Rapid chloroplast segregation and recombination of mitochondrial DNA in Brassica cybrids

Summary Brassica cybrids were obtained after fusing protoplasts of fertile and cytoplasmic male sterile (CMS) B. napus lines carrying the original b. napus, and the Ogura Raphanus sativus cytoplasms, respectively. Iodoacetate treatment of the fertile line and X-irradiation of the CMS line prevented colony formation from the parental protoplasts. Colony formation, however, was obtained after protoplast fusion. Hybrid cytoplasm formation was studied in 0.5 g to 5.0 g calli grown from a fused protoplast after an estimated 19 to 22 cell divisions. Chloroplasts and mitochondria were identified in the calli by hybridizing appropriate DNA probes to total cellular DNA. Out of the 42 clones studied 37 were confirmed as cybrids. Chloroplast segregation was complete at the time of the study. Chloroplasts in all of the cybrid clones were found to derive from the fertile parent. Mitochondrial DNA (mtDNA) segregation was complete in some but not all of the clones. In the cybrids, mtDNA was different from the parental plants. Physical mapping revealed recombination in a region which is not normally involved in the formation of subgenomic mtDNA circles. The role of treatments used to facilitate the recovery of cybrids, and of organelle compatibility in hybrid cytoplasm formation is discussed.     

Intergeneric transfer of cytoplasmic male sterility between Raphanus sativus (cms line) and Brassica napus through cytoplast-protoplast fusion

Summary Cytoplasts isolated from hypocotyl protoplasts of Raphanus sativus cv Kosena (cms line) by ultracentrifugation through Percoll/mannitol discontinuous gradient were fused with iodoacetamide(IOA)-treated protoplasts of Brassica napus cv Westar. Seventeen randomly selected regenerated plants were characterized for morphology and chromosome numbers. All of the regenerated plants had morphology identical to B. napus and 10 of them possessed the diploid chromosome number of B. napus. The remaining plants had chimeric or aneuploid chromosome numbers. The mitochondrial genomes in the 10 fusion products possessing the diploid chromosome numbers of B. napus were examined by Southern hybridization analysis. Four of the 10 plants contained mitochondrial DNA showing novel hybridization patterns. Of these 4 plants, 1 was male sterile, and 3 were male fertile. The remaining plants showed mitochondrial DNA patterns identical to B. napus and were male fertile.     

Synthesis of male sterile,triazine-resistant Brassica napus by somatic hybridization between cytoplasmic male sterile B. oleracea and atrazine-resistant B. campestris

Summary Fusion of leaf protoplasts from an inbred line of Brassica oleracea ssp. botrytis (cauliflower, n=9) carrying the Ogura (R1) male sterile cytoplasm with hypocotyl protoplasts of B. campestris ssp. oleifera (cv Candle, n=10) carrying an atrazine-resistant (ATR) cytoplasm resulted in the production of synthetic B. napus (n=19). Thirty-four somatic hybrids were produced; they were characterized for morphology, phosphoglucose isomerase isoenzymes, ribosomal DNA hybridization patterns, chromosome numbers, and organelle composition. All somatic hybrids carried atrazine-resistant chloroplasts derived from B. campestris. The mitochondrial genomes in 19 hybrids were examined by restriction endonuclease and Southern blot analyses. Twelve of the 19 hybrids contained mitochondria showing novel DNA restriction patterns; of these 12 hybrids, 5 were male sterile and 7 were male fertile. The remaining hybrids contained mitochondrial DNA that was identical to that of the ATR parent and all were male fertile.     

The effect of genotype on pollen transmission of mitochondria in rapeseed (Brassica napus)

Summary Crossing experiments were conducted to determine whether parental genotype affected the rate of transmission of paternal mitochondria to progeny in rapeseed (Brassica napus). Progeny were screened either by RFLP analysis of mitochondrial (mt) DNA or by means of a mt marker that causes male sterility. To date we have transferred paternal mitochondria to progeny in only cross, i.e. a specific female line crossed to a specific male line. The male line carries the polima cytoplasm, the mitochondria of which confer a characteristic malesterile flower morphology when in a napus nuclear background. This line is male fertile due to a restorer gene carried on an extra chromosome from a closely related species, Brassica juncea. The female line has a Brassica campestris cytoplasm with a chloroplast mutation conferring resistance to triazine herbicides. Progeny with mixtures of parental mtDNA display a range of plant phenotype from complete male fertility through varying proportions of male-sterile sectors to complete male sterility. The male sterility or fertility of flowers on a sector of a plant reflects the mt population of that sector, and such sectors will give rise to stably fertile or sterile progeny. These experiments suggest that maternal inheritance of mitochondria in higher plants is due to genes active in both the pollen parent and the egg parent.     

