Increased resistance to fungal wilts in transgenic eggplant expressing alfalfa glucanase gene.

The wilt diseases caused by Verticillium dahliae and Fusarium oxysporum are the major diseases of eggplant (Solanum melongena L.). In order to generate transgenic resistance against the wilt diseases, Agrobacterium-mediated gene transfer was performed to introduce alfalfa glucanase gene encoding an acidic glucanase into eggplant using neomycin phosphotransferase (npt-II) gene as a plant selection marker. The transgene integration into eggplant genome was confirmed by Polymerase chain reaction (PCR) and Southern blot analysis and transgene expression by the glucanase activity and western blot analysis. The selected transgenic lines were challenged with V. dahliae and F. oxysporum under in vitro and in vivo growth conditions, and transgenic lines showed enhanced resistance against the wilt-causing fungi with a delay of 5-7 days in the disease development as compared to wild-type plants.

ISSR and isozyme characterization of androgenetic dihaploids reveals tetrasomic inheritance in tetraploid somatic hybrids between Solanum melongena and Solanum aethiopicum group Gilo.

Gene exchanges between Solanum melongena and its allied relative Solanum aethiopicum are a crucial prerequisite for introgression of useful traits from the allied species into the cultivated eggplant. In order to evaluate the extent of genetic recombination between the 2 species, biochemical and molecular markers were employed. A dihaploid population obtained through anther culture of the corresponding tetraploid somatic hybrids was genetically analyzed. The extent of disomic/tetrasomic inheritance and segregation ratios of 3 isozyme systems and intersimple sequence repeat (ISSR) markers were evaluated. The dihaploids, being derived from microspores, allowed for simple, complete, and accurate analyses. The segregation of 280 ISSR markers (110 aethiopicum-specific, 104 melongena-specific, and 66 monomorphic) were evaluated in 71 dihaploids. According to the genetic constitution (simplex/duplex/triplex), almost 64% of the fragments revealed the tetrasomic and/or disomic inheritance. With regard to the assigned species-specific fragments, 68% and 4% were unambiguously the result of tetrasomic and disomic inheritance, respectively. Twenty-four of the 66 monomorphic ISSRs were inherited according to random chromatid segregation. The phenotypes of glucose-6-phosphate dehydrogenase (G-6-PDH), 6-phosphogluconate dehydrogenase (6-PGDH), and shikimate dehydrogenase (SKDH) were studied in 70 dihaploids and inferences were made about the allelic state of their 5 loci. The isozyme markers segregated in the dihaploids in a distorted manner, their segregations did not fit in with any of the expected segregation ratios. However, tetrasomic inheritance might be suggested for G-6-PDH 2 and SKDH 1 loci. Our results demonstrated that gene exchanges occurred readily in the somatic hybrids between S. melongena and S. aethiopicum gr. Gilo.

Effect of genotype, gelling agent, and auxin on the induction of somatic embryogenesis in sweet potato (Ipomoea batatas Lam.).

Lateral buds of six cultivars of sweet potato were induced to form embryogenic callus in a culture medium solidified with two types of gelling agents, Agar or Gelrite, and supplemented with various concentrations of auxins, 2,4-D, 2,4,5-T and Picloram. Of the six cultivars screened, only three gave an embryogenic response. Best results with an average of 3.53% embryogenic response were obtained with the medium solidified with Agar, while in Gelrite only 0.45% of lateral buds gave rise to embryogenic callus. The interaction between the genotype and auxins was highly significant; particularly the optimal response was obtained with cv. Zho and 865 yielding 10.7 and 14.7% somatic embryogenesis, respectively, in the medium containing 2,4,5-T or Picloram. The plant conversion was dramatically improved by subculture of the embryogenic callus on the medium with the combination of 1 microM 2,4-D and 1 microM Kinetin or 5 microM ABA alone before transfer of mature embryos onto hormone-free medium. The embryogenic callus of sweet potato and its sustained ability to further regenerate plants have regularly been maintained for several years by frequent subculture in 5 microM 2,4,5-T or the combination of 10 microM 2,4-D and 1 microM BAP or kinetin. The embryo-derived plants seemed apparently genetically stable and similar to the hexaploid parental plants, based on morphological analysis and their ploidy level determined by using flow cytometry.

Evaluation of somatic hybrids of potato with Solanum stenotomum after a long-term in vitro conservation.

