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

Progress in plant protoplast research

In this review we focus on recent progress in protoplast regeneration, symmetric and asymmetric hybridization and novel technology developments. Regeneration of new species and improved culture techniques opened new horizons for practical breeding in a number of crops. The importance of protoplast sources and embedding systems is discussed. The study of reactive oxygen species effects and DNA (de)condensation, along with thorough phytohormone monitoring, are in our opinion the most promising research topics in the further strive for rationalization of protoplast regeneration. Following, fusion and fragmentation progress is summarized. Genomic, transcriptomic and proteomic studies have led to better insights in fundamental processes such as cell wall formation, cell development and chromosome rearrangements in fusion products, whether or not obtained after irradiation. Advanced molecular screening methods of both genome and cytoplasmome facilitate efficient screening of both symmetric and asymmetric fusion products. We expect that emerging technologies as GISH, high resolution melting and next generation sequencing will pay major contributions to our insights of genome creation and stabilization, mainly after asymmetric hybridization. Finally, we demonstrate agricultural valorization of somatic hybridization through enumerating recent introgression of diverse traits in a number of commercial crops.

Production and analysis of asymmetric hybrid plants between monocotyledon (Oryza sativa L.) and dicotyledon (Daucus carota L.)

Asymmetric hybrid plants were obtained from fused protoplasts of a monocotyledon (Oryza sativa L.) and a dicotyledon (Daucus carota L.). X-ray-irradiated protoplasts isolated from a cytoplasmic malesterile (cms) carrot suspension culture were fused with iodoacetoamide-treated protoplasts isolated from a 5-methyltryptophan (5MT)-resistant rice suspension culture by electrofusion. The complementary recovered cells divided and formed colonies, which were then cultivated on regeneration medium supplemented with 25mg/l 5MT to eliminate any escaped carrot cells. Somatic hybrids were regenerated from 5 of the 5MT-resistant colonies. The morphologies of most of the regenerated plants closely resembled that of the parental carrot plants. A cytological analysis of callus cultures induced from these plants indicated that most of the cells possessed 20-22 chromosomes and were resistant to 5MT. An isozyme analysis revealed that several regenerated plants had the peroxidase isozyme patterns of both parents. A Southern hybridization analysis with non-radioactively labelled DNA fragments of the rgp1 gene showed that regenerated plants had hybridizing bands from both rice and carrot. Chloroplast (cp) and mitochondrial (mt) DNAs were also analyzed by Southern hybridization by using several probes. CpDNA patterns of the regenerated plants were indistinguishable from those of the carrot parent. However 1 of the regenerated plants had a novel band pattern of mtDNA that was not detected in either of the parents, indicating a possible recombination of mitochondrial genomes.

Cybrid production based on mutagenic innactivation of protoplasts and rescuing of mutant plastids in fusion products: Potato with a plastome fromS. bulbocastanum andS. pinnatisectum

A procedure for cybrid production, based on double treatment of donor protoplasts by physical and afterwards chemical mutagens at superlethal doses (γ-irradiation at a dose of 1000 Gy was applied for the inactivation of nuclei; 3-5 mMN-nitroso-N-methylurea was used for the efficient induction of plastome mutation) and the rescuing of mutant plastids after fusion with untreated recipient protoplasts, was developed. For identification of mutant donor-type plastids in fusion products a selection for streptomycin was performed. In two sets of experiments, in whichS. tuberosum served as the recipient of foreign cytoplasm with the wild tuber-bearing speciesS. bulbocastanum andS. pinnatisectum as donors, a total of about 40 streptomycin-resistant colonies was isolated. Eight regenerants from theS. tuberosum+S. bulbacastanum fusion combination and four fromS. tuberosum+S. pinnatisectum were further investigated using chromosome counting, analysis of esterase isoenzymes, restriction analysis of organelle DNA, and blot hybridization. All but one plant from both combinations were characterised as potato cybrids possessing exclusively foreign plastids and retaining a morphology typical of the recipient. Only in one line was rearranged mtDNA detected. The availability of potato cybrids facilitates the analysis of plastome-encoded breeding traits and the identification of the most valuable source of cytoplasm among the wild potato species. The described system for producing cybrids without genetic selectable markers in the parental material offers the possibility for the rescue of cytoplasmic mutations which are impossible to isolate by conventional approaches.

Production of somatic hybrids between Daucus carota L. and Nicotiana tabacum

Protoplasts of a kanamycin-resistant (KR, nuclear genome), streptomycin-resistant (SR, chloroplast genome) and chlorophyll-deficient (A1, nuclear genome) Nicotiana tabacum (KR-SA) cell suspension cultures or X-ray-irradiated mesophyll protoplasts of kanamycin- and streptomycin-resistant green plants (KR-SR) were fused with protoplasts of a cytoplasmic male-sterile (CMS) Daucus carota L. cell suspension cultures by electrofusion. Somatic hybrid plants were selected for kanamycin resistance and the ability to produce chlorophyll. Most of the regenerated plants had a normal D. carota morphology. Callus induced from these plants possessed 23-32 chromosomes, a number lower than the combined chromosome number (66) of the parents, and were resistant to kanamycin, but they segregated for streptomycin resistance, which indicated that N. tabacum chloroplasts had been eliminated. Genomic DNA from several regenerated plants was analyzed by Southern hybridization for the presence of the neomycin phosphotransferase gene (NPTII); all of the plants analyzed were found to contain this gene. Mitochondrial (mt) DNA was analyzed by Southern hybridization of restriction endonuclease digests of mtDNA with two DNA probes, PKT5 and coxII. The results showed that the two plants analyzed possessed the mitochondria of D. carota. These results demonstrate that the regenerated plants are interfamilial somatic hybrids.

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

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 plasmone-encoded 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.