Evaluation of transgenic approaches for controlling tuber moth in potatoes.

A wide spectrum of strategies to genetically engineer potato plants resistant to potato tuber moth, Phthorimaea operculella (Zeller), have been investigated. The potato cv Iwa was transformed with a range of genes under the transcriptional control of the CaMV 35S promoter using Agrobacterium-mediated gene transfer. The transferred genes encode protease inhibitors (spleen inhibitor and alpha1-antitrypsin inhibitor), biotin-binding proteins (avidin and streptavidin) and Cry proteins (crylAc9, cry1Ba1, crylCa5 and cry9Aa2). Of these three transgenic approaches, cry genes have proved the most useful. In order to control the expression of the cry genes in foliage and not in the tubers a light-inducible Lhca3 promoter from potato was also used. The interaction of different cry genes was investigated using an experimental approach to simulate gene pyramiding in potato. Potato plants transgenic for both the crylAc9 and cryAa2 genes were developed and evaluated to help provide a more durable resistance to potato tuber moth.

Genetic engineering of crops as potential source of genetic hazard in the human diet.

The benefits of genetic engineering of crop plants to improve the reliability and quality of the world food supply have been contrasted with public concerns raised about the food safety of the resulting products. Debates have concentrated on the possible unforeseen risks associated with the accumulation of new metabolites in crop plants that may contribute to toxins, allergens and genetic hazards in the human diet. This review examines the various molecular and biochemical mechanisms by which new hazards may appear in foods as a direct consequence of genetic engineering in crop plants. Such hazards may arise from the expression products of the inserted genes, secondary or pleiotropic effects of transgene expression, and random insertional mutagenic effects resulting from transgene integration into plant genomes. However, when traditional plant breeding is evaluated in the same context, these mechanisms are no different from those that have been widely accepted from the past use of new cultivars in agriculture. The risks associated with the introduction of new genes via genetic engineering must be considered alongside the common breeding practice of introgressing large fragments of chromatin from related wild species into crop cultivars. The large proportion of such introgressed DNA involves genes of unknown function linked to the trait of interest such as pest or disease resistance. In this context, the potential risks of introducing new food hazards from the applications of genetic engineering are no different from the risks that might be anticipated from genetic manipulation of crops via traditional breeding. In many respects, the precise manner in which genetic engineering can control the nature and expression of the transferred DNA offers greater confidence for producing the desired outcome compared with traditional breeding.

Flank matrix attachment regions (MARs) from chicken, bean, yeast or tobacco do not prevent homology-dependent trans-silencing in transgenic tobacco plants.

The effect of flanking matrix attachment regions (MARs) on homology-dependent trans-silencing was tested using two strong trans-silencing loci. The transgenic tobacco line 271 carries at a single locus a p35S-RiN-tNos transgene which is able to silence, in trans and at the transcriptional level, the expression of any p35S-driven transgene irrespective of its position. The transgenic tobacco line 6b8 carries at a single locus a p35S-uidA-tRbcS transgene which is able to silence in trans, at the post-transcriptional level, the expression of any uidA-expressing transgene irrespective of its position. Various transgenic tobacco lines carrying a target p35S-uidA-tNos transgene, flanked on each side by MARs from chicken, bean, yeast or tobacco, were crossed with lines carrying the 271 and 6b8 loci. Expression of the target transgene was silenced in all hybrids, irrespective of the presence or absence of MAR sequences. These results therefore demonstrate that MARs are not able to protect transgene expression from strong silencing loci that act in trans.

Energy dissipation as a key factor for electroporation of protoplasts.

Energy dissipation (epsilon) during electroporation was theoretically determined to be epsilon = 0.5CV02 for the various combinations of capacitance (C) and initial voltage (V0). Experiments on asparagus protoplasts established that electroporation efficiency (EE) and survival rate were directly proportional to energy dissipation during electroporation. A positive linear relationship exists between energy dissipation per unit volume and EE, whereas energy dissipation per unit volume and survival rate of protoplasts are related in a negative linear manner. At the same energy level, longer time constants were more effective at increasing EE. This suggests that energy dissipation approximating rectangular waveforms is more important than that dissipated as sharply decaying exponential waveforms. With energy as the key parameter, the optimization of electrical parameters for efficient electroporation is greatly simplified, is not machine-dependent, and generally applies to all species.

Dissection of a synthesized quantitative trait to characterize transgene interactions.

