The Role Of Cholesterol In Patched/hedgehog Signalling During Mammalian Development.
Funder
National Health and Medical Research Council
Funding Amount
$198,660.00
Summary
Fluctuations in levels of cholesterol during development of the mammalian embryo have been shown to have catastrophic affects leading to gross deformities particularly in terms of brain and facial development. The requirement of the developing embryo for cholesterol has been linked to the patched-hedgehog signalling pathway which we have previously shown to be central to mammalian development as well as tumour formation. In particular, the patched protein which is responsible for regulating sign ....Fluctuations in levels of cholesterol during development of the mammalian embryo have been shown to have catastrophic affects leading to gross deformities particularly in terms of brain and facial development. The requirement of the developing embryo for cholesterol has been linked to the patched-hedgehog signalling pathway which we have previously shown to be central to mammalian development as well as tumour formation. In particular, the patched protein which is responsible for regulating signalling through this complex cascade of protein interactions has a domain similar to that which in other proteins has been shown to detect and respond to intracellular levels of cholesterol. The patched protein binds to hedgehog at the surface of the cell and mediates the transduction of the the hedgehog signal into the cell. By analogy to the role of sterol sensing domains in other proteins, we hypothesise that this domain in patched detects fluctuations in intracellular cholesterol levels which in turn alter trafficking of patched to the cell surface where it can participate in the hedgehog receptor complex. This hypothesis is supported by our preliminary data which suggests that patched is normally localised both at the cell surface and intracellularly. We are proposing a series of experiments to test our hypothesis, most of which deal with determing the localisation of patched in a cell culure system exposed to agents aimed at varying the intracellular levels of cholesterol. Subcellular localisation of patched will be analysed by immunofluorescence, electron microscopy and immunoblotting analysis. We will also test the ability of patched to aggregate at the cell surface with other molecules important in receiving and sending the hedgehog signal. The experiments in this proposal are likely to give the first clues as to the function of the sterol sensing domain in patched and its role in mediating the vital link between cholesterol and embryonic development.Read moreRead less
Regulation Of Hedgehog Signalling Through Intracellular Trafficking Events
Funder
National Health and Medical Research Council
Funding Amount
$220,500.00
Summary
The hedgehog signalling cascade plays a role in forming almost every organ of the body during development of an embryo. Perturbation of the function of key members of this pathway during embryonic development often results in death in utero or severe childhood abnormalities. In addition, disruption to this pathway also results in a range of cancers, most notably the extremely common skin cancer basal cell carcinoma. In this proposal we aim to investigate in detail the regulatory mechanisms which ....The hedgehog signalling cascade plays a role in forming almost every organ of the body during development of an embryo. Perturbation of the function of key members of this pathway during embryonic development often results in death in utero or severe childhood abnormalities. In addition, disruption to this pathway also results in a range of cancers, most notably the extremely common skin cancer basal cell carcinoma. In this proposal we aim to investigate in detail the regulatory mechanisms which operate to ensure that this complex pathway of interacting molecules functions correctly during embryonic development. By understanding how this regulation occurs we will gain valuable insight into how disruption of this pathway results in such a range of disease, as well as into how agents which modulate this pathway may potentially act in a therapeutic setting.Read moreRead less
Colorectal cancer is a common malignancy in Australia and the mutation of one gene (Apc) is implicated in >80% of the cases. We aim to understand Apc biochemistry in normal and colon cancer cells by integrating mathematics with our experimental biology program. The main outcomes for this project will be a better understanding of the regulatory systems perturbed in colon cancer. We believe that the insights gained by our research will point the way to more effective treatments of colon cancer.
Targeting Of The APC Tumour Suppressor To Mitochondria: Implications For APC Regulation And Cellular Function
Funder
National Health and Medical Research Council
Funding Amount
$390,116.00
Summary
Inherited mutations in the APC gene cause colon cancer, and kills 4,700 Australians every year. About 1 in 21 Australians develop colorectal cancer by the age of 75. APC mutations change cells in different ways, triggering the cancer process. We have discovered a new pathway, involving altered movement of APC to mitochondria in tumour cells. This study will investigate how this cancerous change may help our understanding of colon cancer progression.
