Developing technologies that support the genetic modification of rats. Rats and the mouse play critical roles in medical research. Until recently, the targeted genetic modification of a mammal was limited to the mouse. This was due to a technology that was unique to the mouse: embryonic stem (ES) cells. These cells have not been isolated from any other species. The recent development of animal cloning allows for an alternate strategy for targeting genes. We propose to develop cloning strate ....Developing technologies that support the genetic modification of rats. Rats and the mouse play critical roles in medical research. Until recently, the targeted genetic modification of a mammal was limited to the mouse. This was due to a technology that was unique to the mouse: embryonic stem (ES) cells. These cells have not been isolated from any other species. The recent development of animal cloning allows for an alternate strategy for targeting genes. We propose to develop cloning strategies in the rat that supports the genetic modification of this animal. The development of this technology will bring considerable benefits to the areas of physiological research and drug design.Read moreRead less
Enabling Technologies for Structural Genomics. New technologies will be developed to save time, money and effort in rapid preparation of protein samples for structural genomics. Systems will be devised for preparing sufficient isotope-labelled proteins for nuclear magnetic resonance spectroscopy without using living organisms, for efficiently identifying points at which proteins can be broken into smaller fragments with the right properties, and for joining the ends of proteins and peptides toge ....Enabling Technologies for Structural Genomics. New technologies will be developed to save time, money and effort in rapid preparation of protein samples for structural genomics. Systems will be devised for preparing sufficient isotope-labelled proteins for nuclear magnetic resonance spectroscopy without using living organisms, for efficiently identifying points at which proteins can be broken into smaller fragments with the right properties, and for joining the ends of proteins and peptides together to make them much more stable. This combination of technologies are widely applicable to current problems in protein chemistry, molecular biology, functional genomics and the medical sciences.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