Direct transfer of a cold-tolerant Ogura male-sterile cytoplasm into cabbage (Brassica oleracea ssp. capitata) via protoplast fusion

Cold tolerant cytoplasmic male-sterile (CMS) cabbage (Brassica oleracea var. capitata) was produced by the fusion of leaf protoplasts from fertile cabbage and cold-tolerant Ogura CMS broccoli lines. The cabbage lines tested showed great variation in plant regeneration from unfused protoplasts; three with high regenerability were selected as the fusion partners. Several procedures for eliminating the nuclear DNA of the broccoli fusion partner were tested. Diploid cabbage plants were identified by flow cytometry and morphological characters. Gamma-irradiation (30 krad) was the most successful procedure; isolation of cytoplasts from broccoli leaf protoplasts, followed by gamma-irradiation of the cytoplast fraction, also produced diploids. UV-irradiation of the broccoli protoplasts was less effective. PCR using primers for an Ogura CMS-specific mitochondrial DNA sequence permitted the identification of cybrids likely to be CMS. Over 200 diploid plants with the CMS-specific sequence were obtained from 66 independent fusion products and three cabbage lines. Plants were ready for transfer into soil within 8 months after fusion. The plants identified as CMS by PCR produced male-sterile flowers. Our procedures permit the transfer of a desirable male-sterile cytoplasm into cabbage much more rapidly than conventional backcrossing procedures. Received: 4 June 1996 / Accepted: 2 August 1996     

Improved resistance to bacterial soft rot by protoplast fusion between Brassica rapa and B. oleracea

Erwinia soft rot is a destructive disease of Brassica rapa vegetables. Reliable sources of resistance and control methods are limited, so development of highly resistant breeding lines is desirable. Protoplasts from B. rapa and B. oleracea genotypes selected for resistance to soft rot were fused in order to combine different sources of resistance. Twelve somatic hybrids (synthetic B. napus) were obtained and confirmed by morphology, nuclear DNA content, and RAPD analysis. They were normal looking plants that easily set seeds following self-pollination and backcrossing to B. rapa. Assays of detached leaves or seedlings inoculated in a mist-chamber showed that most somatic hybrids had lower disease severity ratings than the B. rapa fusion partner and a commercial variety of B. napus. Some progeny from selfing or backcrossing of somatic hybrids to B. rapa showed much more resistance than either fusion partner. The offspring populations of the somatic hybrids (F₁–S₁ and F₁–BC₁) clearly moved to the resistant direction compared to the parents; the percentage of resistant plants increased from 21% (average of parents) to 36% (F₁–S₁) and 48% (F₁–BC₁). These results suggest that it may be possible to obtain highly resistant B. rapa lines by further backcrossing and selection. Received: June 1999 / Accepted: 29 July 1999     

Transfer of the Brassica tournefortii cytoplasm to B. napus for the production of cytoplasmic male sterile B. napus

The donor-recipient fusion method was used to combine the cytoplasm of Brassica lournefortii with the nucleus of B. napus for the production of cytoplasmic male sterile (CMS) plants. X-ray-irradiated mesophyll protoplasts of B. tournefortii were fused with iodoacetamide (lOA)-inactivated hypocotye protoplasts of B. napus . Selective conditions of IOA concentrations and X-ray doses were determined, which resulted in recovery of fusion products and inhibition of further growth of unfused parental cells. In total, 54 plants were obtained from different fusion experiments, of which 25 were verified as cybrids or partial hybrids. Mitochondrial DNA (mtDNA) analyses using 5 mitochondrial gene probes revealed that 20 of the 25 fusion-derived plants had mtDNA either identical, or with varying degrees of similarity, to B. lournefortii . These plants were classified into four groups on the basis of pollen viability and number. Seven plants were categorised as male sterile since they did not produce pollen or had non-viable pollen. Of the male sterile plants, five had a mtDNA pattern identical to B. tournefortii and a nuclear DNA content corresponding to B. napus . The nuclear-mito-chondrial constitution of these plants thus indicates that the combination of B. tournefortii cytoplasm with the B. napus nucleus results in CMS. Furthermore, mtDNA analysis of the two additional male sterile plants which displayed a rearranged mtDNA, revealed that the only mtDNA similarity shared among all male sterile plants was specific for B. tournefortii atp6 pattern. This indicates that the atp6 region of B. tournefortii may be involved in the expression of CMS.     