A new cytoplasmic male sterility system for hybrid seed production in Indian oilseed mustard Brassica juncea

We report a novel cytoplasmic male sterility (CMS) system in Brassica juncea (oilseed mustard) which could be used for production of hybrid seed in the crop. A male sterile plant identified in a microspore derived doubled haploid population of re-synthesized B. napus line ISN 706 was found to be a CMS as the trait was inherited from the female parent. This CMS, designated ‘126-1’, was subsequently transferred to ten different B. juncea varieties and lines through inter-specific crosses followed by recurrent backcrossing. The F₁s of inter-specific crosses were invariably partially fertile, but irrespective of the variety/line used, the recipient lines became progressively male sterile over five to seven generations and could be maintained by crossing the male sterile lines with their normal counterparts. The male sterile lines were found to be stable for the trait under both long and short day conditions. CMS lines when crossed with lines other than the respective maintainer line were restored for fertility, implying that any variety could act as a restorer for ‘126-1’ cytoplasm in B. juncea. These unique features in maintenance and restoration of CMS lines coupled with near normal floral morphology of the CMS lines have allowed the use of ‘126-1’ cytoplasm for hybrid seed production. The uniqueness of ‘126-1’ has been further established by Southern hybridization with mitochondrial DNA probes and by a histological study of the development of male sterile anthers.     

Analysis of organelle genomes in a somatic hybrid derived from cytoplasmic male-sterile Brassica oleracea and atrazine-resistant B. campestris

Summary An atrazine-resistant, male-fertile Brassica napus plant was synthesized by fusion of protoplasts from the diploid species B. oleracea and B. campestris. Leaf protoplasts from B. oleracea var. italica carrying the Ogura male-sterile cytoplasm derived from Raphanus sativus were fused with etiolated hypocotyl protoplasts of atrazine-resistant B. campestris. The selection procedure was based on the inability of B. campestris protoplasts to regenerate in the media used, and the reduction of light-induced growth of B. oleracea tissue by atrazine. A somatic hybrid plant that differed in morphology from both B. oleracea and B. campestris was regenerated on medium containing 50 M atrazine. Its chromosome number was 36–38, approximately that of B. napus. Furthermore, nuclear ribosomal DNA from this hybrid was a mixture of both parental rDNAs. Southern blot analyses of chloroplast DNA and an assay involving tetrazolium blue indicated that the hybrid contained atrazine-resistant B. campestris chloroplasts. The hybrid's mitochondrial genome was recombinant, containing fragments unique to each parent, as well as novel fragments carrying putative crossover points. Although the plant was female-sterile, it was successfully used to pollinate B. napus.     

Transfer of the CMS trait in Daucus carota L. by donor-recipient protoplast fusion

Summary X-irradiated protoplasts of Daucus carota L., 28A1, carrying cytoplasmic male sterile (CMS) cytoplasm and iodoacetamide-treated protoplasts of a fertile carrot cultivar, K5, were fused with polyethylene glycol (PEG), and 73 plants were regenerated. Twenty-six randomly chosen regenerated plants had non-parental mitochondrial DNA (mtDNA) as revealed by XbaI restriction fragment patterns, and all of the plants investigated had diploid chromosome numbers. Of the 11 cybrid plants that showed mtDNA fragment patterns clearly different from those of the parents, 10 plants showed male sterility with brown or red anthers, and one plant possessed partially sterile yellow anthers. The mtDNA fragment patterns of the ten cybrid plants with male sterile flowers resembled that of a CMS parent, 28A1; and four fragments were identified that were common between the sterile cybrid plants and 28A1, but absent from the partially sterile cybrid plants and a fertile cultivar, K5. The results indicated that the CMS trait of the donor was efficiently transferred into the cybrid plants by donor-recipient protoplast fusion.     

