Resynthesis of Brassica carinata by protoplast fusion and recovery of a novel cytoplasmic hybrid

Brassica carinata (2n=34, BBCC), was synthesized by fusing dark grown etiolated hypocotyl protoplasts of B. nigra (2n=16, BB) with green mesophyll protoplasts of B. oleracea (2n=18,CC) using polyethylene glycol. Heterokaryons could be microscopically distinguished from the parental types by their dark green chloroplasts in the colourless hypocotyl protoplast background. The mean heterokaryotic fusion frequency estimated on the basis of this morphological distinction was about 16%. A total of 626 calli were obtained, of which 92 regenerated shoots after transfer to zeatin (2 mg/l) supplemented MS medium. Of these, 81 calli differentiated into plants morphologically similar to naturally occurring B. carinata and 11 calli yielded plants resembling parental types. Meiosis in seven hybrid plants showed the chromosome number to be 2n=34 the sum of B. nigra and B. oleracea chromosomes. Molecular confirmation of the amphidiploid nature of hybrids was obtained by probing with a B. juncea derived genomic clone. The use of chloroplast and mitochondrial specific gene probes, revealed that one plant was a cytoplasmic hybrid having cp DNA sequences of both B. oleracea and B. nigra and mt DNA sequences of B. nigra.Abbreviations PEG Polyethylene glycol - 2,4-D 2,4-dichlorophenoxyacetic acid - NAA Naphthaleneacetic acid - IBA Indole-3-butyric acid - BAP 6-Benzylaminopurine - MS Murashige and Skoog (1962)     

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.     

Analysis of chloroplast and mitochondrial segregation in three different combinations of somatic hybrids produced within Brassicaceae

Summary Mitochondrial and chloroplast DNA were characterized in three different combinations of somatic hybrids produced between different species within Brassicaceae. The fusions were made between B. campestris and B. oleracea, B. napus and B. nigra and between B. napus and Eruca sativa. The combinations represent interspecific hybridizations, but the phylogenetic distance between the species used in each instance is different. Whereas the B. campestris (+) B. oleracea and the B. napus (+)B. nigra hybrids are both examples of intrageneric hybrids, B. campestris is more closely related to B. oleracea than B. napus is to B. nigra. The fusion of B. napus and E. sativa represents an intergeneric hybridization. Since hybrids were produced with reproducible and uniform fusion and culture methods, a comparison of chloroplast and mitochondrial segregation and mitochondrial DNA (mt-DNA) rearrangements could be made between the combinations. The segregation of both chloroplasts and mitochondria was biased in the B. napus (+)B. nigra and the B. napus (+)E. sativa combination. The nonrandom segregation of chloroplasts and mitochondria could be due to the different ploidy levels of the fusion partners and/or reflect differences in organelle replication rate. Furthermore, segregation of mitochondria was correlated to the differences in phylogenetic distance between the species used in the fusions. However, mitochondrial segregation, in contrast to chloroplast segregation, could in all combinations also have been affected by the cell type used as protoplast source in the fusions. All different chloroplast types could be established within each combination. Hybrids containing chloroplast from one parent together with mitochondria from the other parent were found in two of the combinations, although the majority of the hybrids had mt-DNA that was altered compared to the parental species. The rearranged mt-DNA found in most hybrids was an effect of the heteroplasmic state following protoplast fusion rather than of the tissue culture methods, since no mt-DNA rearrangements were found in B. napus plants regenerated from protoplast culture. The mtDNA restriction patterns of the hybrids with rearranged mt-DNA indicated that specific regions of the mt-DNA were involved in the rearrangements following protoplast fusion.     

Transfer and segregation of triazine tolerant chloroplasts in Brassica napus L.

