用线粒体DNA鉴定玉米雄性不育细胞质的研究

参照Kemble法,通过分析玉米线粒体DNA,鉴定出我国生产上应用的玉米双型和唐徐型雄性不育细胞质属于S组。近年新获得的不育类型Y型属于T组,为玉米种子生产合理应用雄性不育细胞质提供了可靠依据,并对鉴别玉米雄性不育细胞质的方法进行了讨论。     

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     

Efficiency of one- and two-stage selection indexes for improvement of net economic merit in White Leghorns

Summary Mitochondrial (mt) and chloroplast (ct) DNAs from sugar beet lines carrying normal and introduced sources of male sterile cytoplasms have been characterized and compared on the basis of restriction enzyme analysis. Normal cytoplasm was shown to contain mt and ctDNAs which differed from those of the male sterile cytoplasms examined in the present investigation. On the other hand, four groups of male sterile cytoplasms could be differentiated by their own characteristic mtDNA digest patterns, while two were separated by ctDNA comparisons. In addition, a greater degree of variability of the mitochondrial genome is suggested. Our results also imply strict maternal inheritance of mt and ctDNAs. Thus, the organelle DNA assay provides a positive and alternative means of identifying various male sterile 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.     

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.     

Two new types of cytoplasmic male sterility found in wild Beta beets

Summary Mitochondrial (mt) and chloroplast (ct) DNAs from sugar beet carrying normal fertile and different cytoplasmic male sterile (cms) cytoplasms were compared by restriction analysis and for the occurrence of minicircles. One of the cms materials had the Owen cms cytoplasm currently used for hybrid production in sugar beet; the other three cms materials were derived from wild Beta beets. The mtDNAs from two of the latter cms types (C 7051, C 8640) differed from both the Owen and the fertile cytoplasms in fragment patterns seen after restriction enzyme analysis and in minicircle composition. The third cms type (C 8684) differed from the Owen cytoplasm in mini-circle composition, but restriction enzyme analysis revealed no differences. The presence of the different minicircles was confirmed by Southern hybridization using minicircle-specific clones. All bands hybridized as predicted by gel electrophoresis except a band in the cms type C 8640, which migrated in a similar manner as the c.c.c. form of the a minicircle. This band hybridized only faintly to a minicircle a-specific probe and could be removed by treatment with nuclease S1. In contrast to the large mtDNA variation, restriction analysis of ctDNA detected little variation between cytoplasms. The molecular characterization of the new sources of cms supports the results of previous crossings. Two of the cytoplasms are not only of independent origin, but are also most likely functionally different and thus may be of value in future production of hybrid sugar beet varieties.     

Mitochondrial DNA modifications associated with cytoplasmic male sterility in rice

Summary 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.     

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.     

DNA methylation affected by male sterile cytoplasm in rice (Oryza sativa L.)

Male sterile cytoplasm plays an important role in hybrid rice, and cytoplasmic effects are sufficiently documented. However, no reports are available on DNA methylation affected by male sterile cytoplasm in hybrid rice. We used a methylation-sensitive amplified polymorphism technique to characterize DNA methylation in four male sterile cytoplasms that are widely commercialized in China. In total, 12 pairs of selective primers in combinations of EcoRI and MspI/HpaII amplified 350 bands among four male sterile (A) lines and the corresponding maintainer (B) lines. Sites b1 and b3 were fully methylated only in all the B lines, while b2 was fully methylated only in all the A lines. These results implied a relationship of DNA methylation at these sites specifically with male sterile cytoplasms, as well as male sterility, since the only difference between the A and B lines was the cytoplasm. The DNA methylation was markedly affected by male sterile cytoplasms. WA-type and Yinshui-type cytoplasms affected the methylation to a much greater degree than G-type and D-type cytoplasms, as indicated by the number and degree of methylated sites, ratio of methylated sites, number of fully methylated sites, ratio of fully methylated sites, and polymorphism between A and B lines for these cytoplasms. The genetic distance between the cytoplasm and nucleus for the WA-type is much greater than for G- and D-types because the former is between wild and cultivated species and the latter is within indica subspecies between African and Asian cultivars. This difference in genetic distance may be responsible for the variation in methylation which we observed.     

Small mitochondrial DNA molecules of wild abortive cytoplasm in rice are not necessarily associated with CMS

Summary Mitochondrial DNA was isolated from leaf tissue of both the cytoplasmic male sterile line of Indica rice variety V41, which carries wild abortive (WA) cytoplasm, and from the corresponding maintainer line. In addition to the main mitochondrial DNA, four small plasmid-like DNA molecules were detected in both the male sterile and fertile lines. Restriction analysis of total mitochondrial DNA from the male sterile and fertile lines showed DNA fragments unique to each. Our findings suggest that the four small mitochondrial DNA (mtDNA) molecules are conserved when WA cytoplasm is transferred into different nuclear backgrounds. However, there is no simple correlation between the presence/ absence of small mitochondrial DNA molecules and the expression of WA cytoplasmic male sterility (CMS).     

Cytoplasmic effects on DNA methylation between male sterile lines and the maintainer in wheat (Triticum aestivum L.)

