Correlation between hordatine accumulation, environmental factors and genetic diversity in wild barley (Hordeum spontaneum C. Koch) accessions from the Near East Fertile Crescent.

Wild barley shows a large morphological and phenotypic variation, which is associated with ecogeographical factors and correlates with genotypic differences. Diversity of defense related genes and their expression in wild barley has been recognized and has led to attempts to exploit genes from H. spontaneum in breeding programs. The aim of this study was to determine the variation in the accumulation of hordatines, which are Hordeum-specific preformed secondary metabolites with strong and broad antimicrobial activity in vitro, in 50 accessions of H. spontaneum from different habitats in Israel. Differences in the accumulation of hordatines in the seedling stage were significant between different H. spontaneum genotypes from different regional locations and micro-sites. Variation in the hordatine accumulation within genotypes was between 9% and 45%, between genotypes from the same location between 13% and 38%, and between genotypes from different locations up to 121%. Principal component analysis showed that water related factors explain 39%, temperature related factors explain 33% and edaphic factors account for 11% of the observed variation between the populations of H. spontaneum. Genetic analysis of the tested accessions with LP-PCR primers that are specific for genes involved in the biosynthetic pathway of hordatines showed tight correlations between hordatine abundance and genetic diversity of these markers. Multiple regression analyses indicated associations between genetic diversity of genes directly involved in hordatine biosynthesis, ecogeographical factors and the accumulation of hordatines.

Transposon-mediated single-copy gene delivery leads to increased transgene expression stability in barley.

Instability of transgene expression in plants is often associated with complex multicopy patterns of transgene integration at the same locus, as well as position effects due to random integration. Based on maize transposable elements Activator (Ac) and Dissociation (Ds), we developed a method to generate large numbers of transgenic barley (Hordeum vulgare var Golden Promise) plants, each carrying a single transgene copy at different locations. Plants expressing Ac transposase (AcTPase) were crossed with plants containing one or more copies of bar, a selectable herbicide (Basta) resistance gene, located between inverted-repeat Ds ends (Ds-bar). F(1) plants were self-pollinated and the F(2) generation was analyzed to identify plants segregating for transposed Ds-bar elements. Of Ds-bar transpositions, 25% were in unlinked sites that segregated from vector sequences, other Ds-bar copies, and the AcTPase gene, resulting in numerous single-copy Ds-bar plants carrying the transgene at different locations. Transgene expression in F(2) plants with transposed Ds-bar was 100% stable, whereas only 23% of F(2) plants carrying Ds-bar at the original site expressed the transgene product stably. In F(3) and F(4) populations, transgene expression in 81.5% of plants from progeny of F(2) plants with single-copy, transposed Ds-bar remained completely stable. Analysis of the integration site in single-copy plants showed that transposed Ds-bar inserted into single- or low-copy regions of the genome, whereas silenced Ds-bar elements at their original location were inserted into redundant or highly repetitive genomic regions. Methylation of the non-transposed transgene and its promoter, as well as a higher condensation of the chromatin around the original integration site, was associated with plants exhibiting transgene silencing.

An efficient method for dispersing Ds elements in the barley genome as a tool for determining gene function.

To devise a method for function-based gene isolation and characterization in barley, we created a plasmid containing the maize Activator (Ac) transposase (AcTPase) gene and a negative selection gene, codA, and a plasmid containing Dissociation (Ds) inverted-repeat ends surrounding the selectable herbicide resistance gene, bar. These plasmids were used to stably transform barley (Hordeum vulgare). In vitro assays, utilizing a Ds-interrupted uidA reporter gene, were used to demonstrate high-frequency excisions of Ds when the uidA construct was introduced transiently into stably transformed, AcTPase-expressing plant tissue. Crosses were made between stably transformed plants expressing functional transposase under the transcriptional control of either the putative AcTPase promoter or the promoter and first intron from the maize ubiquitin (Ubi1) gene, and plants containing Ds-Ubi-bar. In F(1) plants from these crosses, low somatic and germinal transposition frequencies were observed; however, in F(2) progeny derived from individual selfed F(1) plants, up to 47% of the plants showed evidence of Ds transposition. Further analyses of F(3) plants showed that approximately 75% of the transposed Ds elements reinserted into linked locations and 25% into unlinked locations. Transposed Ds elements in plants lacking the AcTPase transposase gene could be reactivated by reintroducing the transposase gene through classical genetic crossing, making this system functional for targeted gene tagging and studies of gene function. During the analysis of F(3) plants we observed two mutant phenotypes in which the transposed Ds elements co-segregate with the new phenotype, suggesting the additional utility of such a system for tagging genes.

Negative selection systems for transgenic barley (Hordeum vulgare L.): comparison of bacterial codA- and cytochrome P450 gene-mediated selection.

Efficient negative selection systems are increasingly needed for numerous applications in plant biology. In recent years various counter-selectable genes have been tested in six dicotyledonous species, whereas there are no data available for the use of negative selection markers in monocotyledonous species. In this study, we compared the applicability and reliability of two different conditional negative selection systems in transgenic barley. The bacterial codA gene encoding cytosine deaminase, which converts the non-toxic 5-fluorocytosine (5-FC) into the toxic 5-fluorouracil (5-FU), was used for in vitro selection of germinating seedlings. Development of codA-expressing seedlings was strongly inhibited by germinating the seeds in the presence of 5-FC. For selecting plants in the greenhouse, a bacterial cytochrome P450 mono-oxygenase gene, the product of which catalyses the dealkylation of a sulfonylurea compound, R7402, into its cytotoxic metabolite, was used. T1 plants expressing the selectable marker gene showed striking morphological differences from the non-transgenic plants. In experiments with both negative selectable markers, the presence or absence of the transgene, as predicted from the physiological appearance of the plants under selection, was confirmed by PCR analysis. We demonstrate that both marker genes provide tight negative selection; however, the use of the P450 gene is more amenable to large-scale screening under greenhouse or field conditions.