Summary Hypocotyl protoplasts of 45 different genotypes of German winter oilseed rape Brassica napus L. (double zero quality: high in yield, seeds low in erucic acid and glucosinolate content) were regenerated to plants. Triazine/triazinone (tri)-tolerant chloroplasts of the Canadian spring oilseed rape variety OAC Triton were introduced into some winter oilseed rapes by means of protoplast fusion. X-ray irradiation was used to limit the transfer of nuclear DNA of Triton protoplasts and to promote the selective transfer of tri-tolerant chloroplasts. Regenerated cybrid plants survived a treatment rate of 1000 g/ha metribuzin. The presence and segregation of the tri-tolerant chloroplasts in winter oilseed rape plants, regenerated from fusion products and their progeny, was investigated by restriction fragment length polymorphism (RFLP). Our results indicate that chloroplast segregation was not completed in plants regnerated from fusion products derived from X-irradiated OAC Triton mesophyll protoplasts and German winter oilseed rape hypocotyl protoplasts. In regenerants and their progeny both chloroplast types can still be present. Chloroplasts derived from wintertype protoplasts can outcompete tritolerant chloroplasts during plant development. In some instances, even progeny plants not kept under selective conditions (metribuzin) lost tri-tolerant chloroplasts. A homogenous population of tri-tolerant chloroplasts was necessary to obtain stable tri-tolerant winter oilseed rape plants.     

Non-random inheritance of organellar genomes in symmetric and asymmetric somatic hybrids between Lycopersicon esculentum and L. pennellii

Summary The organization of the mitochondrial genome and the genotype of the chloroplast genome was characterized using restriction fragment length polymorphisms in a population (82 individuals) of symmetric and asymmetric somatic hybrids of tomato. The protoplast fusion products were regenerated following the fusion of leaf mesophyll protoplasts of Lycopersicon esculentum (tomato cv UC82) with suspension cell protoplasts of L. pennellii that had been irradiated with 5, 10, 15, 25, 50, or 100 kRads from a gamma source. The chloroplast genome in the somatic hybrids showed a random pattern of inheritance, i.e., either parental genome was present in equal numbers of regenerants, while in asymmetric somatic hybrids, the chloroplast genotype reflected the predominant nuclear genotype, i.e., tomato. The mitochondrial genome in the symmetric somatic hybrids showed a non-random pattern of inheritance, i.e., predominantly from the L. pennellii parent; asymmetric somatic hybrids had more tomato-specific mitochondrial sequences than symmetric somatic hybrids. The non-random inheritance of the chloroplast and mitochondrial DNA in these tomato protoplast fusion products appears to be influenced by the nuclear background of the regenerant.     

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.     

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.     

Absence of mitochondrial and chloroplast DNA recombinations in Brassica napus plants regenerated from protoplasts,protoplast fusions and anther culture

Summary Over 400 Brassica napus plants regenerated from individual protoplasts, from protoplast fusions and from anther culture were analysed for chloroplast and mitochondrial genome rearrangements by restriction fragment length polymorphisms. None were detected, attesting to the fidelity of the tissue culture procedures employed. In the majority of protoplast fusion products, the cytoplasmic organelles had completely sorted out at the callus stage but three regenerated plants possessed mixed parental populations of mitochondrial genomes and one regenerant contained mixed chloroplast genomes. In all four examples, the cytoplasmic genome sorted out in planta in favor of one parental type which was faithfully maternally transmitted to progeny.     

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     

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     

Fertility and chromosome stability in Brassica napus resynthesised by protoplast fusion

Summary Fertile somatic hybrids between Brassica campestris and B. oleracea have been produced by protoplast fusion. Fusion products were identified by their intermediate protoplast morphology. Heterokaryons were isolated either with micropipettes using a micromanipulator or by flow sorting. About 2% of the obtained calli differentiated to shoots. Of the shoots obtained from manually selected heterokaryons, 100% were true hybrids as confirmed by isozyme analysis while 87% of the flow sorted ones showed a hybrid pattern. Ploidy level of the hybrid plants was determined by chromosome counting and relative DNA-content analysis. The sum of the chromosome number (38) from the two fusion partners were found in 30% of the hybrids; 9% had fewer and 61% had more chromosomes. Pollen viability and seed set varied with ploidy level. Compared to natural B. napus, a pollen viability of 52%–93% and a fertility of 1%–40% was found for the somatic hybrids with normal chromosome number. Restriction enzyme analysis of chloroplast-DNA showed that either B. campestris or B. oleracea chloroplasts were present in the somatic hybrid plants. Of 11 hybrid plants 5 had the campestris and 6 had the oleracea type (11 ratio).     

