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Unlocking secrets of fertility restoration for hybrid breeding in crops. Hybrid varieties give higher and more stable yields than conventional lines, but a cost-effective system to make hybrid seed on a commercial scale is still missing for economically important crops like wheat or barley. By elucidating the mode of action of a new type of restorer gene plus exploiting ancient or exotic wheat and barley collections this project will reveal aspects of largely understudied mechanisms underlying f ....Unlocking secrets of fertility restoration for hybrid breeding in crops. Hybrid varieties give higher and more stable yields than conventional lines, but a cost-effective system to make hybrid seed on a commercial scale is still missing for economically important crops like wheat or barley. By elucidating the mode of action of a new type of restorer gene plus exploiting ancient or exotic wheat and barley collections this project will reveal aspects of largely understudied mechanisms underlying fertility restoration in wheat and barley. The expected outcomes of the proposed research have the potential to deliver new tools for hybrid seed production programs in wheat and barley. Higher and more stable yields from hybrids will ensure food security in the face of an uncertain climate and growing human population.Read moreRead less
Establishing Vibrio natriegens as Ultra-Rapid Host for Synthetic Biology. This project aims to harness Vibrio natriegens, the world’s fastest-growing bacterium, as a microbial cell factory for synthetic biology and biotechnology. The project expects to develop new genetic tools and genetically-engineered microbes that can rapidly transform cheap feedstocks, such as plastic waste, into valuable chemicals and bioplastics. Expected outcomes include new knowledge on the mechanisms driving V. natrieg ....Establishing Vibrio natriegens as Ultra-Rapid Host for Synthetic Biology. This project aims to harness Vibrio natriegens, the world’s fastest-growing bacterium, as a microbial cell factory for synthetic biology and biotechnology. The project expects to develop new genetic tools and genetically-engineered microbes that can rapidly transform cheap feedstocks, such as plastic waste, into valuable chemicals and bioplastics. Expected outcomes include new knowledge on the mechanisms driving V. natriegens’ rapid growth, as well as building Australian multidisciplinary research capacity in synthetic biology that can translate this potential into bio-manufacturing processes. Significant benefits include the means to cut plastic pollution in our environment and to provide the basis for a carbon-negative chemical industry.Read moreRead less
Regulation and role of metabolic networks for respiration in plants. This project aims to understand the regulation of respiration in plants which underpins the energy provision that cells need to operate. Understanding respiration and how it responds to the changing environment is a building block needed for rational engineering of our future food from plants.
Targeting mitochondrial dysfunction in disease. Defects in mitochondria, the energy producing compartments within cells, lead to severe neurodegenerative diseases and contribute to the development of cancer. Treatment for such diseases caused by mutations in mitochondrial DNA remains unsatisfactory and mostly confined to supportive measures. The identification of proteins that regulate gene expression within mitochondria provides an unexplored resource of potential disease modulators and drug ta ....Targeting mitochondrial dysfunction in disease. Defects in mitochondria, the energy producing compartments within cells, lead to severe neurodegenerative diseases and contribute to the development of cancer. Treatment for such diseases caused by mutations in mitochondrial DNA remains unsatisfactory and mostly confined to supportive measures. The identification of proteins that regulate gene expression within mitochondria provides an unexplored resource of potential disease modulators and drug targets. This research will lead to new strategies in the design of improved anticancer drugs, which is an important Australian research priority that will promote and maintain good health, and provide potential commercial outcomes.Read moreRead less
Characterizing the regulators of mitochondrial biogenesis in Arabidopsis thaliana. The overall aim of this project is to identify and characterise the underlying regulatory factors that control mitochondrial mass and number in plants. The project will exploit a regulatory mechanism that links the mitochondrial import machinery and the respiratory chain. Utilising both forward and reverse genetic approaches, the abundances of protein import translocases will be altered and the changes to mitochon ....Characterizing the regulators of mitochondrial biogenesis in Arabidopsis thaliana. The overall aim of this project is to identify and characterise the underlying regulatory factors that control mitochondrial mass and number in plants. The project will exploit a regulatory mechanism that links the mitochondrial import machinery and the respiratory chain. Utilising both forward and reverse genetic approaches, the abundances of protein import translocases will be altered and the changes to mitochondrial biogenesis will be investigated. This will identify regulatory factors, which can be manipulated and used to alter mitochondrial number and activity.Read moreRead less
