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

Summary 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.     

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.     

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.     

Characterization of anther differentiation in cytoplasmic male sterile maize using a specific isozyme system (esterase)

Summary During anther development, characterized in maize plants with N cytoplasm, certain esterase isozymes in non-microspore cells decrease in amount with anther age and new isozymes appear in the developing microspores. In anthers from male sterile plants with cms T or cms C cytoplasm, neither of these changes in esterase patterns occurred. In anthers from plants with cms S cytoplasm, the decrease in the esterases of non-microsporogenous cells was observed but not the appearance of microspore esterases. In lines carrying cms S cytoplasm and nuclear restorer genes, esterase changes during anther development were as in normal fertile anthers. These results are discussed with respect to the phenomenon of cytoplasmic male sterility in the different maize genotypes.     

RAPD Comparison Study on Mitochondrial DNA of the D2 Cytoplasmic Male Sterile (CMS) Line with K-, V-and T-type CMS Lines in Wheat

A new line of cytoplasmic male sterile (CMS) wheat ( Triticum aestivum L. ) named msD2-CA8057 (briefly as D:) was compared with K-, V- and T-type CMS lines by mitochondrial DNA (mtDNA) RAPD analysis. It was revealed that the mtDNA of this D2 line was different from that of the other three types although differences were also found between the K-, V- and T-type lines themselves. This result provided some evidences at the molecular level for the identification of the cytoplasm of this D2 line as a new type of CMS line. In the experiment the authors also found polymorphism between two CMS lines, which had the same source of T-type cytoplasm but had different nuclear background. This was the first time to provide direct evidence about the mtDNA mutation in T-type CMS wheat lines during the routine backcross process. Such changes are most likely resulted from the influence of different nuclear background.     

Cloning and characterization of a linear 2.3 kb mitochondrial plasmid of maize

Summary A linear 2.3 kb DNA molecule found in maize mitochondria was cloned into pUC8. A natural deletion of this plasmid, found in cmsT and some N (fertile) types of maize plants, was mapped to one end of the plasmid. A minor sequence homology to S-2, another linear mitochondrial plasmid, was detected, as well as more significant sequence homology with chloroplast and maize nuclear DNA. Hybridization to teosinte mitochondrial DNA (mtDNA) revealed the presence of part of the maize plasmid in the high molecular weight mtDNA of the maize relatives. RNA dot hybridization indicates that the plasmid is transcribed in mitochondria. The termini of the 2.3 kb linear plasmid contain inverted repeated sequences; of the first 17 nucleotides of the termini, 16 are identical to the terminal inverted repeats of the linear S plasmids found in the mitochondria of cmsS maize plants.     

Molecular characterization of a new type of cytoplasmic male sterile sugar beet

A line (named Cl) of cytoplasmic sterility of sugar beet whose cytoplasm derived from Betacicla Turkey was obtained by interspecific hybrid. Its cytoplasm and a spontaneous male sterile cytoplasm from wild beet Beta maritima (named M) were compared with that of Owen's sterile line (S-cms) and a common maintainer of them named N was used as control. RFLP and RAPD methods were mainly used in our experiments. The restriction fragment patterns of mtDNAs were found to be likely but for a few of specific low-lighted electrophoresis bands in Cl. The results of Southern hybridization of six heterogeneous mitochondrial genes as probes to digests of mtDNAs by six restriction enzymes showed to be analogous between S and M lines. But the Cl mtDNA was sorted out by hybridization of atpA probe. Difference of low-molecular-weight mitochondrial DNAs was found among the three sterile lines. Three RNA molecules weighing about 4.2kb stably existed in Cl mitochondria. Our results of RAPD also supported that the Cl cytoplas     

Polymorphism of mitochondrial DNA ‘S’ regions among normal cytoplasms of maize

Genomic variation in S1 and S2 homologous sequences, defined as the S regions, were examined in mitochondrial DNAs of 12 normal cytoplasm maize lines collected in the United States. Three genomic variants were detected among the 12 cytoplasms, eight of which were identical to the Wf9 model structure. Hybridization data with S1 and S2 DNAs and with two cosmids spanning these regions were consistent with the concept that S1 and S2 sequences are found in each normal cytoplasm. Three variations of the S1 region were established; the Wf9 structure, a second group consisting of F6, A188, and W182BN, and a third, Black Mexican. Genome structure was conserved through the S2 region in all lines examined. None of the cytoplasms included complete copies of S1; the 1400 bp repeat characteristic of S1 and S2 was absent in the S1 region of all lines. A 2.1 kb linear DNA was observed instead of a 2.3 kb DNA in F6, A188, and W182BN. Integrated copies of S1 and S2 sequences may be a constituitive characteristic of normal, male-fertile maize cytoplasms.     

Comparison of restriction endonucleases and sources of probes for their efficiency in detecting restriction fragment length polymorphisms in lettuce (Lactuca sativa L.)