Asymmetric somatic hybridization between tall fescue (Festuca arundinacea Schreb.) and irradiated Italian ryegrass (Lolium multiflorum Lam.) protoplasts

Intergeneric asymmetric somatic hybrids have been obtained by the fusion of metabolically inactivated protoplasts from embryogenic suspension cultures ofFestuca arundinacea (recipient) and protoplasts from a non-morphogenic cell suspension ofLolium multiflorum (donor) irradiated with 10, 25, 50, 100, 250 and 500 Gy of X-rays. Regenerating calli led to the recovery of genotypically and phenotypically different asymmetric somatic hybridFestulolium plants. The genome composition of the asymmetric somatic hybrid clones was characterized by quantitative dot-blot hybridizations using dispersed repetitive DNA sequences specific to tall fescue and Italian ryegrass. Data from dot-blot hybridizations using two cloned Italian ryegrass-specific sequences as probes showed that irradiation favoured a unidirectional elimination of most or part of the donor chromosomes in asymmetric somatic hybrid clones obtained from fusion experiments using donor protoplasts irradiated at doses 250 Gy. Irradiation of cells of the donor parent with 500 Gy prior to protoplast fusion produced highly asymmetric nuclear hybrids with over 80% elimination of the donor genome as well as clones showing a complete loss of donor chromosomes. Further information on the degree of asymmetry in regenerated hybrid plants was obtained from chromosomal analysis including in situ hybridizations withL. multiflorum-specific repetitive sequences. A Southern blot hybridization analysis using one chloroplast and six mitochondrial-specific probes revealed preferentially recipient-type organelles in asymmetric somatic hybrid clones obtained from fusion experiments with donor protoplasts irradiated with doses higher than 100 Gy. It is concluded that the irradiation of donor cells before fusion at different doses can be used for producing both nuclear hybrids with limited donor DNA elimination or highly asymmetric nuclear hybrid plants in an intergeneric graminaceous combination. For a wide range of radiation doses tested (25–250Gy), the degree of the species-specific genome elimination from the irradiated partner seems not to be dose dependent. A bias towards recipient-type organelles was apparent when extensive donor nuclear genome elimination occurred.Abbreviations cpDNA Chloroplast DNA - 2, 4-D 2,4-dichlorophenoxyacetic acid - FDA fluorescein diacetate - IOA iodoacetamide - mtDNA mitochondrial DNA - RFLP restriction fragment length polymorphism     

Somatic hybrids between<Emphasis Type="Italic"> Arabidopsis thaliana</Emphasis> and cytoplasmic male-sterile radish (<Emphasis Type="Italic">Raphanus sativus</Emphasis>)

Somatic hybrids were produced by protoplast fusion between Arabidopsis thaliana ecotype Columbia and a male-sterile radish line MS-Gensuke (Raphanus sativus) with the Ogura cytoplasm. Forty-one shoots were differentiated from the regenerated calli and established as shoot cultures in vitro. About 20 of these shoots were judged to be hybrids based on growth characteristics and morphology. Molecular analyses of 11 shoots were performed, confirming the hybrid features. Of these 11 shoots, eight were established as rooted plants in the greenhouse. Polymerase chain reaction and randomly amplified polymorphic DNA analyses of the nuclear genomes of all analyzed shoots and plants confirmed that they contained hybrid DNA patterns. Their chromosome numbers also supported the hybrid nature of the plants. Investigations of the organelles in the hybrids revealed that the chloroplast (cp) genome was exclusively represented by radish cpDNA, while the mitochondrial DNA configuration showed a combination of both parental genomes as well as fragments unique to the hybrids. Hybrid plants that flowered were male-sterile independent of the presence of the Ogura CMS-gene orf138.Abbreviations CMS Cytoplasmic male sterilityCommunicated by M.R. Davey     

