ABSTRACT
Microprotoplast-mediated chromosome transfer (MMCT) through fusion of small (subdiploid) microprotoplasts of a transgenic triploid potato (Solanum tuberosum) cell line with leaf protoplasts of tobacco (Nicotiana tabacum) and the wild tomato species Lycopersicon peruvianum is reported. The microprotoplasts contained one or a few chromosomes. Monosomic addition plants were produced from the fusion products. We employed mass-scale induction of micronuclei in donor suspension cells of potato using the microtubule inhibitor Cremart. Protoplasts were isolated from micronucleated cells after incubation in a cell wall digesting enzyme mixture. The microprotoplasts were isolated from the micronucleated protoplasts by high-speed centrifugation. By using sequential filtration, small microprotoplasts containing one or few chromosomes were separated from the bigger subdiploid microprotoplasts. These small microprotoplasts were fused with recipient protoplasts of tobacco or tomato using polyethylene glycol. The selectable marker kanamycin resistance (KanR) and the reporter gene β-glucuronidase (gus), carried by the donor potato chromosome, were used for the selection of fusion products and the isolation of hybrid calli. Several monosomic addition plants were obtained within the short period of 3-4 months after fusion. These contained one potato chromosome carrying a single copy of gus and one or two copies of the neomycin phosphotransferase (nptII) gene conferring KanR, and the complete set of chromosomes of tobacco or tomato, as revealed by genomic in situ hybridization and Southern blot hybridization. The alien genes, gus and nptII, were stably expressed in both the tobacco and tomato backgrounds. They were transmitted to the progeny after backcrossing to tomato. Monosomic and disomic additions, and some introgression plants showing integration of gus and nptII in the tomato genome, were recovered in the first backcross progeny. The potential value of MMCT for the transfer of economically important traits, genome analysis, and gene expression is discussed. Key words : chromosome transfer, microprotoplast fusion, monosomic-disomic additions, sexual transmission, DNA integration, alien gene expression.
ABSTRACT
Results are reported on the transfer of single, specific chromosomes carrying kanamycin resistance (Kan(R)) and ß-glucuronidase (GUS) traits from a transformed donor line of potato (Solanum tuberosum) to a recipient line of the tomato species Lycopersicon peruvianum through microprotoplast fusion. Polyethylene glycol-induced mass fusion between donor potato microprotoplasts containing one or a few chromosomes and normal recipient diploid L. peruvianum protoplasts gave several Kan(R) calli. A high frequency of plants regenerated from Kan(R) calli expressed both Kan(R) and GUS, and contained one or two copies of npt-II and a single copy of gus. Genomic in situ hybridization showed that several microprotoplast hybrid plants had one single potato donor chromosome carrying npt-II and gus genes and the complete chromosome complement of the recipient L. peruvianum (monosomic additions). Several monosomic-addition hybrid plants could be regenerated within the short time of 3 months and they were phenotypically normal, resembling the recipient line. These results suggest that the transfer of single chromosomes is tolerated better than is the transfer of the whole donor genome. The unique advantages of microprotoplast fusion are discussed: these include the direct production of monosomic addition lines for the transfer and introgression of economically important traits in sexually-incongruent species, the construction of chromosome-specific DNA libaries, high-resolution physical mapping and the identification of alien chromosome domains related to gene expression.
ABSTRACT
Plant regeneration capacity was studied for 8 cultivars and 4 accessions of leek (A. ampeloprasum var. porrum L.). Compact callus was induced on embryo and leaf explants on three different media. The highest frequency of compact callus formation (up to 90%) was obtained when mature, zygotic embryos were cultured on MS medium, containing 30 g/l sucrose and 1 mg/l 2,4-D. Regeneration occurred through somatic embryogenesis on MS medium, supplemented with 1 mg/l kinetin. Plants could be regenerated from all cultivars and accessions tested. These cultivars and accessions could be classified into three groups with respect to shoot formation frequency. The results suggest a distinct influence of the genotype on the morphogenic response of leek embryo explants in vitro.
ABSTRACT
A series of fusion experiments were performed between protoplasts of a cytoplasmic albino mutant of tomato, Lycopersicon esculentum (ALRC), and gamma-irradiated protoplasts of L. hirsutum and the Solanum species S. commersonii, S. etuberosum and S. nigrum. These species were chosen for their different phylogenetic relationships to tomato. In all fusion combinations except from those between ALRC and S. nigrum, green calli were selected as putative fusion products and shoots regenerated from them. They were subsequently analyzed for their morphology, nuclear DNA composition and chloroplast DNA origin. The hybrids obtained between ALRC and L. hirsutum contained the chloroplasts of L. hirsutum and had the flower and leaf morphology of L. esculentum. After Southern blot analysis, using 13 restriction fragment length polymorphisms (RFLPs) randomly distributed over all chromosomes, all hybrids showed L. esculentum hybridization patterns. No chromosomes of L. hirsutum were found. These results indicate that these hybrids were true cybrids.The putative asymmetric hybrids, obtained with S. commersonii and S. etuberosum, showed phenotypic traits of both parents. After hybridization with species-specific repetitive nuclear DNA probes it was found that nuclear material of both parents was present in all plants. In the case of S. nigrum, which combination has the greatest phylogenetic distance between the fusion parents, no hybrid plants could be obtained. The chloroplast DNA of all hybrid plants was of the donor type suggesting that chloroplast transfer by asymmetric protoplast fusion can overcome problems associated with large phylogenetic distances between parental plants.
ABSTRACT
The organelles of somatic hybrids obtained from symmetric and asymmetric fusions between the Lycopersicon species L. peruvianum and L. esculentum were analyzed by DNA hybridization methods. In the asymmetric fusions the L. peruvianum protoplasts were gamma-irradiated at a dose of 50, 300 and 1,000 Gy. The organelles were characterized using the Petunia chloroplast probe pPCY64 and the mitochondrial EcoRI-SalI fragment of the Pcf gene. In all symmetric and asymmetric hybrid plants, a total of 73 being analyzed, only one of the parental chloroplast genomes was present, except for one hybrid plant which harbored both parental chloroplast genomes. No recombination and/or rearrangement in the chloroplast genome could be identified with the pPCY64 probe. Irradiation of the L. peruvianum protoplasts did not significantly reduce the fraction of asymmetric hybrids with L. peruvianum chloroplasts. A novel mitochondrial restriction pattern was present in 5 out of 24 hybrids tested. In 9 hybrids novel combinations of chloroplasts and mitochondria were found, indicating that both organelle types sorted out independently.