Intertrubal chloroplast transfer by protoplast fusion between Nicotiana tabacum and Salpiglossis sinuata

Summary Chloroplast tranfer was achieved by protoplast fusion between Nicotiana tobacum (Cestreae, Cestroideae) and Salpiglossis sinuata (Salpiglossideae, Cestroideae) in the family Solanaceae. Isolation of cybrid clones was facilitated by irradiation of the cytoplasm donor protoplasts, and the use of appropriate plastid mutants, streptomycin-resistant as donor, or light-sensitive as recipient. Cybrid colonies were selected by their green colour against the background of bleached (light-sensitive or streptomycin-sensitive) colonies. In the Nicotiana (Salpiglossis) cybrid plants possessing normal tobacco morphology and chromsome number, the presence of Salpiglossis, plastids was verified by restriction analysis of the chloroplast DNA. A similar analysis of the mitochondrial DNA of these lines revealed unique, recombinant patterns in the case of both fertile and sterile plants. Progeny showed no appearance of chlorophyll-deficiency in F₁ and an additional back-cross generation. Attempts at transfer of entire chloroplasts between Nicotiana tabacum and Solanum nigrum (Solaneae, Solanoideae) did not result in any cybrid cell lines in a medium suitable for green colony formation of both species. These results suggest that fusion-mediated chloroplast transfer can surmount a considerable taxonomical distance, but might be hampered by a plastome-genome incompatibility in more remote combinations.     

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     

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.     

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.     

Male-sterile chicory cybrids obtained by intergeneric protoplast fusion

Male-sterile chicory plants were obtained by fusion of chicory mesophyll protoplasts and hypocotyl protoplasts derived from male-sterile sunflower plants. The protoplasts of both species were fused by the PEG method and the products were selected manually and cultivated at very low density in a liquid medium. Three to twenty percent of the heterokaryocytes divided and evolved into microcalli, then into calli where budding could be induced. The mitochondrial genome of ten male-sterile or totally sterile plants was studied. Restriction endonuclease profiles of mitochondrial DNA and molecular hybridization with specific genes of the mitochondrial genome used as probes indicated that mitochondrial DNA rearrangement had occurred between sunflower and chicory and the intensity of the rearrangements correlated with the degree of sterility of the different plants.     

Brassica carinata resynthesized by protoplast fusion

Brassica carinata (bbcc) was resynthesized by protoplast fusion betweenB. nigra (bb) andB. oleracea (cc). In two fusion experiments 64 hybrid plants were obtained and identified to be true hybrids by isoenzyme analysis, nuclear DNA content, chromosome number, and intermediate morphology. Of these plants 56% were normal amphidiploids with 2n=34 chromosomes and a DNA content equivalent to that of naturalB. carinata. The remaining plants were polyploid, morphologically abnormal, and infertile. The majority of the hybrids contained both chloroplasts and mitochondria fromB. nigra, but some plants combined chloroplast and mitochondria from the different progenitors. Hybrids with a DNA content equivalent to that ofB. carinata had a wide range of male fertility (4–98%), but consistently low female fertility. Only a few selfed seed were produced, but these germinated and grew into vigorous plants.Salaries and research support provided by State and Federal funds appropriated to the Ohio Agricultural Research and Development Center, The Ohio State University. Journal Article No. 296-92     

Stable inheritance and expression of the CMS traits introduced by asymmetric protoplast fusion

The donor-recipient protoplast fusion method was used to produce cybrid plants and to transfer cytoplasmic male sterility (CMS) from two cytoplasmic male-sterile lines MTC-5A and MTC-9A into a fertile japonica cultivar, Sasanishiki. The CMS was expressed in the cybrid plants and was stably transmitted to their progenies. Only cytoplasmic traits of the male-sterile lines, especially the mitochondrial DNAs, were introduced into the cells of the fertile rice cultivar. More than 80% of the cybrid plants did not set any seeds upon selfing. Sterile cybrid plants set seeds only when they were fertilized with normal pollen by hand and yielded only sterile progenies. This maternally inherited sterility of the cybrid plants showed that they were characterized by CMS. The CMS of cybrid plants could be restored completely by crossing with MTC-10R which had the single dominant gene Rf-1 for restoring fertility. These results indicated that CMS was caused by the mitochondrial genome introduced through protoplast fusion. The introduced CMS was stably transmitted to their progenies during at least eight backcross generations. These results demonstrate that cybrids generated by the donor-recipient protoplast fusion technique can be used in hybrid rice breeding for the creation of new cytoplasmic male-sterile rice lines.     

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.     