Intergeneric somatic hybrid production through protoplast fusion between Brassica juncea and Diplotaxis muralis

Summary The need to transfer genetic traits from Diplotaxis muralis (2n=42) to Brassica juncea (2n=36), a major oil seed crop of the tropical world, was realised. Since the two plant types are sexually incompatible, attempts were made to evolve parasexual hybrids as the result of protoplast fusion. Protoplasts of hypocotyl-derived calli of two cultivars of B. juncea were fused with normal and -irradiated mesophyll protoplasts of Diplotaxis muralis. Regeneration of 110 plants from the fused products was successfully achieved. Upon analysis of some of them, we realised that true somatic hybrids and partial somatic hybrids had been generated. Thus the primary goal of evolving intergeneric hybridisation products between these two plant types was fulfilled.     

Morphological and molecular characterization of fertile tetraploid somatic hybrids produced by protoplast electrofusion and PEG-induced fusion between Lycopersicon esculentum Mill. and Lycopersicon peruvianum Mill.

Summary Mesophyl protoplasts of two genotypes of cultivated tomato (Lycopersicon esculentum Mill.) and one of its wild relative species (Lycopersicon peruvianum Mill.) were fused by using electrofusion and polyethyleneglycol-induced fusion. Forty-three fertile tetraploid somatic hybrid plants, each deriving from separate calli, were recovered from both fusion procedures. Electrofusion appeared more efficient than chemical fusion for the production of somatic hybrids. These plants appeared morphologically similar, whatever the fusion procedure and tomato genotype. They had intermediate leaf, inflorescence, and flower morphology. After self-pollination, the hybrids set fruit of intermediate size and color. The hybrid nature of these plants was confirmed by isoelectric focusing of the Rubisco small subunits used as nuclear markers. L. esculentum and L. peruvianum were distinguished by means of two chloroplast markers: CF1-ATPase subunit as analyzed by isoelectro-focusing and ct DNA restriction patterns. All hybrids displayed both ct markers of only one parent with no biased transmission. Mitochondrial (mt) DNAs were prepared from flower buds by using miniaturized CsCl gradients. Preliminary analysis indicated that mt genomes from the hybrids all differed from those of both parents. mt DNA Sall restriction enzyme analysis revealed that all but two hybrids contained one novel fragment of 13.5 kb. Gene mapping experiments showed that the mt apocytochrome b and ATPase subunit 9 homologies in the somatic hybrid mt DNA resembled L. esculentum and L. peruvianum, respectively; the mt nad5 probe distinguished at least four distinct patterns in the hybrids. These results indicated that mt DNA rearrangements involving intergenomic recombinations occurred through protoplast fusion. A greater mt DNA polymorphism was induced with chemical fusion than with electrofusion.     

2,4-Dichlorophenoxyacetic acid affects mode and frequency of regeneration from hypocotyl protoplasts ofBrassica oleracea

Summary The effect of 2,4-dichlorophenoxyacetic acid (2,4-D) on the regeneration from hypocotyl protoplasts ofBrassica oleracea was studied by varying the 2,4-D concentration in the protoplast culture medium, 8 p, and the callus proliferation medium, K3. When hypocotyl protoplasts of the inbred line BL12 were cultured in the complete absence of 2,4-D, they divided and produced embryogenic calli. Moreover, these calli generated somatic embryos which were easily recognized by red cotyledons due to the presence of anthocyanin. When 2,4-D was present either in 8p medium or K3 medium the formation of somatic embryos was reduced. On the other hand, the number of shoot-forming calli increased considerably. We therefore conclude that 2,4-D directs the mode of regeneration by suppressing somatic embryogenesis in favour of shoot regeneration. Secondly, 2,4-D increases the regeneration efficiency. Furthermore, the callus proliferation phase on K3 medium is most important with respect to the determination of either somatic embryogenesis or shoot regeneration.Abbreviations BA benzyladenine - 2,4-D 2,4-dichlorophenoxyacetic acid - IAA indole acetic acid - NAA naphthalene acetic acid - PE plating efficiency     