Six transgenic tobacco lines, each homozygous for the beta-glucuronidase (GUS) gene at a different locus, and wild type were selfed and intercrossed to evaluate GUS activity in all possible hemizygous, homozygous and dihybrid combinations of GUS alleles. The transgenic lines are characterized by their GUS activity (two low, three intermediate, one high), T-DNA complexity (four single-copy, two more complex single-locus) and the presence of the chicken lysozyme matrix-associated region (MAR) around the full T-DNA (two lines). Gene action and interaction was analyzed by weighted linear regression with parameters for additivity, dominance and epistasis. The analysis showed that each of the four single-copy lines acted fully additively. In contrast, the two complex single-locus lines showed classical single-locus overdominance and were epistatic dominant over all other GUS alleles. The latter is manifested in severe suppression of GUS activity in dihybrid lines, irrespective of the presence of MAR elements around the GUS gene. Such elements apparently do not protect against epistatic dominance. The quantitative data suggested that the epistatic dominance and overdominance are based on the same molecular mechanism. Our approach of a genetic analysis of quantitative variation in well-characterized transgenic lines provides a powerful tool to gain insight into complex plant traits.

Biological potential of extraterrestrial materials. 2. Microbial and plant responses to nutrients in the Murchison carbonaceous meteorite.

Meteoritic materials are investigated as potential early planetary nutrients. Aqueous extracts of the Murchison C2 carbonaceous meteorite are utilized as a sole carbon source by microorganisms, as demonstrated by the genetically modified Pseudomonas fluorescence equipped with the lux gene. Nutrient effects are observed also with the soil microorganisms Nocardia asteroides and Arthrobacter pascens that reach populations up to 5 x 10(7) CFU/ml in meteorite extracts, similar to populations in terrestrial soil extracts. Plant tissue cultures of Asparagus officinalis and Solanum tuberosum (potato) exhibit enhanced pigmentation and some enhanced growth when meteorite extracts are added to partial nutrient media, but inhibited growth when added to full nutrient solution. The meteorite extracts lead to large increases in S, Ca, Mg, and Fe plant tissue contents as shown by X-ray fluorescence, while P, K, and Cl contents show mixed effects. In both microbiological and plant tissue experiments, the nutrient and inhibitory effects appear to be best balanced for growth at about 1:20 (extracted solid : H2O) ratios. The results suggest that solutions in cavities in meteorites can provide efficient concentrated biogenic and early nutrient environments, including high phosphate levels, which may be the limiting nutrient. The results also suggest that carbonaceous asteroid resources can sustain soil microbial activity and provide essential macronutrients for future space-based ecosystems.

Reconsideration of pollen dispersal data from field trials of transgenic potatoes.

During the initial field evaluation of transgenic plants, it is usual to isolate them genetically from other plants of the same species. Several field experiments on potatoes, using transgenes as markers, have shown that transgene dispersal by pollen to other potato plants is limited and very unlikely at distances over 10 m. In a recent study in Sweden, a frequency of transgene-containing progeny of over 30% is reported from non-transgenic potato plants grown at distances of 10-1000 m from transgenic plants containing nptII and gus marker genes. Data from the Swedish study is discussed along with other relevant observations, and it is concluded that the high frequency of gene dispersal in that study results from a high frequency of false positives during PCR analysis of the nptII gene. From the data available in potato, it is concluded that a distance of 20 m is generally adequate for the initial field evaluation of transgenic potatoes containing novel gene constructs.

pBINPLUS: an improved plant transformation vector based on pBIN19.

We describe the construction of a new plant transformation vector, pBINPLUS, based on the popular pBIN19 vector. Improvements over pBIN19 include location of the selectable marker gene at the left T-DNA border, a higher copy number in E. coli, and two rare restriction sites around the multiple cloning site for easier cloning and analysis of T-DNA insertions in plant genomes.

The MAR-Mediated Reduction in Position Effect Can Be Uncoupled from Copy Number-Dependent Expression in Transgenic Plants.

To study the role of matrix-associated regions (MARs) in establishing independent chromatin domains in plants, two transgenes were cloned between chicken lysozyme A elements. These transgenes were the neomycin phosphotransferase (NPTII) gene under control of the nopaline synthase (nos) promoter and the [beta]-glucuronidase (GUS) gene controlled by the double cauliflower mosaic virus (dCaMV) 35S promoter. The A elements are supposed to establish an artificial chromatin domain upon integration into the plant DNA, resulting in an independent unit of transcriptional regulation. Such a domain is thought to be characterized by a correlated and position-independent, hence copy number-dependent, expression of the genes within the domain. The presence of MARs resulted in a higher relative transformation efficiency, demonstrating MAR influence on NPTII gene expression. However, variation in NPTII gene expression was not significantly reduced. The selection bias for NPTII gene expression during transformation could not fully account for the lack of reduction in variation of NPTII gene expression. Topological interactions between the promoter and A element may interfere with the A element as a domain boundary. In contrast, the GUS gene on the same putative chromatin domain showed a highly significant reduction in variation of gene expression, as expected from previous results. Surprisingly, no copy number-dependent GUS gene expression was observed: all plants showed approximately the same GUS activity. We concluded, therefore, that dCaMV 35S-GUS gene expression in mature tobacco plants is regulated by some form of dosage compensation.