Targeted cybridization in citrus: transfer of Satsuma cytoplasm to seedy cultivars for potential seedlessness

CMS (cytoplasmic male sterility) can be controlled by the mitochondrion genome in higher plants, including Satsuma mandarin. Somatic fusion experiments in citrus combining embryogenic callus protoplasts of one parent with leaf protoplasts of a second parent often produce cybrid plants of the leaf parent, a phenomenon occurring most often with interspecific fusion combinations. In an attempt to practically exploit this cybridization phenomenon, we conducted somatic fusion experiments combining embryogenic suspension-derived protoplasts of Satsuma mandarin, Citrus unshiu Marc. cv. Guoqing No. 1 (G1), a male-sterile cultivar, with leaf protoplasts of other seedy types—Hirado Buntan Pink pummelo (HBP) [Citrus grandis (L.) Osbeck], Sunburst mandarin (C. reticulata Blanco), Orie Lee hybrid (C. reticulata cv. Clementine × Murcott tangor), and Murcott tangor [C. reticulata × C. sinensis (L.) Osbeck], respectively—in an attempt to generate seedless cybrids by the targeted transfer of CMS. The genetic identities of regenerated plants from all four parental combinations were determined by flow cytometry, SSR, CAPS (or PCR-RFLP), RFLP, and chloroplast-SSR analyses. Regenerated plants from the first three parental combinations were diploids, and the cybrid nature of G1 + HBP with the mitochondrion genome from G1 and the chloroplast genome from HBP was confirmed, whereas the cybrid nature of the remaining two combinations was difficult to confirm because of the close phylogenetic relatedness of both fusion parents, as expected. Plants from G1 + Murcott were confirmed as tetraploid somatic hybrids. This is the first report of targeted citrus cybrid production by symmetric fusion with male-sterile Satsuma as the callus parent and other seedy cultivars as the leaf parents.Abbreviations CAPS: Cleaved amplified polymorphic sequence - CMS: Cytoplasmic male sterility - cp-SSR: Chloroplast simple sequence repeat - PEG: Polyethylene glycol - SSR: Simple sequence repeat - RFLP: Restriction fragment length polymorphism Communicated by G.C. Phillips     

Asymmetric protoplast fusion aimed at intraspecific transfer of cytoplasmic male sterility (CMS) in Lolium perenne L.

Summary Techniques have been developed for the production of cybrids in Lolium perenne (perennial ryegrass). Gamma-irradiated protoplasts of a cytoplasmically male-sterile breeding line of perennial ryegrass (B200) were fused with iodoacetamide-treated protoplasts of a fertile breeding line (Jon 401). After fusion 25 putative cybrid calli were characterized to determine mitochondrion type and composition of the nuclear genome. Analysis of phosphoglucoisomerase isozyme profiles and determination of the ploidy level by flow cytometry indicated that all of the calli tested essentially contained the nuclear DNA of the fertile line. However, the presence of parts of the nuclear DNA from the sterile line could not be excluded. Southern blotting of total DNA isolated from the parental lines and putative cybrids combined with hybridizations using the mitochondrial probes cox1 and atp6 revealed that the mitochondria of the calli originated from the fertile line (5 calli), the sterile line (5 calli) or from both parental lines (15 calli). The hybridization patterns of the mtDNA from the cybrid calli showed extensive quantitative and qualitative variation, suggesting that fusion-induced inter- or intramolecular mitochondrial recombination had taken place.     

Interspecific T-DNA transfer through plant protoplast fusion

Summary An attempt was made to transfer the T-DNA of Agrobacterium tumefaciens, previously introduced into plant cells, via protoplast fusion from one species into another. For the experiments two cell lines were used: firstly, a Nicotiana paniculata cell line transformed with the Agrobacterium strain B6S3. This cell line exhibits both hormone independent growth and synthesis of octopine as a result of the incorporated T-DNA from Agrobacterium. These two markers are dominant. The second cell line was the nitrate reductase deficient cnx-68 cell line of N. tabacum which contains an intracellular calcium oxalate druse. These two markers are recessive. Isolated protoplasts of the donor cell line N. paniculata B6S3 were mitotically inactivated by X rays and fused with protoplasts of the cell line cnx-68. Asymmetric somatic hybrids were selected on hormone free agar medium supplemented with 50 mM KClO₃. This compound is toxic for cells possessing nitrate reductase activity. From about 1.1×10⁷ cultivated protoplasts 18 cell lines survived the selection treatment. Of these seven exhibited the two dominant and the two recessive markers, whereas the others showed either only one or none of the recessive or only one of the dominant markers. In dot-blot experiments using species specific DNA clones of the donor and the recipient plant species it was confirmed that besides the T-DNA other nuclear genomic DNA of the donor species had also been transferred in various amounts. The possible consequences of these results for plant breeding programmes are discussed.     

