Genome evolution & adaptation of the multinuclear wheat stripe rust fungus. Animals and plants package their genomes into a single nucleus within each cell. In contrast, millions of fungal species accommodate multiple nuclei containing individual haploid genomes. It is currently unknown what the evolutionary implications are for this unusual genome division into multiple nuclei. Here we explore the evolutionary consequences of genome division into multiple nuclei for the first time by applying c ....Genome evolution & adaptation of the multinuclear wheat stripe rust fungus. Animals and plants package their genomes into a single nucleus within each cell. In contrast, millions of fungal species accommodate multiple nuclei containing individual haploid genomes. It is currently unknown what the evolutionary implications are for this unusual genome division into multiple nuclei. Here we explore the evolutionary consequences of genome division into multiple nuclei for the first time by applying cutting edge genome biology tools and algorithms. The economically significant study system is the devastating wheat stripe rust fungus. This pathogen costs Australian farmers over $100 million a year. New understanding is expected to lead to better disease management, reduced fungicide applications, and increased yields.Read moreRead less
Fungal Glucanase Genes for Engineering Disease Resistance in Plants. Plants can be engineered for resistance to fungal diseases by transformation with recombinant genes encoding chitinase or glucanase. Although fungi are prolific producers of glucanases, with some species producing novel forms, they have been unexplored as a source of useful glucanases. This project will isolate glucanase-producing fungi from soil, screen them for antifungal activity, and clone the glucanase genes from one or m ....Fungal Glucanase Genes for Engineering Disease Resistance in Plants. Plants can be engineered for resistance to fungal diseases by transformation with recombinant genes encoding chitinase or glucanase. Although fungi are prolific producers of glucanases, with some species producing novel forms, they have been unexplored as a source of useful glucanases. This project will isolate glucanase-producing fungi from soil, screen them for antifungal activity, and clone the glucanase genes from one or more isolates. In view of the high degree of biodiversity in WA soils, we have a high expectation of finding novel glucanases which will be useful for engineering disease resistance in plants, or for other industrial processes.Read moreRead less
Molecular basis of synergy between PIs and defensins against fungi. The plant defensin nicotinamide adenine dinucleotide dehydrogenase subunit 1 (NaD1) has potent antifungal activity against agricultural and human pathogens and has potential in the treatment of serious diseases that affect crop production and human health. NaD1 has been found to permeabilise membranes and allows entry of other molecules into the fungal cytoplasm. While screening for molecules that enhance the activity of defensi ....Molecular basis of synergy between PIs and defensins against fungi. The plant defensin nicotinamide adenine dinucleotide dehydrogenase subunit 1 (NaD1) has potent antifungal activity against agricultural and human pathogens and has potential in the treatment of serious diseases that affect crop production and human health. NaD1 has been found to permeabilise membranes and allows entry of other molecules into the fungal cytoplasm. While screening for molecules that enhance the activity of defensins a number of proteinase inhibitors were identified that act synergistically with NaD1. This project aims to identify the molecular basis of this synergy which is expected to lead to better control of fungal diseases of crops and in humans.Read moreRead less