The role of N-linked protein glycosylation in Campylobacter jejuni. It is estimated that 300,000 Campylobacter jejuni (C. jejuni) infections occur in Australia annually, causing a vast economic loss. This project will assist in the understanding of the role of glycosylation and will significantly aid in determining how C. jejuni colonises humans and poultry and lead to the discovery of interventions to reduce the organism in poultry for human consumption.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100007
Funder
Australian Research Council
Funding Amount
$650,000.00
Summary
A research platform for exploring the genotype: phenotype nexus. This project will allow us to connect the genetic code of an organism with its characteristic traits that are essential for its survival. The equipment will accelerate research that performs this translation, and will allow leading Australian scientists to continue to make breakthroughs in this field globally.
Functional Dissection of the Bacterial Replisome. This project aims to develop and use a suite of new single-molecule techniques to define how the bacterial replisome really works. The replisome is the machine that makes DNA in cells that are about to divide. Replisomes have many mechanistic challenges as they work to copy both strands of DNA at the same time. Many years of classic biochemical studies have worked out how many of these challenges are overcome. In recent years, the use of single-m ....Functional Dissection of the Bacterial Replisome. This project aims to develop and use a suite of new single-molecule techniques to define how the bacterial replisome really works. The replisome is the machine that makes DNA in cells that are about to divide. Replisomes have many mechanistic challenges as they work to copy both strands of DNA at the same time. Many years of classic biochemical studies have worked out how many of these challenges are overcome. In recent years, the use of single-molecule biophysical techniques has begun to challenge many aspects of the elegant textbook view of replisome function. This approach is expected to reveal how synthesis of the two DNA strands in different directions at the same time is coupled together and how timing mechanisms work.Read moreRead less
A functional dissection of the bacterial replisome. This project aims to study the replisome, the machine that duplicates DNA before cell division. Years of biochemical research has shown how its protein components work, but observation at the single-molecule level is needed to understand how they all work together. This project aims to combine novel single-molecule biophysical tools with state-of-the-art biochemistry to define how the bacterial replisome coordinates synthesis of the two DNA str ....A functional dissection of the bacterial replisome. This project aims to study the replisome, the machine that duplicates DNA before cell division. Years of biochemical research has shown how its protein components work, but observation at the single-molecule level is needed to understand how they all work together. This project aims to combine novel single-molecule biophysical tools with state-of-the-art biochemistry to define how the bacterial replisome coordinates synthesis of the two DNA strands and how it exchanges protein components on the fly. Expected outcomes of this project include improved understanding of a fundamental biological process, development of novel biophysical methodology, and training of the next generation of interdisciplinary scientists.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100078
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Establishment of a comprehensive regional biophysical analysis facility. Interactions between molecules are needed for cells to function correctly. This facility will permit comprehensive molecular characterisation as well as research into the fundamentals of how molecules interact.