Identification of a Genetic Locus in Pseudomonas aureofaciens Involved in Fungal Inhibition.

In iron-rich conditions, Pseudomonas aureofaciens PA147-2 produces an antibiotic-like compound that inhibits the growth of a plant fungal pathogen, Aphanomyces euteiches. To contribute to the potential use of PA147-2 as a biocontrol organism, we report the identification of a genetic locus important for antibiotic biosynthesis. Mutants defective for fungal inhibition (Af) were generated by Tn5 mutagenesis. Southern hybridization of total DNAs from three Af mutants indicated that loss of fungal inhibition was due to a single Tn5 insertion in each mutant. Restriction mapping of the mutation points showed that in two mutants the Tn5 insertions were in the same 16.0-kb EcoRI fragment and were separated by 2.1 kb. A genomic library of PA147-2 was constructed and screened by using a region of DNA flanking the Tn5 insertion in one mutant (PA109) as a probe to recover complementing cosmids. Three cosmids containing a 16.0-kb EcoRI fragment complementary to the two mutants were recovered. Allele replacement by homologous recombination with putative complementing cosmids restored one mutant to antifungal activity against A. euteiches. Southern analysis of the complemented mutants confirmed that allele replacement had occurred between cosmid DNA and Tn5. The wild-type 16.0-kb EcoRI fragment was cloned from the cosmid and complemented the two mutants to antifungal activity. An antifungal compound was isolated from PA147-2 grown on solid medium. Antifungal activity correlated to a peak on high-pressure liquid chromatography analysis. Under the same growth and extraction conditions, the antifungal activity seen in PA147-2 was absent in two Af mutants. Furthermore, absence of an antifungal compound in each mutant correlated to the absence of the wild-type "antifungal" peak on high-pressure liquid chromatography analysis.

Strategies for the selection and characterization of aluminum-resistant variants from cell cultures of Nicotiana plumbaginifolia.

The development of strategies for selecting and characterizing aluminum-resistant variants from Nicotiana plumbaginifolia Viv. cell cultures is described. Plated cells, smeared callus, in-vitro-grown shoots, and seedlings of wild-type N. plumbaginifolia all showed similar responses to Al, with total growth inhibition at or above 600 µM Al. The strict control of both cell density and aggregate size is important in selection experiments for total inhibition of the growth of wild-type cells. Two approaches for the selection of Al-resistant variants were used. In a direct method, cells were plated onto medium containing 600 µM Al which inhibited growth and chlorophyll synthesis in wildtype cells. A double selection strategy based on both cell growth and greening was used to isolate 29 Al-resistant variants. In the other approach, a rescue method, suspensions were cultured for 10 d in medium containing 600 µM Al, then plated onto standard medium for recovery of survivors. Using this strategy, 217 Al-resistant variants were selected. After six to twelve weeks of growth in the absence of Al, each variant was cloned and reselected from single cells. Al resistance was retained in 31% and 51% of the variants selected by the direct and rescue strategies, respectively. Seedling segregation data are presented for the progeny (selfed and backcrossed) of plants regenerated from one of the variants and are consistent with those expected for a single dominant mutation.

Large scale selection of aluminum-resistant mutants from plant cell culture: expression and inheritance in seedlings.

A large number of aluminum-resistant variants, selected from non-mutagenized homozygous diploid cell cultures of Nicotiana plumbaginifolia Viv., are characterized. Of 115 variants cloned and reselected from single cells, 67 retained Al resistance in callus cultures after 6-9 months of growth in the absence of Al. There was no association between Al resistance and callus growth in the absence of Al, suggesting that the Al-resistant phenotype is not detrimental in the absence of Al challenge and that Al resistance is not the result of increased vigor. Plants regenerated from initially resistant callus lines that subsequently lost their resistance failed, with one exception, to transmit resistance to their seedling progeny. Fertile plants were regenerated from 40 of the 67 variants that retained stable Al resistance in callus culture. All 40 transmitted Al resistance to their seedling progeny (selfed and backcrossed) in segregation ratios expected for a single dominant mutation. The selfed progeny of many variants also segregated for recessive lethal mutations which were attributed to independent mutations that occurred during cell culture.