Male sterile cytoplasm plays an important role in hybrid wheat, and three-line system including male sterile (A line), its maintainer (B line) and restoring (R line) has played a major role in wheat hybrid production. It is well known that DNA methylation plays an important role in gene expression regulation during biological development in wheat. However, no reports are available on DNA methylation affected by different male sterile cytoplasms in hybrid wheat. We employed a methylation-sensitive amplified polymorphism technique to characterize nuclear DNA methylation in three male sterile cytoplasms. A and B lines share the same nucleus, but have different cytoplasms which is male sterile for the A and fertile for the B. The results revealed a relationship of DNA methylation at these sites specifically with male sterile cytoplasms, as well as male sterility, since the only difference between the A lines and B line was the cytoplasm. The DNA methylation was markedly affected by male sterile cytoplasms. K-type cytoplasm affected the methylation to a much greater degree than T-type and S-type cytoplasms, as indicated by the ratio of methylated sites, ratio of fully methylated sites, and polymorphism between A lines and B line for these cytoplasms. The genetic distance between the cytoplasm and nucleus for the K-type is much greater than for the T- and S-types because the former is between Aegilops genus and Triticum genus and the latter is within Triticum genus between Triticum spelta and Triticum timopheevii species. Thus, this difference in genetic distance may be responsible for the variation in methylation that we observed.     

Variations in mitochondrial DNA organisation between normal and male-sterile cytoplasms of maize.

Mitochondrial DNA from male-sterile lines of maize carrying S cytoplasm contains two small DNA species which are absent from N (fertile) and other male-sterile cytoplasms. Portions of these species have been purified and amplified by constructing recombinant plasmids in vitro. Probes made with these plasmids have been used to demonstrate; i) a homologous region in the N mitochondrial genome, which may indicate the origin of the S specific DNA species. ii) two other DNA species present in low amounts in S cytoplasm only. iii) the absence of strong homology to the S specific DNA species in mitochondria from C and T male-sterile cytoplasms.     

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.     

Chloroplast DNA polymorphism in fertile and male-sterile cytoplasms of sorghum (Sorghum bicolor (L.) Moench)

Summary Restriction endonuclease patterns of chloroplast DNA (cpDNA) were consistently distinguishable between fertile and male-sterile cytoplasms of sorghum [Sorghum bicolor (L.) Moench], whereas no differences in restriction patterns of cpDNA among male-sterile (A₁) lines, including six isocytoplasmic strains, were revealed in this study. It is suggested that chloroplast DNA may contribute to the male sterility of A₁ lines used currently in hybrid sorghum production.This research was supported by a research grant from Kansas Grain Sorghum Commission, Kansas Board of Agriculture. Contribution 90-293-J from the Kansas Agricultural Experiment Station     

Comparison of chloroplast and mitochondrial DNA from five morphologically distinct Beta vulgaris cultivars: sugar beet,fodder beet,beet root,foliage beet,and Swiss chard

Summary Two cytoplasms, N and S, are used in the breeding of sugar beet, Beta vulgaris var. altissima. These cytoplasms can be distinguished by their mitochondrial DNA. In an attempt to detect new cytoplasms, we compared the restriction profiles of chloroplast and mitochondrial DNA from five different cultivars of Beta vulgaris. All restriction patterns of chloroplast DNA were identical. With the exception of sugar beet with S-cytoplasm, all cultivars studied showed the same restriction profile of mitochondrial DNA, indicating that these cultivars all contain the N-cytoplasm. These results are discussed with regard to the large morphological differences of the cultivars and the cytoplasmic variability found in natural populations of the wild beet, Beta maritima.     

Organization of mitochondrial DNA in normal and texas male sterile cytoplasms of maize

Recombinant DNA and hybridization techniques have been used to compare the organization of mitochondrial DNA (mtDNA) from normal (N) and Texas male sterile (T) cytoplasms of maize. Bam H1 restriction fragments of normal mtDNA were cloned and used in molecular hybridizations against Southern blots of Bam H1 digested N and T mtDNA. Fifteen of the 35 fragments were conserved in both N and T as indicated by hybridization to comigrating bands in their restriction patterns. Only three fragments produced autoradiographs whose differences could reasonably be attributed to single changes in the cleavage site of the enzyme while approximately half (17/35) of the clones resulted in more complicated differences between N and T. The autoradiographs produced by these 17 clones indicated multiple cleavage site changes and/or sequence rearrangements of the mtDNA. Patterns of six of these 17 clones indicated partial duplication of the sequence and two showed variation in the intensity of hybridization between N and T, which may be related to the molecular heterogeneity phenomenon found in maize mitochondrial genomes. The large proportion of changes observed between N and T mtDNA indicates that rearrangements may have played an important role in the evolution of the maize mitochondrial genome.     

Development of a rapid identification method for potato cytoplasm and its use for evaluating Japanese collections

The cytoplasm of potatoes, characterized by the presence of T-type chloroplast DNA and β-type mitochondrial DNA, is sensitive to nuclear chromosomal genes that contribute to various types of male sterility. Past breeding efforts with various potato varieties have resulted in several different cytoplasms other than T/β. Varieties with Solanum stoloniferum-derived cytoplasm (W/γ) show complete male sterility, while those with S. demissum-derived cytoplasm (W/α) produce abundant, but non-functional pollen. Thus, identification of cytoplasmic types is important for designing efficient mating combinations. To date, only T-type chloroplast DNA can be accurately identified by a PCR marker. Here, we report a rapid identification technique by multiplex PCR, followed by restriction digestion with BamHI in one reaction tube, and propose a new nomenclature for potato cytoplasm types (T, D, P, A, M, and W). Using this new technique, our collections of 748 genotypes, including 84 Japanese named varieties, 378 breeding lines and 26 landraces, and 260 foreign varieties and breeding lines, were grouped into cytoplasm types: T (73.9?%), D (17.4?%), P (4.5?%), A (1.5?%), M (0.3?%), and W (2.4?%). The utility of this marker system for breeding is discussed.     

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.     

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.