Cloning of mtDNA fragments homologous to mitochondrial S2 plasmid-like DNA in maize

Summary Mitochondria from S-type cytoplasmic male-sterile maize contain two small DNA species, S1 and S2, which are absent from other fertile and male-sterile cytoplasms. These species have been cloned in plasmid pBR322 by the homopolymer extension method. Probes made with these recombinant plasmids have been used to establish the homology between high molecular weight mitochondrial DNAs of fertile and male-sterile cytoplasms, and small mitochondrial plasmid-like molecules. Hybridization and mapping data show that S2 DNA copies are homologuous with sequences of the normal mitochondrial genome. A comparison of physical maps of different isolated mtDNA fragments indicates a heterogeneous arrangement of S2 sequences in the mtDNA population of normal fertile maize cytoplasm. The origin of this heterogeneity is discussed.     

Classification of normal and male-sterile cytoplasms in maize. I. Electrophoretic analysis of variation in mitochondrially synthesized proteins

Male-sterile cytoplasms of maize have previously been classified into three groups (T, S and C) according to their fertility ratings in various inbred backgrounds. In earlier studies, mitochondria from three male-sterile cytoplasms, representing each of these three groups, have been found to synthesize characteristic variant polypeptides that distinguish them from each other and from those of normal (N) cytoplasm. In order to determine the extent of cytoplasmic variation, we have now analyzed the translation products of mitochondria from 28 additional cytoplasmic sources. The results show that on this basis 18 of the cytoplasms are identical to the USDA (S) cytoplasm, three are identical to the Texas (T) cytoplasm and two are identical to the C cytoplasm. The five remaining cytoplasms are indistinguishable from normal, male-fertile (N) cytoplasm. Our classification of the cytoplasms is in general agreement with those based on fertility restoration. However, of three cytoplasms that have previously remained unclassified, two (B and D) have now been assigned to the S group and one (LF) to the N group. No heterogeneity in mitochondrial translation products was detected within the normal or any of the three male-sterile groups. The usefulness of the analysis of mitochondrial translation products as a method for classifying normal and male-sterile cytoplasms is discussed.     

Diversity among male-sterility-inducing and male-fertile cytoplasms of onion

Hybrid-onion (Allium cepa) seed is produced using systems of cytoplasmic-genic male sterility (CMS). Two different sources of CMS (S and T cytoplasms) have been genetically characterized. Testcrosses of N-cytoplasmic maintaining and restoring genotypes to S and T cytoplasmic lines demonstrated that different alleles, or loci, restore male fertility for these two male-sterile cytoplasms. Other sources of CMS have been used or reported in Europe, Japan and India, and their relationships to S and T cytoplasms are not clear. Restriction fragment length polymorphisms were identified in the organellar genomes among commercially used male-sterile cytoplasms from Holland, Japan and India, and were compared to S and T cytoplasms. Mitochondrial DNA diversity among 58 non-S-cytoplasmic open-pollinated onion populations was also assessed. All five putative CMS lines selected from the Indian population Nasik White Globe were identical to S cytoplasm for all polymorphisms in the chloroplast genome, and always possessed the same-sized mitochondrial fragments as S cytoplasm. T cytoplasm, the male-sterile cytoplasm used to produce the Dutch hybrid Hygro F₁, and two sources of CMS from Japan, were similar and showed numbers of mitochondrial polymorphisms similar to those observed among the 58 non-S-cytoplasmic open-pollinated populations. This research demonstrates that the same, or very similar, male-sterile cytoplasms have been independently isolated and exploited for hybrid-seed production in onion. Received: 27 October 1999 / Accepted: 12 February 2000     

