The role of low-energy excited states in solar-energy capture. This project aims to determine the nature and role of the lowest-energy excited states in most natural photosynthetic reaction centres and light-harvesting complexes. The lowest-energy states of bacterial reaction centres are critical to function and are used as a paradigm in artificial organic solar-energy capture, but for most photosystems their nature remains unknown. The project aims to answer the critical question of why they do ....The role of low-energy excited states in solar-energy capture. This project aims to determine the nature and role of the lowest-energy excited states in most natural photosynthetic reaction centres and light-harvesting complexes. The lowest-energy states of bacterial reaction centres are critical to function and are used as a paradigm in artificial organic solar-energy capture, but for most photosystems their nature remains unknown. The project aims to answer the critical question of why they do not actually prevent function. It is expected that both the outcomes obtained and techniques developed will be directly relevant to solar-energy device design. The project will apply five existing, complimentary and purposely built spectrometers as well as quantum electronic and nuclear simulation techniques to identify and characterise three key systems.Read moreRead less
Investigating the dynamic nature of antibody stability. The aim of the project is to provide insights into the molecular mechanisms of antibody stability. Monoclonal antibodies have transformed the study of biological processes and represent blockbuster therapeutics for cancer and inflammation. Unfortunately, antibodies often display limited stability, which greatly hinders development. Mutations have recently been identified that render human antibodies resistant to aggregation, and high-resolu ....Investigating the dynamic nature of antibody stability. The aim of the project is to provide insights into the molecular mechanisms of antibody stability. Monoclonal antibodies have transformed the study of biological processes and represent blockbuster therapeutics for cancer and inflammation. Unfortunately, antibodies often display limited stability, which greatly hinders development. Mutations have recently been identified that render human antibodies resistant to aggregation, and high-resolution crystal structures are being used to identify function. Intriguingly, preliminary data indicates that the mutations do not affect the native antibody structure, but rather influence dynamic states. The project plans to use a combination of mutagenesis, molecular dynamics simulation and deuterium exchange to study antibody dynamics.Read moreRead less
Structural studies of a reconstructed primordial antigen receptor. Antigen receptors (B- and T-cell receptor) form the basis of the adaptive immune system of humans and all other modern day vertebrates. These complex receptors are believed to have evolved from an extinct homodimeric (symmetrical) ancestor through a process of gene duplication and diversification. However, any molecular insights had so far remained elusive. Using laboratory evolution and X-ray crystallography this project demonst ....Structural studies of a reconstructed primordial antigen receptor. Antigen receptors (B- and T-cell receptor) form the basis of the adaptive immune system of humans and all other modern day vertebrates. These complex receptors are believed to have evolved from an extinct homodimeric (symmetrical) ancestor through a process of gene duplication and diversification. However, any molecular insights had so far remained elusive. Using laboratory evolution and X-ray crystallography this project demonstrates that such a primordial receptor can in principle be reconstructed and characterised. The project proposes to expand this work, which will provide intriguing insights into antigen receptor evolution. The reconstruction of basic recognition modules will also be highly beneficial for biosensor applications. Read moreRead less
Artificially building the bacterial flagellar motor. This project will allow us to learn how nature’s most sophisticated rotary motor works and how to build these artificially, establishing a new field of research into man-made biological machines. This has potential applications for the emerging field of nanotechnology to make nanometre-scale devices that are powered by efficient biological machines.
Phage display derived antibody fragments for membrane protein research. Membrane proteins are key components of all living organisms and represent more than 50 per cent of all drug targets. This project will redefine the way membrane proteins are studied and will be highly beneficial to basic research, human disease and the biotechnology industry.
Protein structure controls light harvesting in photosynthetic light algae. The strange phenomena of quantum mechanics were not expected to play a direct role in life, however, it appears that quantum effects may be important in the efficient capture of sunlight for photosynthesis. The conditions for the emergence of quantum phenomena appear to be set by the structures of proteins. The aim of this project is to relate protein structure to the emergence of quantum effects in the light harvesting p ....Protein structure controls light harvesting in photosynthetic light algae. The strange phenomena of quantum mechanics were not expected to play a direct role in life, however, it appears that quantum effects may be important in the efficient capture of sunlight for photosynthesis. The conditions for the emergence of quantum phenomena appear to be set by the structures of proteins. The aim of this project is to relate protein structure to the emergence of quantum effects in the light harvesting proteins of marine algae. Understanding the link between structure and quantum effects could improve our knowledge of how nature achieves its remarkable efficiency in utilising the energy from the sun. This is likely to foster new technologies that improve the efficiency of solar energy systems.Read moreRead less
Flick the biological quantum switch: light controls photosynthetic proteins. This project aims to determine whether light conditions dictate which proteins, and hence quantum properties, a marine alga selects. The protein structures determine whether non-trivial quantum effects are available to the alga. Expected outcomes include fostering new technologies which will provide significant benefits, such as improving the efficiency of solar energy systems.
Structural studies on chaperone protein machines from an Antarctic archeon. This project is to understand two fundamental biological processes, protein folding and prevention of RNA folding, that are crucial to all life, in particular, to survival in the cold. The project will determine the structure of the protein folding machine, showing how it works, and determine how RNA is protected after synthesis.
Imaging the T cell signalling machinery . The conversion of external stimuli to the interior of a cell is a fundamental process that underpins many unique facets of biology, including cellular movement, nerve transmission, response to hormones and immune recognition. However, the basic mechanism by which such signals are transmitted across cellular membranes is poorly understood. This proposal will seek to bridge this gap in our knowledge by imaging a multi-component “decision-making” machine th ....Imaging the T cell signalling machinery . The conversion of external stimuli to the interior of a cell is a fundamental process that underpins many unique facets of biology, including cellular movement, nerve transmission, response to hormones and immune recognition. However, the basic mechanism by which such signals are transmitted across cellular membranes is poorly understood. This proposal will seek to bridge this gap in our knowledge by imaging a multi-component “decision-making” machine that controls whether or not the immune system becomes activated. Accordingly, this proposal will provide far-reaching insights into molecular events that are of central importance to the initiation of immunity, and thus will ultimately benefit society via improvements in health.Read moreRead less
Breaching the defences: the role of hydrophobin protein monolayers in rice blast fungal infections. Rice blast is the most important disease of rice, causing significant reduction of rice yields worldwide. This project aims to understand how hydrophobin proteins from the rice blast fungus facilitate rice plant infections and to devise new methods that will safeguard Australian rice fields from this fungus.