Crops for a phosphorus-scarce future: plant adaptation to fluctuating phosphorus availability. Phosphorus is commonly used on farmland to ensure high yields. However, rock phosphate reserves are declining and leaching of phosphorus from farmlands into native vegetation and water bodies causes significant environmental degradation. As a result, more phosphorus-efficient farming systems are urgently required. Many Australian native plants have adapted to low phosphorus soils and fast fluctuations ....Crops for a phosphorus-scarce future: plant adaptation to fluctuating phosphorus availability. Phosphorus is commonly used on farmland to ensure high yields. However, rock phosphate reserves are declining and leaching of phosphorus from farmlands into native vegetation and water bodies causes significant environmental degradation. As a result, more phosphorus-efficient farming systems are urgently required. Many Australian native plants have adapted to low phosphorus soils and fast fluctuations in phosphorus availability. This project aims to investigate plant adaptations to phosphorus fluctuations and the potential for storing phosphorus when it is abundant for later use. This should aid development of crops with improved phosphorus fertiliser-use efficiency in anticipation of a phosphorus-scarce future.Read moreRead less
Developmental functions of oxygen and redox cues in plants. This project aims to transform our understanding of the regulation of meristem functions, with a central hypothesis that plant cell quiescence (repressed cell division) is governed by oxygen and oxidation/reduction (redox)-dependent cues. Meristems are the growing tips of plants, and thus the fundamental unit of plant growth and productivity. This project will develop new knowledge of how plants integrate changes in the environment to r ....Developmental functions of oxygen and redox cues in plants. This project aims to transform our understanding of the regulation of meristem functions, with a central hypothesis that plant cell quiescence (repressed cell division) is governed by oxygen and oxidation/reduction (redox)-dependent cues. Meristems are the growing tips of plants, and thus the fundamental unit of plant growth and productivity. This project will develop new knowledge of how plants integrate changes in the environment to regulate meristem activity. This project will define new paradigms of how oxygen and redox status interact with energy and other cues to regulate decisions to grow or quiesce. This will underpin the development of new strategies to optimise crop management and productivity, improve the efficiency of inputs, and reduce the risk of decision making in crop production.Read moreRead less
Deciphering the Thermal Acclimation of Mitochondrial Respiration. Plants acclimate to the extremes of temperature following a pre-exposure to a sub-lethal increase/decrease in temperature. Recent research has revealed that proteins of oxidative phosphorylation and the tricarboxylic acid (TCA) cycle are dynamic and change their abundance in response to temperature change. Harnessing a cutting edge protein mass spectrometry approach, this project seeks to better understand how mitochondrial respir ....Deciphering the Thermal Acclimation of Mitochondrial Respiration. Plants acclimate to the extremes of temperature following a pre-exposure to a sub-lethal increase/decrease in temperature. Recent research has revealed that proteins of oxidative phosphorylation and the tricarboxylic acid (TCA) cycle are dynamic and change their abundance in response to temperature change. Harnessing a cutting edge protein mass spectrometry approach, this project seeks to better understand how mitochondrial respiration and hence adenosine triphosphate (ATP) production is maintained during temperature change. Uniquely this project will examine this in both the model plant Arabidopsis and wheat and combine both tissue, environment-induced and genotype variation to reveal a new understanding of the thermal acclimation of this major mitochondrial process.Read moreRead less
Unlocking a new hormone signalling system to increase plant performance. This project seeks to discover new ways to improve crop productivity by investigating a recently identified chemical signalling pathway in plants that affects seed germination, seedling growth, leaf development and water use. The aims are to identify unknown signalling compounds that work through this pathway, to discover the molecular regulators of the pathway, and to examine how it operates in different plant species. The ....Unlocking a new hormone signalling system to increase plant performance. This project seeks to discover new ways to improve crop productivity by investigating a recently identified chemical signalling pathway in plants that affects seed germination, seedling growth, leaf development and water use. The aims are to identify unknown signalling compounds that work through this pathway, to discover the molecular regulators of the pathway, and to examine how it operates in different plant species. The project also plans to exploit this pathway to find inhibitors of premature seed germination that afflict crops such as wheat and barley. The intended outcomes are a better understanding of how plants grow and new strategies for boosting plant performance in the field. Specific potential applications include reducing plant water use, regulating seed germination, and encouraging early seedling establishment. Read moreRead less
Genetic evolution of plant proteins with biomedical applications. This project will draw upon a unique combination of skills in plant genetics and biomedical research to demonstrate that plants are not just a source of novel drugs. The results will show that they also provide a powerful biotechnological platform for the discovery, understanding, design and production of new pharmaceuticals.