玉米不育系及其保持系线粒体atp6基因转录本编辑位点研究

以玉米同核异质细胞质雄性不育系T黄早四、C黄早四、S黄早四以及保持系N黄早四为材料, 比较研究了供试材料小孢子发育到单核期的线粒体atp6基因转录本保守区域的编辑位点。结果表明, DNA序列在T、C、S 3种胞质中完全一致, 与N胞质相比除在27、28核苷酸处不同外, 其余均一致, 而各胞质cDNA序列却不尽相同。DNA和cDNA序列比较显示: atp6基因转录本保守区域内, N、S胞质中均存在19个编辑位点, T胞质存在22个, C胞质存在20个, 它们相同的编辑位点有18个。大多数编辑位点都发生在密码子的第一、二位点上, 可改变氨基酸的种类。18个相同的编辑位点大都为完全编辑, 其中第1位点在各胞质中为部分编辑, 第19位点除在N胞质中为完全编辑外其余胞质都为部分编辑。而各胞质特有编辑位点均以部分编辑的形式出现。由此可见, 在玉米中atp6基因RNA编辑不仅具有序列特异性, 同时还受到胞质背景的影响。通过分析还可看出, 编辑的C残基前一个碱基多为嘧啶类碱基, 编码氨基酸Ser和Pro的密码子较其他类的密码子更易受到编辑, 且植物RNA的编辑有着改变蛋白质疏水性、增加物种间保守性的倾向。     

Heterogeneity of Maize Cytoplasmic Genomes among Male-Sterile Cytoplasms

Maize mitochondrial and chloroplast DNA's were prepared from normal (fertile) lines or single crosses and from members of the T, C, and S groups of male-sterile cytoplasms. Restriction endonucleases HindIII, BamI, EcoRI, and SalI were used to restrict the DNA, and the resultant fragments were electrophoresed in agarose gels. The results show that the N (fertile), T, C, and S cytoplasms each contained distinct mitochondrial DNA (mtDNA). These distinctive patterns were unaffected by nuclear genotype. No evidence of paternal inheritance of mtDNA was observed. Chloroplast DNA (ctDNA) from the N, C, and T cytoplasms was indistinguishable by HindIII, SalI, or EcoRI endonuclease digestion. The S cytoplasm ctDNA, however, was slightly different from that of other cytoplasms, as indicated by a slight displacement of one band in HindIII digests. The molecular weight of maize ctDNA was estimated to be as high as 88 x 10⁶. Estimates of the minimum molecular weight of maize mtDNA ranged from 116–131 x 10⁶, but the patterns were to complex for an unambiguous determination. Based on HindIII data, a comparison of the molecular weight of mtDNA bands common to the N, T. C, and S cytoplasms suggests that C cytoplasm most closely resembles N cytoplasm. The T and S sources are more divergent from the C and N cytoplasms. These results indicate a possible gradation of relatedness among male-sterile cytoplasms. The marked variation in mtDNA, with apparently less variation in ctDNA, represents circumstantial, but compelling, evidence that mtDNA may be involved in the male sterility and disease susceptibility traits in maize.     

Stoichiometric differences in DNA molecules containing the atpA gene suggest mechanisms for the generation of mitochondrial genome diversity in maize

Four genomic arrangements of the maize mitochondrial atpA gene (encoding the α subunit of the F₁ ATPase), have been characterized. Most N (fertile) and S (male-sterile) cytoplasms contain two atpA arrangements of equal abundance. Prolonged exposure of blots of maize mitochondrial DNA probed with atpA-specific sequences show that cytoplasms previously reported to lack one of the atpA arrangements do contain the second arrangement but at low levels. Similarly, restriction fragments containing the atpA gene previously thought unique to male-sterile S and T cytoplasms are present in low abundance in fertile cytoplasms. These observations suggest that fertile and male-sterile cytoplasms of maize may be more closely related than previously thought, and suggest possible mechanisms to explain the observed mitochondrial genome diversity.     