Summary 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.Cooperative Investigations of Agricultural Research Service, U.S. Department of Agriculture, and Institute of Food and Agricultural Sciences, University of FloridaMention of trademark, proprietary product, or vendor does not constitute a guarantee of the product by the U.S. Department of Agriculture and does not imply its approval to the exclusion of other products or vendors that may also be suitable     

A new source of cytoplasmic male sterility in maize induced by the nuclear gene,iojap

Summary Cytoplasmic male sterility (cms) was found in plants derived from the F₂ progeny of fertile, normal cytoplasm plants of the inbred R181 pollinated with a genetic stock carrying the recessive nuclear gene, iojap. The male sterile plants were maintained by back-crossing with the inbred W182BN which maintains all known sources of cytoplasmic male sterility. The new male sterile progeny were found to exhibit stable male sterility under field conditions in two environments. However, they were partially fertile in the hot, dry summer of 1983 at Aurora, NY. It was found that these lines were restored by lines that characteristically restore cms S group cytoplasms. Pollen phenotype studies indicated that the restoration was gametophytic in nature, also characteristic of the cms S group. Agarose gel electrophoresis of undigested mitochondrial DNA (mtDNA) from these steriles indicated that these lines have the S-1 and S-2 episomes characteristic of the cms S group. Restriction endonuclease digest patterns of mtDNA from these sterile lines digested with BamH I indicated that these steriles fit into the CA subgroup of the cms S group. The new source of cms has been designated cms Ij-1.     

Mitochondrial aldehyde dehydrogenase activity is required for male fertility in maize

Some plant cytoplasms express novel mitochondrial genes that cause male sterility. Nuclear genes that disrupt the accumulation of the corresponding mitochondrial gene products can restore fertility to such plants. The Texas (T) cytoplasm mitochondrial genome of maize expresses a novel protein, URF13, which is necessary for T cytoplasm-induced male sterility. Working in concert, functional alleles of two nuclear genes, rf1 and rf2, can restore fertility to T cytoplasm plants. Rf1 alleles, but not Rf2 alleles, reduce the accumulation of URF13. Hence, Rf2 differs from typical nuclear restorers in that it does not alter the accumulation of the mitochondrial protein necessary for T cytoplasm-induced male sterility. This study established that the rf2 gene encodes a soluble protein that accumulates in the mitochondrial matrix. Three independent lines of evidence establish that the RF2 protein is an aldehyde dehydrogenase (ALDH). The finding that T cytoplasm plants that are homozygous for the rf2-R213 allele are male sterile but accumulate normal amounts of RF2 protein that lacks normal mitochondrial (mt) ALDH activity provides strong evidence that rf2-encoded mtALDH activity is required to restore male fertility to T cytoplasm maize. Detailed genetic analyses have established that the rf2 gene also is required for anther development in normal cytoplasm maize. Hence, it appears that the rf2 gene was recruited recently to function as a nuclear restorer. ALDHs typically have very broad substrate specificities. Indeed, the RF2 protein is capable of oxidizing at least three aldehydes. Hence, the specific metabolic pathway(s) within which the rf2-encoded mtALDH acts remains to be discovered.     

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.     

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.     

A fertile revertant from petaloid cytoplasmic male-sterile carrot has a rearranged mitochondrial genome

 A spontaneously derived fertile plant was recovered from a petaloid cytoplasmic male-sterile (CMS) carrot inbred line. Genetic analysis indicated a single nuclear gene was responsible for the restoration to fertility. Within a family segregating for the nuclear restorer in combination with the sterility-inducing cytoplasm, fertile plants were recovered that could not restore fertility when crossed to sterile genotypes. Genetic analysis indicated cytoplasmic reversion for fertility, and Southern analysis, comparing mtDNA organization of the fertile revertant and its CMS progenitor, identified mitochondrial genome rearrangements. Hybridization of cosmids representing a 108-kb subgenomic circle of the sterile line to DNA of a fertile maintainer and fertile revertant lines indicated a similar mtDNA organization for these genotypes that was distinct from that of the sterile line. Six restriction fragments totalling 43.2 kb were common to the fertile maintainer and revertant and absent in the sterile; other restriction fragments totalling 38.2 kb were present only for the sterile line. Unique fragments of low stoichiometry, two for the fertile maintainer and three for the revertant, distinguished these lines. The reversion to fertility in the sterile line could have resulted from the amplification of a mitochondrial submolar genome highly homologous to that found in the fertile maintainer line. Received: 4 October 1997/Accepted: 12 December 1997     

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.     

水稻两种细胞质雄性不育“三系”及其F1杂交种线粒体DNA的RFLP分析

对水稻BT型和WA型细胞质的雄性不育系,相应保持系和恢复系以及杂种的mtDNA用12个线粒体探针进行了RFLP分析,结果如下(1)BT型和WA型不育系的mtDNA在组织结构上存在差异;(2)不育系的mtDNA与其保持系间存在显著差异,推测mtDNA与水稻的cms有关;(3)atp9探针检测到WA型不育系与F1之间的多态性,Frag36探针检测到BT型不育系与F1之间的多态性,Frag9探针检测到WA型和BT型不育系与其F1之间的多态性,证明核恢复基因影响mtDNA的结构;(4)对mtDNA的结构变异与细胞质雄性不育的关系进行了分析与探讨.