Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100127
Funder
Australian Research Council
Funding Amount
$355,000.00
Summary
Superresolution fluorescence imaging in microbiology. Superresolution fluorescence imaging in microbiology:
This project involves the purchase of new, and upgrade of existing, fluorescence imaging tools to facilitate the study of intracellular processes in microbial systems at significantly higher spatial and temporal resolutions than hitherto possible. Visualisation of the structure and dynamics of intracellular molecular assemblies at maximal resolution is required to understand protein funct ....Superresolution fluorescence imaging in microbiology. Superresolution fluorescence imaging in microbiology:
This project involves the purchase of new, and upgrade of existing, fluorescence imaging tools to facilitate the study of intracellular processes in microbial systems at significantly higher spatial and temporal resolutions than hitherto possible. Visualisation of the structure and dynamics of intracellular molecular assemblies at maximal resolution is required to understand protein function inside living cells. The new equipment is designed to provide a fast super-resolution imaging system to study the intracellular dynamics of proteins in vitro and a super-resolution microscope to visualise structures and assemblies inside microbes with a resolution of tens of nanometres, putting in vitro biochemistry into the context of a living cell. Read moreRead less
Australian Laureate Fellowships - Grant ID: FL140100027
Funder
Australian Research Council
Funding Amount
$2,898,150.00
Summary
Under the hood: single-molecule studies of multi-protein machines. Under the hood: single-molecule studies of multi-protein machines. Living cells are filled with complex protein machines that are responsible for the molecular processes supporting life. This project is aimed towards the development of physical tools that enable the study of these protein complexes at the level of single molecules. This project aims to study the protein machinery responsible for DNA replication, the process of du ....Under the hood: single-molecule studies of multi-protein machines. Under the hood: single-molecule studies of multi-protein machines. Living cells are filled with complex protein machines that are responsible for the molecular processes supporting life. This project is aimed towards the development of physical tools that enable the study of these protein complexes at the level of single molecules. This project aims to study the protein machinery responsible for DNA replication, the process of duplicating genomic information before cell division. By making real-time single-molecule movies of the replication process, this project aims to unravel the molecular mechanisms of this important process and provide the knowledge required to understand disease mechanisms and catalyse drug development.Read moreRead less
Visualising chaperones disentangle and refold proteins - one molecule at a time. Chaperones are enzymes that maintain the proper function of proteins in the cell. This research aims to visualise, at the single molecule level, how chaperones facilitate the folding of individual proteins and how they can disentangle proteins that have aggregated as a result of cell stress.