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     

Protoplast culture and regeneration from Brassica oleracea ‘rapid cycling’ and other varieties

The results are reported for the first time on successful plant regeneration from mesophyll-derived protoplasts of rapid cycling B. oleracea. Comparative data were also presented on plant regeneration from mesophyll-derived protoplasts of two other varieties namely var. botrytis and var. gemmifera. It was found that a modified Pelletier (Pelletier et al. 1983) protocol is highly beneficial for protoplast culture and plant regeneration from mesophyll-derived protoplasts. The plating efficiency of B. oleracea rapid cycling protoplasts was, in the best combination of isolation method, culture technique and culture media 4.5%±0.4% and the plant regeneration frequency approximately 15%. Plant regeneration was further improved by transferring the calli from the D medium of Pelletier to a callus growth medium (MS11) and subsequently to the K₃ regeneration medium of Glimelius (Glimelius 1984). Various factors influencing plating efficiency and plant regeneration from mesophyll protoplasts of B. oleracea are discussed.Abbreviations BAP 6-benzylaminopurine - IAA 3-indoleacetic acid - IBA 3-indole butyric acid - NAA 1-naphtylacetic acid - 2iP N⁶-(2-isopentyl)adenine     

Nuclear-organelle interaction in Solanum: interspecific cybridizations and their correlation with a plastome dendrogram.

Summary Alloplasmic compatibility, namely the functional interaction between the nuclear genome of a given species with plastomes and chondriomes of alien species, is of considerable relevance in plant biology. The genus Solanum encompasses a wide spectrum of species and is therefore suitable for a study of this compatibility. We thus chose the nuclear genome of Solanum tuberosum (potato) and organelles (chloroplast and mitochondria) from 14 other Solanum species to initiate an investigation of intrageneric nucleus/organelle interactions. An assessment of the diversity of the chloroplast DNAs from these 15 species resulted in the construction of a plastome dendrogram (phylogenetic tree). In parallel we extended a previous study and performed ten additional fusion combinations by the donor-recipient protoplast fusion procedure, using potato protoplasts as recipients and protoplasts from any of ten other Solanum species as donors. We found that two fusion combinations did not yield cybrids and that the chloroplasts of S. polyadenium and the mitochondria (or mitochondrial components) from S. tarijense could not be transferred to cybrids bearing potato nuclei. In general, there is a correlation, albeit not perfect, between the cybridization data and the plastome dendrogram. These results furnish valuable information toward future transfer of plasmoneencoded breeding traits from wild Solanum species into potato. This information should also be useful for the planning of asymmetric protoplast fusion between potato and wild accessions for the improvement of pathogen and stress resistance of potato cultivars.     

Protoplast fusion mediated transfer of oligomycin resistance from Nicotiana sylvestris to Solanum tuberosum by intergeneric cybridization

Summary We have successfully bridged the intergeneric barriers between Nicotiana and Solanum with respect to chondriome transfer. To enable this transfer we utilized the donor-recipient protoplast-fusion procedure. Consequently protoplasts of a Nicotiana sylvestris line with putativly oligomycin-resistant mitochondria (line Oli ^R 38) were used as irradiated chondriome donors and iodoacetate-treated protoplasts of Solanum tuberosum cv. Desiree served as recipients. The plated fusion products as well as their derived colonies and calli were exposed to gradually increasing levels of oligomycin. The resulting plantlets had potato morphology and were analyzed with respect to their mitochondrial DNA and chloroplast DNA. Fifteen out of 50 regenerated plants were verified as true cybrids. Detailed analyses of one cybrid revealed chondriome components from the oligomycin-resistant donor line, Oli ^R 38, but retention of the plastome of potato. This cybrid was oligomycin-resistant as revealed by root-culture analysis. It was thus verified that due to selection, chondriome components could be transferred from a N. sylvestris donor into a cybrid having all the phenotypic features controlled by the nucleus of the recipient fusion partner (S. tuberosum).