Physiological Significance Of Cellular Translocation Of The Intestine-specific Homeodomain Protein Cdx2
Funder
National Health and Medical Research Council
Funding Amount
$196,527.00
Summary
Ulcerative colitis and Crohn's disease are debilitating inflammatory diseases of the bowel. Conservative estimates (Australian Crohn's and Colitis Association) suggest that at least 23,000 Australians are affected (>1 in 1000). Ten years after onset, there is an estimated risk of 0.5-1.0% per year of pancolitis patients developing full-blown bowel cancer. Current therapies for colon cancer are not very effective and the median survival for patients with metastatic disease is poor at 7-12 mont ....Ulcerative colitis and Crohn's disease are debilitating inflammatory diseases of the bowel. Conservative estimates (Australian Crohn's and Colitis Association) suggest that at least 23,000 Australians are affected (>1 in 1000). Ten years after onset, there is an estimated risk of 0.5-1.0% per year of pancolitis patients developing full-blown bowel cancer. Current therapies for colon cancer are not very effective and the median survival for patients with metastatic disease is poor at 7-12 months. It is therefore important to increase our understanding of the biology underlying these inflammatory conditions so that more effective treatments may be developed and fewer patients proceed to the cancerous stage. We have recently demonstrated a novel interaction between two proteins that may be relevant to intestinal inflammation. Surprisingly, the two proteins would not normally be expected to coincide with each other because of their different localisations within cells and tissues. The first protein, Cdx2, is only synthesised by intestinal lining cells and normally resides in the nucleus where it activates genes that play a role in the highly specialised absorptive functions of the intestine. The other protein, acrogranin-granulin, is more widely distributed in the body and is generally transported out of cells shortly after it has been made. It has been shown to interact with receptors on epithelial cells and blood cells and promotes their growth. In this proposal we will be investigating whether the complex formed between Cdx2 and granulin is important for normal physiology. Moreover since elevated levels of granulin are associated with inflammation, we aim to determine whether the Cdx2-granulin complex is formed during the active phase of ulcerative colitis and Crohn's disease. Specifically, we will test the hypothesis that the Cdx2-granulin complex plays an important role in repairing the damage caused to the lining of the intestine during inflammation.Read moreRead less
Regulated Shuttling Of Beta-catenin And IQGAP1 Between Nucleus And Plasma Membrane In Migrating Cells
Funder
National Health and Medical Research Council
Funding Amount
$511,703.00
Summary
Inherited gene mutations that cause colon cancer kill 4,700 Australians every year. About 1 in 21 Australians develop colorectal cancer by age 75. Activation of the beta-catenin protein is a critical switch in the path to colon cancer. We discovered that beta-catenin, and another protein it interacts with called IQGAP1, move between different cellular compartments. We plan to study this process in more detail, as it relates to how beta-catenin works and to understanding its role in cancer.
Role Of PAK1 In Colorectal Cancer Growth And Metastasis Regulated By Gastrins
Funder
National Health and Medical Research Council
Funding Amount
$460,070.00
Summary
Increased level of PAK1(a protein kinase) was associated with the progression of colorectal (large bowel) cancer (CRC). Gastrin peptides are growth factors responsible for CRC development. The objective of this project is to determine the role of PAK1 in the regulation of CRC growth and metastasis by gastrin peptides. We will use cell culture, animal models and clinical samples in the program. A successful outcome will lead to the development of new CRC therapies such as inhibitors of PAK1.
Regulation Of Nuclear Import Of Viral Oncoproteins And Transcription Factors By Protein-protein Interactions
Funder
National Health and Medical Research Council
Funding Amount
$650,383.00
Summary
The present application examines the controls that exerted over proteins that localize in the nucleus of eukaryotic cells. This relates relates integrally to cellular processes such as growth, development and oncogenesis. This research area is not represented elsewhere in Australia, and the particular experimental strategies to approach the problem, revolving around the use of special quantitative microscopic techniques are novel internationally. One part of the application seeks to examine tran ....The present application examines the controls that exerted over proteins that localize in the nucleus of eukaryotic cells. This relates relates integrally to cellular processes such as growth, development and oncogenesis. This research area is not represented elsewhere in Australia, and the particular experimental strategies to approach the problem, revolving around the use of special quantitative microscopic techniques are novel internationally. One part of the application seeks to examine transport within the cell of complexes of interacting proteins, rather than single proteins, under as close as possible to physiologically relevant conditions. This will be truly unique, and of great importance to our comprehension of eukaryotic cell function. This application examines particular types of negative control over protein nuclear localization. Since many proteins show such regulation, and in particular important proteins controlling cell growth and division, the results are fundamentally important to our understanding of how cells function in general. Further, this understanding may be applied in disease situations, such as viral-mediated oncogenesis. In the work we propose to do, viral proteins with functions relating to cancer will be examined in detail, as well as a cellular protein which is recognised by them - the tumor suppressor Rb. We intend to examine several viral oncoproteins which target Rb; one is a protein (E7) from the Human Papilloma Virus which has been frequently associated with cervical carcinomas and other cancers. Accordingly, the results may have direct application to viral-induced cancer, and our work may lead to understanding of the regulation of protein transport to the nucleus. This may thus afford a new approach at the pharmacological level to combat transformation.Read moreRead less
Specificity Of Smad Proteins In Transforming Growth Factor-beta Signaling
Funder
National Health and Medical Research Council
Funding Amount
$212,036.00
Summary
Transforming growth factor-betas (TGF-beta) regulate a fascinating array of cellular processes including cell proliferation, differentiation, migration, organization and death, as well as affect a wide range of biological functions, such as embryonic development, hematopoiesis and immune and inflammatory responses. Given the multifunctional nature of TGF-beta action, it is not surprising that the disruptions of TGF-beta functions have been implicated in many human disorders, particularly in colo ....Transforming growth factor-betas (TGF-beta) regulate a fascinating array of cellular processes including cell proliferation, differentiation, migration, organization and death, as well as affect a wide range of biological functions, such as embryonic development, hematopoiesis and immune and inflammatory responses. Given the multifunctional nature of TGF-beta action, it is not surprising that the disruptions of TGF-beta functions have been implicated in many human disorders, particularly in colorectal and pancreatic cancers. The Smad proteins (there are ten of them) are critical components of TGF-beta cellular actions. In fact, Smad4 also called DPC4 for deleted in pancreatic carcinoma locus 4. This project addresses how each Smad protein works at molecular level in the cell, and which part of biological functions it regulates. Collectively, the outcomes of the project may provide clear and specific molecular targets to treat TGF-beta related diseases such as colorectal and pancreatic cancers.Read moreRead less