Protoplast fusion-derived Ogura male sterile cauliflower with cold tolerance

Cauliflower (Brassica oleracea L. ssp. botrytis) protoplasts with Ogura male sterile and fertile B. oleracea cytoplasms were fused, producing plants with an array of organellar types. Plants with Ogura mitochondria were male sterile; those with B. oleracea chloroplasts were cold tolerant. In some fusions, unfused parental protoplasts were eliminated by double inactivation with iodoacetate and gamma-irradiation; in others, fused protoplasts were physically isolated by micromanipulation or by cell sorting. Double inactivation fusions produced the most plants, including many which were male sterile, female fertile, cold tolerant and diploid.Abbreviations IA iodoacetate - FDA fluorescein diacetate - CMS cytoplasmic male sterility - mtDNA mitochondrial DNA     

The characterization of herbicide tolerant plants in Brassica napus L. after in vitro selection of microspores and protoplasts

Brassica napus L.(cv Topas) plants tolerant to chlorsulfuron (CS) were isolated after selection experiments utilizing microspores and haploid protoplasts. The first microspore-derived plant (M-37,) was CS tolerant, haploid and sterile. Normal plant morphology and fertility was restored after colchicine doubling. A CS tolerant plant was also selected from protoplasts (P-26) isolated from microspore-derived embryo tissue and grown on medium containing CS. P-26 was aneuploid, CS tolerant and had very low fertility. The two selected lines produced selfed progeny which were tolerant to from 10–100 times the CS levels of the corresponding Topas plants. Microspores and protoplasts derived from the selfed plants were also CS tolerant. The segregation pattern for CS tolerance from reciprocally crossed progeny of M-37 and Topas was consistent with a semi-dominant nuclear mode of inheritance. Biochemical analysis of the two mutants indicated that the microspore-derived mutant and F1 crosses contained an altered acetohydroxyacid synthase (AHAS) enzyme, while the AHAS activity of the protoplast mutant was similar to Topas. Selfed seed from the M-37 plants have provided tolerance to CS in both greenhouse and field tests. S1 plants from a second microspore selected mutant (M-42) have tolerated 30 g/ha of CS in greenhouse tests. The two single-celled selection systems are discussed and the microspore selection system highlighted as a new method for in vitro selection.     

Somatic transfer of cytoplasmic traits in Brassica napus L. by haploid protoplast fusion

Summary Fusions between protoplasts from haploid cytoplasmic atrazine resistant (CATR) and haploid cytoplasmic male sterile (CMS) Brassica napus plants were used to produce a diploid CMS/CATR cybrid. The hybrid nature of the cytoplasm was confirmed by comparing the EcoRI restriction fragment patterns of chloroplast and mitochondrial DNA from the cybrid with the parental patterns. The advantages of using haploid protoplasts for fusion experiments as well as the utilization of the CMS/CATR cybrid for hybrid seed production are discussed.     

Introduction of a gene from fertility restored radish (Raphanus sativus) into Brassica napus by fusion of X-irradiated protoplasts from a radish restorer line and iodacetoamide-treated protoplasts from a cytoplasmic male-sterile cybrid of B. napus

To establish a cytoplasmic male-sterile/restored fertility (cms-Rf) system for F₁ seed production in Brassica napus, we transferred a gene from fertillity restored radish to B. napus by protoplast fusion. X-irradiated protoplasts, isolated from shoots of Raphanus sativus cv Kosena (Rf line), were fused with iodoacetamide-treated protoplasts of a B. napus cms cybrid. Among 300 regenerated plants, six were male-fertile. The fertile plants were characterized for petal color, chromosome number and the percentage of viable pollen grains. Three fertile plants had aneuploid chromosome numbers and white or cream petals, which is a dominant marker in radish. Of these three plants, one which had 2n = 47 chromosomes and white petals was used for further backcrosses. After two backcrosses, chromosome number and petal color became identical to that of B. napus. No female sterility was observed in the BC₃ generations.     