THE CYTOLOGY OF POLLEN ABORTION IN S CYTOPLASMIC MALE-STERILE CORN ANTHERS

The anther development of the S male-sterile cytoplasm and the fertile maintainer (N) cytoplasm versions of corn inbred W182BN and the restored S cytoplasm version of inbred NY821LERf was studied by light and electron microscopy and compared to pollen abortion in the C and T types of male-sterile cytoplasms. The S anthers did not deviate from the non-male sterile (N) anthers until a very late stage of pollen development. Tapetal cells developed and disappeared normally in the S version which differentiates this cytoplasm from the C and T types. Although some modified membranous structures were seen in a higher frequency in the large vacuole of the sterile S pollen than in the N and restored S counterparts, the mitochondria and other organelles in the S pollen appeared normal up to the time of pollen abortion. Pollen abortion in the S cytoplasm did not occur until the developing pollen was nearly mature. At this time the pollen grains disintegrated abruptly but other anther tissues appeared unaltered. The male sterility of S plants appeared to be determined by the pollen itself without external influence from the tapetum.     

Classification of Normal and Male-Sterile Cytoplasms in Maize. II. Electrophoretic Analysis of DNA Species in Mitochondria

Mitochondrial DNA preparations were made from 31 maize lines carrying different sources of cytoplasm in the same nuclear genetic background. The DNAs were analyzed by agarose gel electrophoresis. A number of discrete low molecular weight bands were present in all lines. However, only four different DNA banding patterns were observed. These were correlated with the N, T, S and C cytoplasms defined by nuclear fertility restorer genes. Of the 31 cytoplasmic sources examined, six possessed DNA species characteristic of N cytoplasms, four possessed DNA species characteristic of T cytoplasm, 19 possessed DNA species characteristic of S cytoplasm and two possessed DNA species characteristic of C cytoplasm. This classification is in complete agreement with that based on mitochondrial translation products reported in the accompanying paper. No within-group heterogeneity was observed in the DNA banding patterns, indicating a lack of cytoplasmic variation within the four cytoplasmic groups. Attributes of the various methods available for classifying maize cytoplasms are compared and discussed.     

Sequence analysis of a chloroplast intergenic spacer for phylogenetic estimates in Allium section Cepa and a PCR-based polymorphism detecting mixtures of male-fertile and male-sterile cytoplasmic onion

Restriction-enzyme analysis of the chloroplast (cp) DNA yielded maternal phylogenies supporting a close phylogenetic relationship among normal (N) male-fertile and male-sterile (S) cytoplasmic bulb onion (Allium cepa), Allium altaicum, Allium fistulosum, Allium galanthum, Allium roylei, and Allium vavilovii. The S cytoplasm of onion is most likely an alien cytoplasm introduced in antiquity into onion populations. We previously showed that size differences in an intergenic spacer in the cp DNA distinguish N and S cytoplasms of onion. We cloned and sequenced this intergenic spacer from the N and S cytoplasms of onion, A. altaicum, A. fistulosum, A. galanthum, Allium pskemense, Allium oschaninii, A. roylei, and Allium ampeloprasm (outgroup) to identify the nature of previously described RFLPs and to develop a PCR-based marker revealing N-cytoplasmic contamination of S-cytoplasmic hybrid seed lots. Phylogenies based on restriction-enzyme analysis of the entire cp DNA were similar, but not identical, to those based on sequence divergence in this intergenic region. Received: 29 November 1999 / Accepted: 28 April 2000     

DNA polymorphism in Allium cepa cytoplasms and its implications concerning the origin of onions

Summary Mitochondrial and chloroplast DNA was isolated from fertile and cytoplasmic male sterile cultivars of cultivated onions. Restriction fragment length polymorphism led to the distinction between cytoplasms S and M. Mitochondrial DNA patterns from S cytoplasms appeared dentical and characterized mostly male sterile lines. An open-pollinated variety was found to bear this cytoplasm and thought to be the origin of S types. Mitochondrial DNA patterns from M cytoplasms were subdivided into four types, M₁ and M₂ corresponding to normal N cytoplasm, M₃ and M₄ probably corresponding to T cytoplasms. S and M cytoplasms were also distinguished by chloroplast DNA restriction patterns. Our results confirm previous genetic distinction between S, N and T cytoplasms.     