Discovery and characterisation of novel lanthipeptide biopreservatives. The aim of this project is to advance fundamental knowledge of microbial metabolism and provide natural anti-microbial molecules to the Australian food industry. A quarter of the world’s food supply is lost because of microbiological spoilage. Some chemical preservatives have been developed to combat food spoilage organisms, however their chronic impact on human health is the subject of debate. Consumer demand for safe and n ....Discovery and characterisation of novel lanthipeptide biopreservatives. The aim of this project is to advance fundamental knowledge of microbial metabolism and provide natural anti-microbial molecules to the Australian food industry. A quarter of the world’s food supply is lost because of microbiological spoilage. Some chemical preservatives have been developed to combat food spoilage organisms, however their chronic impact on human health is the subject of debate. Consumer demand for safe and natural alternatives is growing. Paradoxically, microbially-produced bioactive peptides may be the key to combating food spoilage organisms and food-borne pathogens. To this end, the project intends to develop an innovative strategy for the discovery, biosynthesis and characterisation of novel anti-microbial lanthipeptides.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100149
Funder
Australian Research Council
Funding Amount
$590,000.00
Summary
Reaching new heights in high-resolution electron microscopy . High-resolution electron microscopy (EM): Direct electron detection cameras are a recent technological breakthrough delivering one of the greatest single advancements to the field of molecular cryo-EM. The aim of this project is to enable a 'first of a kind' cryo-EM platform in Australia enabling high-throughput atomic resolution protein structure determination. This will be achieved by integrating a state-of-the-art Gatan K2 Summit D ....Reaching new heights in high-resolution electron microscopy . High-resolution electron microscopy (EM): Direct electron detection cameras are a recent technological breakthrough delivering one of the greatest single advancements to the field of molecular cryo-EM. The aim of this project is to enable a 'first of a kind' cryo-EM platform in Australia enabling high-throughput atomic resolution protein structure determination. This will be achieved by integrating a state-of-the-art Gatan K2 Summit Direct Electron Detection camera system into the established cryo-EM facility managed by the University of Queensland node of the Australian Microscopy and Microanalysis Facility. This will offer unique and significantly improved capabilities for atomic resolution protein structure analysis, and will support a broad range of projects across the biological sciences.Read moreRead less
New guardians of the mucosa: Molecular characterisation of M cell biology. We aim to completely define the cellular and molecular biology of gut and lung M cells for the first time. We will elucidate how they develop, are regulated and function at a molecular level, and how M cells maintain normal gut and lung tissues and induce immune responses to protect against microbial challenges. In the future, the new insights will be essential pre-requisites for the development of mucosal-based intervent ....New guardians of the mucosa: Molecular characterisation of M cell biology. We aim to completely define the cellular and molecular biology of gut and lung M cells for the first time. We will elucidate how they develop, are regulated and function at a molecular level, and how M cells maintain normal gut and lung tissues and induce immune responses to protect against microbial challenges. In the future, the new insights will be essential pre-requisites for the development of mucosal-based interventions and vaccines that protect the gut and lung from infectious and inflammatory issues. The harnessing of effective immune responses to control such challenges, are of enormous fundamental and long-standing biological interest, and are amongst the most important areas of current scientific research.Read moreRead less
Roadblocks in DNA replication. This project aims to develop the technology to visualise and understand the molecular processes responsible for the faithful copying of cellular DNA in the presence of roadblocks caused by chemical pressures and competing intracellular events. Understanding this process is important as DNA replication is responsible for copying the DNA genetic blueprint of cells and is crucial to all life on earth. This project will have as key outcomes the development of novel mol ....Roadblocks in DNA replication. This project aims to develop the technology to visualise and understand the molecular processes responsible for the faithful copying of cellular DNA in the presence of roadblocks caused by chemical pressures and competing intracellular events. Understanding this process is important as DNA replication is responsible for copying the DNA genetic blueprint of cells and is crucial to all life on earth. This project will have as key outcomes the development of novel molecular visualisation technology and the first molecular description of the dynamic processes used by the DNA-replication machinery to navigate roadblocks. These outcomes should provide significant benefits including enhanced collaboration and scientific capacity in Australia.Read moreRead less
Future Industries Research - Biotechnology and Nanotechnology: Small talk: Communication networks in microbes. We will use the Australian Proteome Analysis Facility to address the multifaceted mechanisms of microbial interactions and produce new knowledge about the pathogen Pseudomonas aeruginosa, a common cause of death in cystic fibrosis patients. We will characterise the interactions between P. aeruginosa and the emerging fungal pathogen Scedosporium aurantiacum as a proactive step towards be ....Future Industries Research - Biotechnology and Nanotechnology: Small talk: Communication networks in microbes. We will use the Australian Proteome Analysis Facility to address the multifaceted mechanisms of microbial interactions and produce new knowledge about the pathogen Pseudomonas aeruginosa, a common cause of death in cystic fibrosis patients. We will characterise the interactions between P. aeruginosa and the emerging fungal pathogen Scedosporium aurantiacum as a proactive step towards better understanding of pathogen communication. Improved understanding of pathogen interactions should facilitate the development of novel anti-adhesives as therapeutics. Our project will train young scientists in a new integrated approach to biology.Read moreRead less