Molecular characterisation of differentially expressed genes in the interaction of barley and Rhynchosporium secalis.

Abstract

The barley scald pathogen (Rhynchosporium secalis) causes extensive economic losses, not only through lost product and quality, but also due to costs associated with chemical control. Economic and environmental impacts and the emerging resistance to fungicides and dominant resistance genes are reasons to understand molecular defence responses in order to develop new strategies to increase resistance of barley to this pathogen. In most pathosystems, defence gene expression in susceptible or resistant genotypes commonly differs quantitatively. Thus, differentially expressed genes between genotypes contrasting for response to infection by pathogens are considered candidate genes that have a role in resistance. This thesis presents functional analysis of a subset of genes isolated from a Suppression Subtractive Hybridisation library. The library was previously established and enriched for differentially expressed genes in epidermis of resistant and susceptible near-isogenic barley cultivars inoculated with R. secalis. Functional characterisation involved both investigating their putitative biochemical function as well as the genes‟ role(s) in biotic and abiotic stress responses. Three cDNA clones from the library were selected based on the putative function of the encoded proteins and the full length of the clones and their homologues were isolated from cDNA and genomic DNA. One of the clones represented a member of the pathogenesis-related protein family 17 (PR-17). Southern hybridisation showed that a small multigene family encodes the barley PR-17 proteins. Three members were cloned with two of them being novel. The second clone was homologous to galactinol synthases (GolS) and Southern blot analysis indicated existence of two GolS genes in the barley genome and subsequently two HvGolS members were isolated. The last clone (a single gene) showed similarity to very long chain fatty acid elongases, which indicates its involvement in synthesis of cuticular waxes. A characterised Arabidopsis mutant named fiddlehead (Atfdh) was highly similar to this gene and it was named HvFdh. Detailed expression analysis using Q-PCR, Northern blot analysis and publically available microarray data revealed that the isolated genes are regulated in response to a variety of abiotic and biotic stresses as well as different tissues during barley development. Under some treatments expression patterns were consistent with their putative roles and in agreement with results of other studies. Nevertheless, in other treatments expression profiles were not in agreement with previous findings in other plants indicating potentially different stress adaptation mechanisms between species. Further insight into the function of the encoded proteins was gained by their subcellular localisation using transient expression as GFP fusion proteins followed by confocal laser scanning microscopy. The results were in agreement with in silico predictions and their putative cellular function. In addition, a comprehensive list of homologous genes from other species was compiled for each gene by using public EST databases. Analyses of phylogenetic relationship and multiple sequence alignment of the homologues provided further clues to their function and conserved regions of the proteins. HvPR-17 anti-fungal properties were investigated by heterologous protein expression in E. coli and subsequent in vitro bioassays using purified protein under different conditions against a number of phytopathogenic fungi. However, no anti-fungal activity was observed. A construct with the AtFdh promoter driving the coding region of barley Fiddlehead was used for complementation of the Arabidopsis fiddlehead mutant to investigate functional orthology between these genes from dicots and monocots. The Arabidopsis fiddlehead mutant phenotype that shows contact-mediated organ fusion, germination of spore on epidermis and reduced number of trichomes was completely reverted by HvFdh. Finally, more than fifty transgenic barley lines were regenerated over-expressing or suppressing one of the three genes. The analyses of the transgenic progeny exhibited some interesting developmental phenotypes and resistance to scald and drought tolerance. These lines are awaiting further experiments to investigate the effect of altered expression in conferring resistance to other pathogens and abiotic stress tolerance as well as biochemical analysis. Collectively, in this work six barley genes were cloned and characterised by a variety of in silico techniques, temporal and transient expression analyses, subcellular localisation, in vitro bioassays and mutant complementation in Arabidopsis and loss- and gain-of-function transgenic barley plants. This work has provided insight into the function of these gene families in barley. Furthermore, the data suggest that they are regulated by the defence response to pathogenic fungi as well as drought, salinity and frost in barley.