The first and second backcross progeny of the intergeneric fusion hybrids of potato and tomato after crossing with potato

Identification of alien chromosomes through GISH and RFLP analysis and the potential for establishing potato lines with monosomic additions of tomato chromosomes

To increase the potential for establishing a complete series of tomato chromosome addition–sbstitution lines in a potato background, six new BC1progeny were produced. All of them originated from crosses between three different hexaploid potato (+) tomato fusion hybrids. Three different somatic hybrids, viz., C31-17-5, C31-17-24, and C31-17-51, were used as female parents, and four different tetraploids, viz., Katahdin, Frieslander, 6704-1, and AM66.42 were used as male parents. A characterisation of the genomes of the three fusion hybrids and the six BC1progenies (6739, 2001, 2002, 2003, 2004, and 2005) through genomic in situ hybridization and restriction fragment length polymorphism (RFLP) analysis indicated that there was preferential tomato chromosome elimination in the fusion hybrids. Similar analyses of the six BC1progeny indicated that a variable number of the alien tomato chromosomes (6–11) were present in individual plants. RFLP analysis using chromosome specific DNA probes indicated that BC1progenies had retained all 12 tomato chromosomes, albeit in different individual plants. This means that the available BC1progenies have the potential for establishing a complete series of tomato chromosome addition–substitution lines in a potato background.Key words: protoplast fusion hybrids, Solanum tuberosum, Lycopersicon esculentum, BC1progeny, in situ hybridization, RFLP analysis.

Microprotoplast-mediated transfer of single specific chromosomes between sexually incompatible plants

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.