Helianthus annuus, and some cytoplasmic male sterile lines (CMS A and CMS P). In contrast, no plasmid is found in some other types of CMS C, I, B and K. A circular supercoiled DNA (P2) of higher molecular weight (1.8 kb) is observed in CMS F. The mitochondrial plasmid P1 was cloned, nick-translated and hybridized with native mitochondrial DNA from different lines of male fertile, CMS or wild Helianthus. No sequence homology has been detected between plasmid DNA P1 and high molecular weight mitochondrial DNA in any line examined. A slight hybridization occurs between plasmids P1 and P2. Thus, there is no apparent relationship between mitochondrial plasmid DNA and CMS or Helianthus species. On the contrary, each Helianthus CMS and male fertile strain can be characterized by digestion fragment patterns (Sal I and Bgl I). Analysis of mitochondrial DNA from wild Helianthus strains indicated a relation between some CMS and the strain from which they were maternally derived, as for example CMS I and H. annuus ssp lenticularis and CMS F and H. petiolaris fallax. On the basis of restriction endonuclease patterns, a CMS phylogenic tree is proposed which illustrates a molecular polymorphism in the mitochondrial genome of Helianthus.

Mitochondrial DNA modifications associated with cytoplasmic male sterility in rice

Mitochondrial DNA was isolated from fertile and cytoplasmic male sterile lines of rice. Restriction analysis showed specific modifications in the male sterile cytoplasm. In addition to the major mitochondrial DNA, three small plasmid-like DNA molecules were detected by agarose gel electrophoresis in both cytoplasms. An additional molecule was specifically found in the sterile cytoplasm. These mitochondrial DNA modifications support the hypothesis of the mitochondrial inheritance of the cytoplasmic male sterility in rice.

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 molecular basis of genetic diversity among cytoplasms of Triticum and Aegilops : 5. Mitochondrial genome diversity among Aegilops species having identical chloroplast genomes

Restriction fragment patterns of mtDNA isolated from the cytoplasm of three groups of Aegilops species (or accessions) which are known to carry the identical chloroplast genome but distinctly different cytoplasmic genomes (plasmons) have been analysed using five restriction endonucleases. Two to four different mitochondrial genomes are found in each group, between which the percent common restriction fragments amounts to 86-97%, whereas the same parameter obtained between mitochondrial genomes of the different groups ranges from 34 to 42%. Mitochondrial genome diversity is far more extensive than the chloroplast genome diversity, and the former provides a useful key for the phylogenetic relationships between cytoplasms of closely related species or even different accessions of the same species. The mitochondrial and chloroplast genome differentiation most certainly accounts for the plasmon variability known in this genus.

Nuclear-mitochondrial interactions in cytoplasmic male-sterile sorghum

Variation in mitochondrial genome organization and expression between male fertile and sterile nuclear-cytoplasmic combinations of sorghum has been examined. Cytoplasmic genotypes were classified into eleven groups on the basis of restriction endonuclease digestion of mitochondrial DNA (mtDNA) and five groups on the basis of mitochondrial translation products. These cytoplasms were further characterized by hybridization of specific gene probes to Southern blots of EcoRI digested mtDNA, and identification of the fragment location of four mitochondrial genes. Variation was observed in the genomic location and copy number of the F1 ATPase α-subunit gene, as well as the genomic location and gene product of the cytochrome c oxidase subunit I gene. The effect of nuclear genotype on mitochondrial genome organization, expression and the presence of two linear plasmid-like mtDNA molecules was examined. Our results indicate that nuclear-mitochondrial interactions are required for regulation of mitochondrial gene expression. When a cytoplasm is transferred from its natural to a foreign nuclear background some changes in the products of in organello mitochondrial protein synthesis occur. In a number of cytoplasmic genotypes these changes correlate with the expression of cytoplasmic male sterile phenotype, suggesting a possible molecular basis for this mutation.

DNA synthesis in purified maize mitochondria

We have developed an in organelle DNA synthesis system using isolated mitochondria from maize. The organelles used in this assay are shown to be intact by a number of criteria. Both the high molecular weight components and the smaller plasmid-like components of the mitochondrial genome are used as templates; however, the plasmid-like elements are relatively more active as templates. The termini of the linear plasmids--S-1, S-2 and the 2.3 kbp plasmids--are more highly labelled than internal regions, probably as a result of filling in of gaps at the termini mediated by a DNA polymerase or to exonuclease degradation of the 3' OH termini, with subsequent filling in. Although most of the DNA synthesis observed in this system most likely results from this type of synthesis at DNA nicks or termini, a small amount of specific, potentially replication-associated, synthesis is also detected.