An investigation of the intracellular site of anthocyanoplasts using isolated protoplasts and vacuoles

Microscopic observations made during preparation of protoplasts and vacuoles from red radish seedling hypocotyl (Raphanus sativus L.) show that anthocyanoplasts, the strongly pigmented bodies present in the pigmented cells of the hypodermis, begin as apparently membranous vesicles in the cytoplasm made visible by the deposition and accumulation of anthocyanins, but only rarely appear in the isolated vacuole. Isolation of protoplasts and vacuoles was also achieved from mung bean seedling hypocotyl (Vigna radiata L Wilczek), red cabbage leaf (Brassica oleracea L.) and Prunus x yedoensis Matsum callus. Anthocyanoplasts were usually in the vacuole, although sometimes in the cytoplasm, of the mung bean and cabbage, but were never seen in vacuoles of Prunus callus.     

Interspecific transfer of isolated plant mitochondria by microinjection

Summary Data on isolation, purification and transfer of mitochondria from a cytoplasmic male sterile line of the Ogura type of Raphanus sativus to a male fertile line of Brassica napus are reported. Microinjection has been used for the transfer of the donor mitochondria to the recipient protoplasts. The injected protoplasts were identified and followed individually throughout their development using a computerized microscope stage which greatly enhanced the number of injections (five-fold). The transferred donor mitochondria were stably maintained during several successive cell divisions, revealing that they were viable and functional. Several calluses were obtained from injected protoplasts without using any selection pressure. Restriction fragment length analysis of seventeen calluses, using mitochondrial DNA probes, indicated that three contained the donor Ogura type mitochondria. No recombinant types of mitochondria have been observed. Flow cytometric and karyotype analyses of the calluses revealed the presence of similar amount of DNA and chromosome number as those of the recipient plants of B.napus. The application of microinjection for the manipulation of cytoplasmic composition is discussed.Abbreviations ATPase adenosine triphosphate phosphohydrolase - BSA bovine serum albumin - CMS cytoplasmic male sterility - DIOC6(3) 3,3-dihexyloxacarbocyanine-iodide - mt mitochondria(I) - PEG polyethylene glycol - RFLP restriction fragment length polymorphism - UV ultraviolet     

Somatic hybridization between male sterile Nicotiana tabacum and N. glutinosa through protoplast fusion

Summary Protoplasts derived from suspension cultured cells of cytoplasmic male sterile Nicotiana tabacum (N. debneyi cytoplasm) and of fertile N. glutinosa were fused with the aid of polyethylene glycol (PEG). Out of 1,089 colonies developed from PEG-treated protoplasts, 29 restored whole plants.A somatic hybrid plant was selected on the basis of isoelectrofocusing analysis of Fraction I protein in leaves of regenerated plants. A newly created hybrid contained small subunits of both parents but only a N. glutinosa type large subunit.Male sterile character was conserved in a hybrid plant while leaf morphology was intermediate between the parents. By tobacco mosaic virus infection tests, the hybrid's leaves showed resistant symptoms, hypersensitive local lesions, which were due to N. glutinosa nuclear genome expression.Abbreviations PEG Polyethylene glycol - TMV Tobacco mosaic virus     

Restoration of fertility in cytoplasmic male sterile (CMS) Nicotiana Sylvestris by fusion with X-irradiated N. tabacum protoplasts

Summary Restoration of male fertility was achieved by fusing protoplasts from male sterile (CMS) Nicotiana sylvestris plants with X-irradiated protoplasts derived from fertile N. tabacum plants. The CMS N. sylvestris plants were derived from a previous somatic hybridization experiment and contained alien (Line 92) cytoplasm. About one quarter of the regenerated plants were found to be cybrids. i.e. they consisted of N. sylvestris nuclei combined with all or some components of N. tabacum cytoplasm. In one half of these cybrids male fertility was restored to different levels. The chloroplasts of the two parental donors differ in respect to tentoxin sensitivity: chloroplasts of CMS N. sylvestris are sensitive while those of N. tabacum are insensitive. It could therefore be demonstrated that there was an independent segregation of chloroplast type and male fertility/sterility: several somatic cybrids were male fertile but tentoxin sensitive and others were tentoxin insensitive yet they were male sterile. Only in about one half of the somatic cybrids was male fertility restored together with restoration to tentoxin insensitivity.     