A protein specific to mitochondria from S-type male-sterile cytoplasm of maize is encoded by an episomal DNA

Mitochondria of S-type cytoplasmic male sterile maize contain two linear double-stranded DNA molecules, S1 and S2. Two open reading frames (ORF1 and ORF2) are present in S2 DNA. Fragments from ORF1 were inserted into plasmids to achieve expression in Escherichia coli. Cells transformed with recombinant plasmids produced mRNA which hybridized with ORF1 and corresponding polypeptides were synthesized by in vivo and in vitro systems. Antiserum against a lacZ/S2 fusion protein precipitated the anticipated polypeptides from transformed E. coli cells and was therefore used to detect homologous peptide sequences in protein preparations of mitochondria from different maize cytoplasms. The antiserum detected a protein of 125 000 M_r present in mitochondria from male sterile B73S but absent from the fertile B73N cytoplasm.     

Rapid hybridization-based assays for identification by DNA probes of male-sterile and male-fertile cytoplasms of the sugar beet Beta vulgaris L.

Summary Methods are described whereby hybridization of mitochondrial (mt) DNA with different DNA probes can definitely distinguish male-fertile and and male-sterile (cms) cytoplasms of sugar beet Beta vulgaris L. We have developed two types of miniassays. (1) Comparative methods requiring the isolation and restriction of total cellular DNA, hybridization with cloned mtDNA fragments from either fertile or male-sterile cytoplasms, and comparison of the hybridization patterns to the fertile-and sterile-specific patterns of mtDNA of sugar beet for the given mtDNA probe. For these analyses, we routinely used 1 g of plant material to determine the type of cytoplasm. (2) Noncomparative (plus-minus) methods requiring neither the isolation of pure DNA nor restriction, electrophoresis, or Southern blotting. Instead, alkaline-SDS plant extracts from as little as 50 mg of plant material were dot-blotted and hybridized with fertile-specific (mitochondrial minicircular DNA) and/or cms-specific probes (consisting of a 2.3-kb mtDNA sequence exclusively occurring in the cms cytoplasm). The assays are simple to perform, give definitive results, are nonde-structive to the plants, and may be used in mass screening of sugar beet populations for hybrid production or in in vitro culture processes.     

Fusion of male-sterile tobacco causes modifications of mtDNA leading to changes in floral morphology and restoration of fertility in cybrid plants

Protoplasts from male-sterile Nicotiana tabacum cultivars with cytoplasms of N. suaveolens, N. bigelovii and N. undulata were fused in different pairwise combinations. Cybrid plants were obtained and categorized according to their flower morphologies into groups as parental male-sterile types, recombined biparentals, novel male-steriles and male fertiles. Restriction enzyme analyses and DNA gel blot hybridizations of the mitochondrial DNA (mtDNA) of these cybrid plants revealed that all plants with parental male-sterile morphologies had banding patterns identical to the parental patterns, whereas all cybrids with flower morphologies different from their parents had novel patterns. Several restriction fragments were found to be unique to the mtDNA of male-fertile plants with perfectly restored stamen morphologies when compared to the mtDNA from cybrid plants with incomplete restoration. MtDNA gel blot hybridization analysis of fertile plants revealed that the probe for atpA hybridized to two restriction fragments, one from each parent. Further, fertile plants with complete stamen restoration lacked an expressed sequence in the 3'flanking region of atpA , in contrast to both male-sterile parents.     

Studies on wheat mitochondrial DNA organization. Comparison of mitochondrial DNA from normal and cytoplasmic male sterile varieties of wheat

The mitochondrial genome of fertile, male-sterile and restored cytoplasm lines of wheat has been studied by means of recombinant DNA and hybridization techniques. Using cloned fragments of mitochondrial DNA (mtDNA) from fertile wheat cytoplasms as probes, about 40% of the genome is shown to have a differential hybridization pattern. The use of wheat rRNA and corn cytochrome oxidase subunit II probes indicates that duplication and rearrangement of genes or parts of genes may account for the differences observed. DNA synthesis in isolated mitochondria showed neither preferential labeling of part of the mtDNA nor the presence of extrachromosomal elements.