Extrachromosomal DNA of pea-root (Pisum sativum) has repeated sequences and ribosomal genes

Restriction endonuclease digestion and Southern blotting procedure were used to determine differences between extrachromosomal, nuclear, plastid, and mitochondrial DNAs from meristematic cells of cultured pea roots.Extrachromosomal and nuclear DNA are highly methylated and neither DNA is homologous to plastid or mitochondrial DNA. Hybridization of extrachromosomal DNA to nuclear DNA indicated that extrachromosomal DNA differed quantitatively from total nuclear DNA in repetitive sequences. Cloned rDNA showed that extrachromosomal DNA contains rRNA genes but the hybridization signal indicated that the copy number was less than that expected if the molecules were amplified. These and cytological findings suggest that extrachromosomal DNA is involved in or a product of genomic changes associated with the onset of differentiation by precursor cells of vascular parenchyma and the root cap.

Maize mitochondria synthesize organ-specific polypeptides

We detected both quantitative and qualitative organ-specific differences in the total protein composition of mitochondria of maize. Labeling of isolated mitochondria from each organ demonstrated that a few protein differences are due to changes in the polypeptides synthesized by the organelle. The synthesis of developmental stage-specific mitochondrial polypeptides was found in the scutella of developing and germinating kernels. The approximately 13-kDa polypeptide synthesized by mitochondria from seedlings of the Texas (T) male-sterile cytoplasm was shown to be constitutively expressed in all organs of line B37T tested. Methomyl, an insecticide known to inhibit the growth of T sterile plants, was shown to be an effective inhibitor of protein synthesis in mitochondria from T plants.

Molecular analysis of mitochondria from a fertility restorer line of maize

Inbred line Ky21 carries nuclear genes which restore fertility to all three cytoplasmic male sterile (cms) types of maize: T, C and S. By substituting the Ky21 cytoplasm into a nuclear background lacking all of the nuclear restorer genes, we have demonstrated that Ky21 contains a fertile (normal) cytoplasm. Gel electrophoresis of mitochondrial DNA from Ky21 demonstrated an approximately 2.1 kb plasmid and no evidence for a 2.35 kb plasmid found in many normal cytoplasms of North American lines of maize. A 2.1 kb plasmid had been reported to be diagnostic for the T-type cms. However, the restriction endonuclease digestion pattern of Ky21 mtDNA more closely resembled that of normal lines than T-cms. Furthermore, mitochondria of Ky21 plants did not synthesize a 13 kilodalton polypeptide, which has only been found to be synthesized by T-type mitochondria. From these molecular criteria, as well as from the genetic analysis, we conclude that the mitochondria of the Ky21 universal restorer line are normal. In having a shorter form of a linear mtDNA plasmid, Ky21 resembles cytoplasms found in Mexican races of maize.

Quantitative variation in components of the maize mitochondrial genome between tissues and between plants with different male-sterile cytoplasms

The amounts of a 1.9 kb mitochondrial plasmid relative to sequences in another mitochondrial DNA replicon and also to nuclear ribosomal DNA sequences have been compared in maize leaves and anthers. Similar comparisons have been made between plants with the same nuclear genotype but containing normal, S, or T cytoplasms. The ratio of 1.9 kb plasmid to nuclear rDNA is lower in plants with normal cytoplasm than in plants with S or T cytoplasm. It also differs between leaves and anthers. Furthermore, the relative concentration of the mitochondrial DNA sequences belonging to different replicons differs between leaves and anthers. It is concluded that components of different mitochondrial replicons are not maintained in fixed ratios during development and that the concentration of the 1.9 kb plasmid is regulated, in part, by cytoplasmically-inherited determinants. The 1.9 kb plasmid is absent from lines with the Vg cytoplasm, but related sequences are found in the maize nuclear genome.

Molecular analysis of the inheritance and stability of the mitochondrial genome of an inbred line of maize

We have investigated the inheritance of the mitochondrial DNA (mtDNA) restriction endonuclease digestion patterns of maize inbred line B37N in individual plants and pooled siblings in lineages derived from five separate plants in the third generation following successive self-pollinations. The restriction fragment patterns of the different mtDNA samples were compared after digestion with five endonucleases. No differences were visible in the mobilities of the 199 fragments scored per sample. Hybridization analysis with two different cloned mtDNA probes, one of which contains homologies to a portion of the S2 plasmid characteristic of cms-S maize, failed to reveal cryptic variation. The apparent rate of genomic change in maize mtDNA from inbred plants appears to be very slow, compared with the faster rates of change seen in maize tissue cultures and with the documented rapid rate of inter- and intraspecific variation for mammalian mtDNA.

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.

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.