Cancer causes significant morbidity and mortality in Australia’s aging population. There is strong evidence that abnormal blood vessels in tumours limit drug access and drive metastases. We have identified a molecule which controls vessel remodelling in tumours. In this proposal we will study mechanisms on how the molecule itself is regulated with the aim to normalize blood vessels for improved therapy.
Regulator Of G Protein Signalling-5 Loss And Gain Of Function In Vivo
Funder
National Health and Medical Research Council
Funding Amount
$625,428.00
Summary
Cancer and cardiovascular diseases are amongst the largest causes of morbidity and mortality in Western populations. We have identified a molecule, called Regulator of G protein signalling 5 (RGS5), which is involved in vessel remodelling in both diseases. This molecule is a prime candidate for drug development. We will study the precise role of RGS5 in sophisticated preclinical models which will create future opportunities for urgent therapy.
RGS5 Signalling In Cardiovascular And Smooth Muscle Cell Physiology
Funder
National Health and Medical Research Council
Funding Amount
$645,613.00
Summary
Cardiovascular diseases, including hypertension, remain one of the largest causes of morbidity and mortality in Western populations. We have identified a molecule, called Regulator of G protein signalling 5 (RGS5), which is involved in pathological vessel remodelling and in the regulation of blood pressure. This molecule is a prime candidate for drug development. We will study the precise role of RGS5 in cardiovascular disease models and regulatory pathways in cell systems.
The Characterization Of A Novel Pseudokinase Regulator Of Platelet Formation
Funder
National Health and Medical Research Council
Funding Amount
$372,965.00
Summary
Mammalian cells contain a complex switchboard, which directs the cell to grow, die, multiply or move in response to external cues. When communication breaks down within the cell, diseases arise. Our studies are directed towards identifying the molecules that comprise the switchboard which directs blood cell formation. A detailed understanding of the regulators of blood cell formation will equip us with a sound starting point for designing drugs to ameliorate blood diseases.
Cells are building blocks of living things and require signalling pathways to communicate their functions. We discovered a new signalling pathway in flies that remarkably exists in yeast and plants to more complex organisms like mice and man. We will study this new signalling pathway in flies to find out how and why it communicates in cells. As flies and humans share similar genes, our studies will inform how this previously unknown signalling pathway functions from simple to complex organisms
Control Of Organ Size And Cancer By The Hippo Pathway
Funder
National Health and Medical Research Council
Funding Amount
$638,517.00
Summary
The Hippo pathway is a key regulator of tissue growth. It was first discovered in vinegar flies and plays a similar role in mammals. We aim to define the mechanism by which the Hippo pathway controls tissue growth and cancer. These studies will be performed in flies and mammalian cell culture. Our studies will shed light on how tissue growth is controlled, and have the potential to inform the way that we treat human cancers and tissue growth disorders.
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
Integrating Wnt-Apc Pathway With TGF-beta Signalling In Colon Cancer
Funder
National Health and Medical Research Council
Funding Amount
$342,364.00
Summary
Colon cancer is one of the leading causes of death of all cancers. Two molecular pathways have been independently implicated in colon cancer development. Emerging evidences suggest that the two pathways may work together in the colon polypus formation. This application will integrate two separate molecular causes to form a new coherent understanding of cancer development and offer new directions in development of novel colon cancer treatment.
Intramembrane Mechanics of Immunoreceptor Signalling. The cells of the immune system constantly survey the body for markers of injury and infection through molecular sensors that are responsive to the presence of pathogens, tumours and damaged cells. The goal of this project is to understand how the mechanical action of these molecular sensors direct the transmission of information to the cell interior.
Exceptions Prove the Rule: How Antigen Recognition Drives T cell Activation. CD8+ T cells are immune cells that are critical for the adaptive immune response, which is central to immune function in vertebrates. CD8+ T cells mediate their effector functions only after activation, which occurs via T cell receptor (TCR) recognition of foreign antigens. Here, unique reagents and sophisticated technologies will be used to define precisely how the nature of TCR-antigen recognition impacts on T cell ac ....Exceptions Prove the Rule: How Antigen Recognition Drives T cell Activation. CD8+ T cells are immune cells that are critical for the adaptive immune response, which is central to immune function in vertebrates. CD8+ T cells mediate their effector functions only after activation, which occurs via T cell receptor (TCR) recognition of foreign antigens. Here, unique reagents and sophisticated technologies will be used to define precisely how the nature of TCR-antigen recognition impacts on T cell activation and effector function. This work builds on an earlier identification of an entirely novel mode of TCR-antigen recognition, and its success will establish novel paradigms in T cell biology and represent a key advance in knowledge in the life sciences.Read moreRead less