Fusion-mediated transfer of triazine-resistant chloroplasts: Characterization of Nicotiana tabacum cybrid plants

Summary Terbutryn-resistant plastids of the Nicotiana plumbaginifolia TBR2 mutant were introduced into N. tabacum plants by protoplast fusion following X-irradiation of TBR2 protoplasts. The N. tabacum chloroplast recipient line, SR1-A15, carried mutant (albino) plastids. Following protoplast fusion, potential cybrid cell lines with an N. tabacum (SR1-A15) nucleus and N. plumbaginifolia (TBR2) chloroplasts were identified by their green color. The presence of TBR2 plastids in regenerated green N. tabacum plants was confirmed by hybridization with a chloroplast DNA probe and by the modified chloroplast fluorescence transients characteristic of the TBR2 mutant. Cybrid plants were resistant to high levels of atrazine (10 kg/ha). The protruding stigma and shorter than normal filaments of the cybrids resulted in male sterility. In the cybrids atrazine resistance was associated with reduced vigour, suggesting a causal relationship.     

Synthesis of Ogura male sterile rapeseed (Brassica napus L.) with cold tolerance by protoplast fusion and effects of atrazine resistance on seed yield

Twenty-one cold-tolerant, male sterile Brassica napus somatic hybrids were produced by protoplast fusion. The fusion partners were a coldsensitive, Ogura cytoplasmic male sterile cauliflower inbred (B. oleracea var. botrytis inbred NY7642A) and a cold-tolerant, fertile canola-type B. rapa cv. Candle. Hybridity was confirmed by morphology, isozyme expression, flow cytometry, and DNA hybridization. Organellar analyses revealed a very strong bias for Brassica over Raphanus chloroplasts. Cold tolerance was confirmed by cold chamber studies and chloroplast DNA analyses. Good female fertility with 21.4 ± 3.1 seeds/pod was observed in the field using natural pollination vectors. Total seed yield was significantly greater for the atrazine-sensitive somatic hybrids produced in this study than for atrazine-resistant isolines.Abbreviations CMS cytoplasmic male sterility - IA iodoacetate - cpDNA chloroplast DNA     

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.     

Asymmetric somatic hybrids of Brassica: partial transfer of B. campestris genome into B. oleracea by cell fusion

Summary To examine the possibility of producing asymmetric somatic hybrids of Brassica having a complete genome of one species and a part of the other, we fused inactivated B. oleracea protoplasts with X-irradiated B. campestris protoplasts. The plants obtained were studied with regard to their morphology, isozymes and chromosomes. The morphology of the hybrids was similar to B. oleracea in 9 out of 22 hybrids studied and the rest showed the intermediate phenotype of the parents. Analysis of three isozymes, leucine aminopeptidase, acid phosphatase and esterase indicated that ten hybrids lost B. campestris-specific bands in one or more of the three isozymes examined. The chromosome analysis showed that 90% of the hybrids were aneuploids. In addition, abnormal chromosomes were often found in root tip cells. These results suggested that the hybrids obtained were asymmetric in nature and resulted from elimination of B. campestris chromosomes by X-ray irradiation.     

Atrazine-resistant cauliflower obtained by somatic hybridization between Brassica oleracea and ATR-B. napus

Summary Somatic hybridization between Brassica oleracea ssp. botrytis (cauliflower, 2n=18), carrying the Ogura (R1) male-sterile cytoplasm and B. napus (2n= 38), carrying a male-fertile, atrazine-resistant (ATR) cytoplasm, yielded three hybrids (2n=56) and six cauliflower cybrids (2n=18), which were selected for resistance to the herbicide in vitro. The hybrids and cybrids were male fertile and self-compatible. They contained both chloroplasts and mitochondria from the ATR cytoplasm. We found no evidence for mtDNA recombination in any of the regenerated plants. Selfed progeny of the B. oleracea atrazine-resistant cybrids were evaluated for tolerance to the herbicide in the field. Resistant plants exposed to 0.56–4.48 kg/ha (0.5–4.0 pounds/acre) atrazine in the soil showed no damage at any herbicide level, whereas plants of a susceptible alloplasmic line were severely damaged at the lowest level of herbicide application and killed at all higher levels. These atrazine-resistant cauliflower may have potential horticultural use, especially in fields where atrazine carry over is a serious problem.