Characterization of a partial male fertility derived from Ogura-cms in progeny of a resynthesized Brassica napus

Summary The inheritance of a partial male fertile phenotype in somatic hybrid B. napus plants that carried novel mtDNA was investigated over five backcross generations to B. napus Triton. The recurrent parent and the original somatic hybrid both contained chloroplasts resistant to atrazine. The F₁ population contained mainly plants that were partial fertile, and some of the plants differed in mtDNA. The partial fertility predominated in the progeny of each backcross generation, but fully male sterile and fertile plants were also obtained. However, the sterility/fertility of these latter plants was not stable; both the fully male sterile and the male fertile plants produced progeny that were again predominantly partial male fertile. This pattern of predominant partial fertility but occasional sterile and fertile plants persisted in different nuclear backgrounds. Neither the male sterility nor the male fertility could be fixed and made stable. Test crosses indicated that restorer genes were probably not associated with appearance of male fertile plants. The evidence indicates that the behavior of the partial male fertility is cytoplasmic, and probably controlled by the chondriome.     

Correction of chlorophyll-defective male-sterile winter oilseed rape (Brassica napus) through organelle exchange: molecular analysis of the cytoplasm of parental lines and corrected progeny

Summary Cytoplasmic differences between male-fertile and male-sterile Brassica napus as well as Raphanus sativus were investigated. Plastids of the male-fertile B. napus were found to differ from those of male-sterile B. napus and R. sativus with respect to DNA restriction enzyme patterns. Differences between male-fertile and male-sterile B. napus mitochondria were detected not only in the restriction fragment patterns of their DNA, but also at the level of expression by in organello translation of mitochondrial polypeptides.The chlorophyll deficiency obtained upon transferral of the male-sterility-conferring radish cytoplasm to a winter variety of B. napus had been corrected earlier through protoplast fusion. The cytoplasmic composition of the corrected lines was analysed using DNA restriction analysis and in organello translation. The stability of the recombined cytoplasm in the corrected lines was confirmed by analysis of the subsequent seed-derived generation.     

Effects of parental ploidy level and genetic divergence on chromosome elimination and chloroplast segregation in somatic hybrids within Brassicaceae

Summary Chromosome and organelle segregation after the somatic hybridization of related species with different degrees of genetic divergence were studied by comparing the interspecific somatic hybrids Brassica oleracea (CC) (+) B. campestris (AA), B. napus (AACC) (+) B. oleracea (CC) B. napus (AACC) (+) B. nigra (BB) and B. napus (AACC) (+) B. juncea (AABB) with the intergeneric somatic hybrids B. napus (AACC) (+) Raphanus sativus (RR) and B. napus (AACC) (+) Eruca sativa (EE). Within each combination, some hybrids were found whose DNA content was equal to the sum of parental chromosomes, others had a relatively higher DNA content and in most of the cases, some had a relatively lower content. However, the frequency distribution in these three classes differed significantly between the combinations. A positive correlation between the frequency of hybrids with eliminated chromosomes and the genetic distance between the species in each combination was found. Furthermore, by combining species with different ploidy levels we found a significantly higher degree of chromosome elimination compared to combinations of species with the same ploidy level. In the B. napus (+) B. Nigra, B. napus (+) R. sativus and B. napus (+) E. sativa combinations chromosomes from the B, R and E genomes appeared to be preferentially sorted out, as indicated by the fact that some of the nuclear markers from these genomes were missing in 7–46% of the plants, whereas no plants were lacking B. napus nuclear markers. Fertile hybrids were found in all but the B. napus (+) R. sativus fusion combination; the latter hybrids were male sterile, but female fertile. Hybrids between the A and C genomes were more fertile than hybrids obtained between the distantly related AC and B, R or E genomes, respectively. Analysis of the chloroplast RFLP pattern revealed that chloroplasts in the B. oleracea (+) B. campestris hybrids segregated randomly. A slightly biased segregation, favouring B. napus chloroplasts, was found in the B. napus (+) B. oleracea combination, whereas B. napus chloroplasts were strongly selected for in the B. napus (+) B. juncea, B. napus (+) B. nigra, B. napus (+) R. sativus and B. napus (+) E. sativa somatic hybrids.