The role of a novel protein, interferon epsilon, in reproductive tract immunity. This project aims to develop a world-first description of a new protein that has a protective role against female reproductive tract infections. This unique protein, called interferon epsilon, was discovered in our laboratory. This project will facilitate development of new therapeutic approaches of benefit in diseases such as Chlamydia and Herpes Simplex Virus.
Mechanisms connecting diet, metabolism, gut microbiota and immunity. This project will identify the role of short chain fatty acids and the G-protein coupled receptor (GPR43) in regulating immune responses. This could explain how diet affects immune responses and also how certain bacteria in the gut provide benefits for immune defence.
To Describe The Regional Differences In The Innate Immune System Of The Skin Using Intra-vital Multiphoton Microscopy And Understand Its Functional Consequences In A Cutaneous Parasite Infection Model.
Funder
National Health and Medical Research Council
Funding Amount
$97,182.00
Summary
This study is the first of its kind to map the innate immune system, the body's first line of defence, in the skin - coined the "immune atlas". Researchers have shown regional differences in innate immune cells which could explain how infections develop at different sites of the body. Although they have shown this in a cutaneous leishmaniasis model, a parasite endemic in most parts of the world, it may have implications also for inflammatory skin conditions such as eczema or psoriasis.
Nuclear alarmins escalate tissue immune responses. Humans and other animals are constantly exposed to potential threats, including microbes on and near the body. Animals can live with such dangers because these everyday encounters are made harmless by the immune system. It is unclear how cells distinguish low-danger threats from high-danger threats. This proposal seeks to reveal how immune cells identify increasing levels of threat and appropriately escalate their responses. Expected outcomes in ....Nuclear alarmins escalate tissue immune responses. Humans and other animals are constantly exposed to potential threats, including microbes on and near the body. Animals can live with such dangers because these everyday encounters are made harmless by the immune system. It is unclear how cells distinguish low-danger threats from high-danger threats. This proposal seeks to reveal how immune cells identify increasing levels of threat and appropriately escalate their responses. Expected outcomes include new insights into how immune cells and tissues respond according to the posing threat. Project benefits include understanding how to manipulate danger responses for future basic research and commercial applications, and fundamental understanding of how animals flourish in a dangerous world.Read moreRead less
A novel mechanism of host defence via macrophage extracellular traps. Animal health relies upon innate immune cells to rapidly detect invading microbes and induce inflammatory and antimicrobial responses to clear infection. Mechanisms of inflammation and immune defence are only partly understood. This project aims to elucidate a novel innate immune pathway (the inflammasome) that drives inflammatory cell death and antimicrobial defence. Using innovative multidisciplinary methods, this project wi ....A novel mechanism of host defence via macrophage extracellular traps. Animal health relies upon innate immune cells to rapidly detect invading microbes and induce inflammatory and antimicrobial responses to clear infection. Mechanisms of inflammation and immune defence are only partly understood. This project aims to elucidate a novel innate immune pathway (the inflammasome) that drives inflammatory cell death and antimicrobial defence. Using innovative multidisciplinary methods, this project will yield exciting new knowledge of mechanisms of inflammation and anti-microbial responses, and new paradigms for inflammasome action. Expected outcomes and benefits include high-impact publications, international collaboration, world-class training for young scientists, and new knowledge for future commercialisation.Read moreRead less
Histone deacetylase functions in immune cells. This project aims to define how an enzyme (a histone deacetylase) enables innate immune cells (macrophages) to respond to specific danger signals, such as those activating Toll-like Receptors. To identify processes that provide specificity to signal transduction pathways, this project will characterise protein targets and biological functions of a specific class IIa histone deacetylase in macrophages. This project expects to result in an understandi ....Histone deacetylase functions in immune cells. This project aims to define how an enzyme (a histone deacetylase) enables innate immune cells (macrophages) to respond to specific danger signals, such as those activating Toll-like Receptors. To identify processes that provide specificity to signal transduction pathways, this project will characterise protein targets and biological functions of a specific class IIa histone deacetylase in macrophages. This project expects to result in an understanding of histone deacetylases and protein deacetylation in immune cell responses which can be harnessed to manipulate cell functions for basic science and biotechnology uses.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101340
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Subversion of innate immune responses by pathogenic Escherichia coli. This project will determine how bacteria that cause diarrhoeal diseases prevent the immune system from signalling efficiently. It will provide important information not only about how the bacteria establish disease, but also provide insight into the host response in the early stages of infection.
An investigation into CD1a, a versatile antigen-presenting molecule. This project aims to investigate how T lymphocytes are activated by lipids presented by the skin-associated antigen-presenting molecule, CD1a. Using X-ray crystallography and cellular immunology, we will provide fundamental insight into this poorly understood immunological axis. We will determine the molecular basis for how CD1a presents diverse self and foreign lipids, and how such CD1a-lipid complexes are recognised by the r ....An investigation into CD1a, a versatile antigen-presenting molecule. This project aims to investigate how T lymphocytes are activated by lipids presented by the skin-associated antigen-presenting molecule, CD1a. Using X-ray crystallography and cellular immunology, we will provide fundamental insight into this poorly understood immunological axis. We will determine the molecular basis for how CD1a presents diverse self and foreign lipids, and how such CD1a-lipid complexes are recognised by the responding T cells. This basic science discovery project will provide substantial new knowledge in the burgeoning field of lipid-mediated immunity, which should ultimately lead to new therapies targeting the CD1a lipid display molecule to either prevent immune mediated damage or promote protective immunity as required.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100070
Funder
Australian Research Council
Funding Amount
$650,000.00
Summary
An advanced in vivo imaging facility. An advanced in vivo imaging facility: This project will establish an advanced In Vivo Imaging Facility (IVIF) for examining host-microbe interactions and associated immunological processes within the context of the numerous infectious disease models within the University of Melbourne and associated collaborators. The Zeiss LSM 7MP 2-photon imaging system will provide enhanced capacity to directly visualise cellular and molecular events in real time, with gre ....An advanced in vivo imaging facility. An advanced in vivo imaging facility: This project will establish an advanced In Vivo Imaging Facility (IVIF) for examining host-microbe interactions and associated immunological processes within the context of the numerous infectious disease models within the University of Melbourne and associated collaborators. The Zeiss LSM 7MP 2-photon imaging system will provide enhanced capacity to directly visualise cellular and molecular events in real time, with greater sensitivity and in a broader range of tissues and organs. This will provide the opportunity for novel insights into numerous immunological and host-microbe interactions.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100097
Funder
Australian Research Council
Funding Amount
$675,000.00
Summary
An Automated Protein Nano-Crystallisation Facility. An automated protein nano-crystallisation facility:
The project aims to establish a high throughput protein nanocrystallisation and imaging facility for protein crystallography. Protein crystallography is an important field of biological research, however there are many proteins, such as integral membrane proteins and transient molecular complexes that are more challenging to crystallise. The facility aims to use state-of-the-art imaging and c ....An Automated Protein Nano-Crystallisation Facility. An automated protein nano-crystallisation facility:
The project aims to establish a high throughput protein nanocrystallisation and imaging facility for protein crystallography. Protein crystallography is an important field of biological research, however there are many proteins, such as integral membrane proteins and transient molecular complexes that are more challenging to crystallise. The facility aims to use state-of-the-art imaging and crystallisation techniques, including second order nonlinear imaging of chiral crystals (SONICC) imaging and lipid cubic phase approaches, to enable structural studies to be undertaken on challenging proteins. This information is often used for the rational development of therapeutics. The facility would support cutting-edge biological research In Australia.Read moreRead less