Engineering and expression of recombinant antibodies that interact with plant pathogenic phytoplasma membrane proteins - a model for phytoplasma disease management. . In Australia phytoplasmas are associated with serious diseases including papaya dieback and strawberry lethal yellows. Phytoplasmas cannot be cultured so there is a paucity of knowledge at the genomic level. We have identified the ABC Transporter and FtsH genes and expressed these phytoplasma membrane proteins (MP) in E. coli . We ....Engineering and expression of recombinant antibodies that interact with plant pathogenic phytoplasma membrane proteins - a model for phytoplasma disease management. . In Australia phytoplasmas are associated with serious diseases including papaya dieback and strawberry lethal yellows. Phytoplasmas cannot be cultured so there is a paucity of knowledge at the genomic level. We have identified the ABC Transporter and FtsH genes and expressed these phytoplasma membrane proteins (MP) in E. coli . We will generate antibody fragments that bind these MP and express them in tomato. We will analyse antibody expression in tomato and study their association with the phytoplasma membrane. Transgenic plants will be inoculated with phytoplasma and monitored for resistance. This work represents a major step towards engineering resistance to phytoplasmas.Read moreRead less
Are flavonoids metabolic regulators of plant development? This project will investigate the mechanisms of action of flavonoids, which are abundant and diverse plant products contained in all fruits and vegetables. We have very little knowledge on the range of activities this large class of natural compounds has in plants. This research will investigate the role of flavonoids in regulating plant development to identify flavonoids and their target proteins and genes that could alter plant develo ....Are flavonoids metabolic regulators of plant development? This project will investigate the mechanisms of action of flavonoids, which are abundant and diverse plant products contained in all fruits and vegetables. We have very little knowledge on the range of activities this large class of natural compounds has in plants. This research will investigate the role of flavonoids in regulating plant development to identify flavonoids and their target proteins and genes that could alter plant development in specific ways to create improved crops. This project will also strengthen Australia's expertise in proteomics, an important tool for the advancement of knowledge and application in biotechnology.Read moreRead less
Characterisation of interacting genes that condition avirulence and resistance between Phytophthora pathogens and soybean. Plant pathogens from the genus Phytophthora cause severe crop losses in Australia and worldwide. Resistance in host plants is frequently overcome by mutation of avirulence genes in the pathogen to create virulent new races. We will clone and characterise genes from Phytophthora sojae that control virulence and avirulence, and isolate soybean genes whose products interact w ....Characterisation of interacting genes that condition avirulence and resistance between Phytophthora pathogens and soybean. Plant pathogens from the genus Phytophthora cause severe crop losses in Australia and worldwide. Resistance in host plants is frequently overcome by mutation of avirulence genes in the pathogen to create virulent new races. We will clone and characterise genes from Phytophthora sojae that control virulence and avirulence, and isolate soybean genes whose products interact with the Phytophthora gene products. An understanding of the molecular mechanisms than enable current plant varieties to recognise Phytophthora pathogens leading to resistance or susceptibility will assist the development of novel strategies for durable disease resistance in soybean and other crop plants.Read moreRead less
Efficient organelle transformation. Chloroplasts and mitochondria are the powerhouses of plant and animal cells. Ability to express introduced genes in these organelles has enormous biotechnological potential in agriculture and medicine, but practical development has been almost stalled for 15 years by very low transformation efficiency. Plastid transformation is today routine only in tobacco; and mitochondrial transformation has been achieved only in yeasts and algae. We have developed a soluti ....Efficient organelle transformation. Chloroplasts and mitochondria are the powerhouses of plant and animal cells. Ability to express introduced genes in these organelles has enormous biotechnological potential in agriculture and medicine, but practical development has been almost stalled for 15 years by very low transformation efficiency. Plastid transformation is today routine only in tobacco; and mitochondrial transformation has been achieved only in yeasts and algae. We have developed a solution, and achieved the key technical requirements for proof of concept. This collaboration between industry, government and university partners will deliver key Australian-owned IP, for environmentally-friendly plant biofactories, and for treatment of mitochondrial genetic disorders.Read moreRead less
Molecular, physiological and environmental regulation of toxic prussic acid levels (cyanogenesis) in forage sorghum. Forage sorghum is grown widely in dry, tropical areas of Australia. The leaves contain dhurrin, a natural defence product that liberates prussic acid (cyanide) when leaf tissue is disrupted (eg when chewed). The problem is that young plants or those experiencing drought are highly toxic, resulting in financial loss through reduced nutritive value, livestock loss and wasted feed. U ....Molecular, physiological and environmental regulation of toxic prussic acid levels (cyanogenesis) in forage sorghum. Forage sorghum is grown widely in dry, tropical areas of Australia. The leaves contain dhurrin, a natural defence product that liberates prussic acid (cyanide) when leaf tissue is disrupted (eg when chewed). The problem is that young plants or those experiencing drought are highly toxic, resulting in financial loss through reduced nutritive value, livestock loss and wasted feed. Using new, non-GM technology we will identify novel genetically altered sorghum lines with negligible prussic acid. Lines with enhanced levels could be used as soil biofumigants. Breeders can use this germplasm to develop varieties tailored for increasingly dry Australian conditions. The new varieties with controlled dhurrin content will be suitable for export.Read moreRead less
Circular Plant Proteins with Pharmaceutical Applications. The proposed research will develop methods for using plants as protein production factories. Initially I will use plants to create engineered cyclotides that incorporate peptides with proven therapeutic activity against cancer and multiple sclerosis. Successful production of therapeutic proteins in plants will benefit Australians by making treatments for these and other diseases more accessible. It also has the potential for a major econo ....Circular Plant Proteins with Pharmaceutical Applications. The proposed research will develop methods for using plants as protein production factories. Initially I will use plants to create engineered cyclotides that incorporate peptides with proven therapeutic activity against cancer and multiple sclerosis. Successful production of therapeutic proteins in plants will benefit Australians by making treatments for these and other diseases more accessible. It also has the potential for a major economic benefit from the sales of Australian-based drugs. This proposal will also provide outstanding research training for graduate students in multidisciplinary methods that constitute state-of the-art structural and plant molecular biology.Read moreRead less