Resolving the steps in the evolution of C4 photosynthesis. This project aims to identify the molecular mechanisms responsible for the evolution of grasses using the C4 biochemical pathway that enables plants to survive in hot, dry, high-light environments. The endemic Australian subtribe Neurachninae is the only known grass group that contains C4 species, species using the ancestral C3 pathway, as well as species using pathways intermediate to C3 and C4. Through a comparative approach employing ....Resolving the steps in the evolution of C4 photosynthesis. This project aims to identify the molecular mechanisms responsible for the evolution of grasses using the C4 biochemical pathway that enables plants to survive in hot, dry, high-light environments. The endemic Australian subtribe Neurachninae is the only known grass group that contains C4 species, species using the ancestral C3 pathway, as well as species using pathways intermediate to C3 and C4. Through a comparative approach employing high-throughput sequencing technologies, it is expected that the molecular changes underlying the transition from C3 to C4 will be identified. These results should define what is required to engineer plant varieties with increased yield and the ability to withstand climate change effects.Read moreRead less
The roles and regulators of new plant cells linked to root transport. Plant genomics has moved to the single cell resolution, allowing precise investigations of previously hidden cell types and cell states that respond to environmental stress and that vary among differentially adapted plant populations. Here, we will extend our pioneering efforts that have mapped and discovered novel root cell types, to determine their salt and nutrient stress responses, and to elegantly dissect the underling ca ....The roles and regulators of new plant cells linked to root transport. Plant genomics has moved to the single cell resolution, allowing precise investigations of previously hidden cell types and cell states that respond to environmental stress and that vary among differentially adapted plant populations. Here, we will extend our pioneering efforts that have mapped and discovered novel root cell types, to determine their salt and nutrient stress responses, and to elegantly dissect the underling causal genetic variation. The unique cell markers and regulatory networks will be validated with tissue specific and transgenic tools that can work across a host of plant species to reveal adaptive cellular responses to harsh environmental conditions.Read moreRead less
Regulators of protein translation reveal new pathways to plant productivity. This proposal aims to make transformative insights into the control of photosynthetic protein production. Photosynthesis is a key target for crop improvement that can address global food security. Improving photosynthesis requires precision control of photosynthetic proteins. It was unknown how this is achieved at the level of protein production. Excitingly, the team discovered how cellular protein production changes in ....Regulators of protein translation reveal new pathways to plant productivity. This proposal aims to make transformative insights into the control of photosynthetic protein production. Photosynthesis is a key target for crop improvement that can address global food security. Improving photosynthesis requires precision control of photosynthetic proteins. It was unknown how this is achieved at the level of protein production. Excitingly, the team discovered how cellular protein production changes in response to photosynthetic demand. The project strives to uncover how clusters of RNAs are decayed or translated into new proteins based on RNA features and linked binding proteins. This will allow manipulation of the accumulation of target proteins towards the goal of revealing unexplored ways to improve photosynthesis.Read moreRead less