Solving the puzzle of complex disease - genes and their interactions with the environment. Many human diseases are caused by the interplay of genetic predisposition (nature) and the environment (nurture); but their causes remain a mystery, since much past research has focused on these aspects in isolation. This project will aim to better understand these complex diseases using a multi-factorial approach that brings both nature and nurture together.
Programmed cell death signalling in innate immunity. This proposal aims to address the under-explored potential for programmed cell death to promote innate immune cell signalling, which is a critical and fundamental biological process. It aims to generate new knowledge in the areas of cell death and innate signalling using innovative interdisciplinary approaches and discover new molecules that impact innate inflammatory responses. The expected outcomes of this project are to enhance our basic un ....Programmed cell death signalling in innate immunity. This proposal aims to address the under-explored potential for programmed cell death to promote innate immune cell signalling, which is a critical and fundamental biological process. It aims to generate new knowledge in the areas of cell death and innate signalling using innovative interdisciplinary approaches and discover new molecules that impact innate inflammatory responses. The expected outcomes of this project are to enhance our basic understanding of cell death, and build interdisciplinary collaborations. This work should provide significant benefit to the economy and health of Australians, as it is expected to identify molecules that will be of interest to the pharmaceutical and biotechnology industries.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100106
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
An advanced flow cytometry facility for the Peter Doherty Institute. The establishment of a flow cytometry facility in the new Peter Doherty Institute for Infection and Immunity will enhance capacity to investigate immunity to a broad range of very serious diseases. This project will support researchers studying viral and bacterial infection as well as cancer and autoimmunity.
Crosstalk between breast cancer cells and the microenvironment to promote metastasis. Breast cancer spread (metastasis) to distant tissues is usually fatal. It is now clear that cross-talk between cancer cells and other normal cells is essential for metastasis and previous studies have discovered two key mechanisms: tumour cell suppression of immune defence pathways to escape immune recognition, and activation of proteases to promote invasion and blood vessel growth. Using unique models and cell ....Crosstalk between breast cancer cells and the microenvironment to promote metastasis. Breast cancer spread (metastasis) to distant tissues is usually fatal. It is now clear that cross-talk between cancer cells and other normal cells is essential for metastasis and previous studies have discovered two key mechanisms: tumour cell suppression of immune defence pathways to escape immune recognition, and activation of proteases to promote invasion and blood vessel growth. Using unique models and cellular imaging, this project aims to investigate the cell specific functions of these pathways and the therapeutic potential of altering their expression and function. This project may lead to the development of novel predictors of metastasis in patients and new targeted therapeutics to prevent breast cancer spread.Read moreRead less
Controlling apoptotic cell death in health and disease. Regulating how and when cells die is crucial for the development and maintenance of a healthy body and mind. This project will investigate the proteins that are responsible for controlling cell death with the view to identifying novel ways to target these proteins for the treatment of disorders such as cancer, neurodegenerative disease and autoimmunity.
Controlling apoptotic cell death in health and disease. Regulating how and when cells die is crucial for the development and maintenance of a healthy body and mind. This project will investigate the proteins that are responsible for controlling cell death with the view to identifying novel ways to target these proteins for the treatment of disorders such as cancer, neurodegenerative disease and autoimmunity.
Discovery Early Career Researcher Award - Grant ID: DE130100537
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Neural regulation of immunity following brain injury. Following a brain injury, the brain tries to protect itself by blocking all inflammation. However, this renders the host with impaired immunity and increased risks to infections. The project aims to delineate the mechanisms behind this response, with the expected outcome of highlighting the important interplay between the nervous and immune system.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100092
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Fluorescence microscopy with optical tweezers: imaging cellular responses. Life relies on the ability of our cells to receive and respond to signals with pinpoint accuracy, involving both chemical and mechanical signals. This equipment will allow scientists to expose cells to both types of signals and measure the response at an unprecedented level of accuracy for the first time.
microRNAs and the control of T lymphocyte differentiation, function and malignant transformation. The molecular mechanism of the immune system is not completely understood. This project will investigate how transcription factors and microRNAs, two major types of regulatory molecules work together to control immune responses. The results from this research will assist in the design of better vaccination strategies and treat certain lymphomas.
Discovery Early Career Researcher Award - Grant ID: DE130100117
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Allosteric fingerprinting of G protein-coupled receptor monomers and oligomers. Allosteric modulation describes interactions between distinct, but conformationally linked, binding sites. Research will develop enabling technology using the unique profile, or 'fingerprint', of allosteric modulation at interacting and non-interacting G protein-coupled receptors to probe for receptor complexes within healthy and diseased tissue.