Somatic hybrids of potato with a cultivated relative, Solanum stenotomum also called Solanum tuberosum Stenotomum group, were evaluated for their physiological and agronomical characteristics as well as the stability of the introgressed resistance to bacterial wilt, caused by Ralstonia solanacearum, after a long-term in vitro conservation for more than 5 years. Analysis of photosynthesis showed that the PEPC/Rubisco ratio remained lower than 0.5 for all vitroplants of potato and the somatic hybrids, except for the relative species. This indicates that the carbon metabolism is heterotrophic (ratio>1) for S. stenotomum, and autotrophic for potato and the somatic hybrids (ratio<1). In both in vitro and greenhouse conditions, potato and the somatic hybrids produced few bigger tubers, while many small tubers were obtained from the relative. The hybrid tubers were morphologically intermediate. The starch content of hybrid tubers was much lower than that of potato, but similar to that of the relative species. Interestingly, the level of bacterial resistance, introgressed from S. stenotomum into potato, was shown to be very stable and remained as high as that of the relative after a long-term period of in vitro conservation.

Production of potato intraspecific somatic hybrids with improved tolerance to PVY and Pythium aphanidermatum.

Somatic hybridization can be an interesting alternative for the selection of heterozygous and vigorous potato plants through combination of dihaploid genomes. The resulting hybrids can harbour interesting characters and thus can be used in agriculture if they are in agreement with agronomic criteria. In this report, we used an intraspecific somatic hybridization technique for the production of tetraploid potato lines. Two parental combinations were used in protoplast electrofusion procedure: Aminca-Cardinal and Cardinal-Nicola. The selection of somatic hybrids was based on in vitro plant vigour. Therefore, among the 75 regenerated plants obtained from Aminca-Cardinal fusion, 3 putative hybrids were retained and 2 plant lines were selected among the 54 regenerated from the Cardinal-Nicola fusion. Heterosis was observed in the larger hybrid tuber size compared to the parents'. Our results also showed a precocity in the in vitro tuberization for the hybrids. Moreover, all of the regenerated putative hybrids were tetraploid (2n=4x=48 chromosomes). Isocitrate dehydrogenase and malate dehydrogenase isoenzyme analyses confirmed the hybrid nature of these lines. A molecular characterization performed by PCR amplification of simple sequence repeats and inter-simple sequence repeats confirmed that all these lines were somatic hybrids. The effect of potato virus Y infection on these hybrid lines was tested by mechanical inoculation of plants cultivated in a greenhouse. The majority displayed a reduction of infection rate associated with a delayed appearance of symptoms compared to the parents. Moreover, complete resistance was noted for one hybrid line (CN2). All hybrids also showed improved tolerance to Pythium aphanidermatum infection during tuber storage or after plant inoculation.

The origin and evolution of sweet potato (Ipomoea batatas Lam.) and its wild relatives through the cytogenetic approaches.

The distribution and organization of 5S and 18S-5.8S-26S (18S) rDNA were studied in 10 varieties of hexaploid Ipomoea batatas, five accessions of tetraploid Ipomeoa trifida, and six related species (five diploids, I. trifida, I. triloba, I. tiliacea, I. leucantha and I. setosa and one tetraploid, I. tabascana), by using fluorescence in situ hybridization (FISH). The FISH data obtained indicated that polyploidization was followed by decrease in the number of 18S rDNA loci in higher ploidy level and provided evidence for major genomic rearrangements and/or diploidization in polyploid I. batatas. Among the five diploid species examined, I. trifida appeared to be the most closely related to I. batatas. By contrast, I. leucantha was closed to I. tiliacea, but both species were distant from sweet potato. I. triloba and I. setosa were distantly related to the rest of Ipomoea batatas complex. The close relationship between I. trifida and I. batatas was also demonstrated by the presence of one 18S and CMA marker in these two chromosome complements only. Based on chromosome morphology, tetraploid I. trifida appeared to be more closely related to sweet potato than I. tabascana. Taking all data obtained in this study, I. trifida might be the progenitor of I. batatas, and I. tabascana, interspecific hybrid between these two species.

Amplification of Nicotiana sylvestris mitochondrial subgenomes is under nuclear control and is associated with phenotypic changes.

We have previously shown the presence in a Nicotiana sylvestris protoplast-derived plant of both a nuclear mutation conferring male sterility (ms4) and a mtDNA reorganisation, named U, characterised by the amplification of substoichiometric mtDNA fragments generated by recombination in the parent T mtDNA. Here we show by physical mapping that the recombining repeats are in direct orientation, thus generating two subgenomes both of which are amplified in the U organisation to the detriment of the parent molecule, and are maintained through sexual reproduction. The nuclear ms4 mutation is likely to have play a role in the shift in mitochondrial molecule equilibrium, as higher levels of recombinant fragments were present in protoplast-derived T calli carrying the ms4 allele than in wild type calli or leaves. The MS4 gene could then lead to conflictual situation. However, subgenomic molecules were counter-selected during the regeneration process, suggesting the existence of different selective pressures in differentiated and non-differentiated cells. The U organisation is associated with higher stem height and late flowering, characters that may not be neutral from a selection point of view. The U equilibrium is an unusual example of sudden mtDNA reorganisation, without obvious differences in genetic information and with only a limited phenotypic impact.