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
From energy stress to hormones: new signals in bacteria and plants. This project will use molecular tools to detect and identify new chemical signals, known as butenolides, that regulate the growth and development of bacteria and plants. This project will use innovative, interdisciplinary techniques to discover where these butenolide signals come from, and how both bacteria and plants detect them. Expected outcomes of this project include a greater understanding of how plants use butenolides to ....From energy stress to hormones: new signals in bacteria and plants. This project will use molecular tools to detect and identify new chemical signals, known as butenolides, that regulate the growth and development of bacteria and plants. This project will use innovative, interdisciplinary techniques to discover where these butenolide signals come from, and how both bacteria and plants detect them. Expected outcomes of this project include a greater understanding of how plants use butenolides to cope with stress such as drought or salinity, and the design of new technologies for manipulating the growth of both plants and bacteria. The long-term benefits of this work should include fresh approaches for enhancing plant performance under sub-optimal conditions.Read moreRead less