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In this project we aim to define the role of the Siah proteins in tumour angiogenesis and inflammatory responses. Hypoxia, a decrease in oxygen tension, places constrains on tumour growth where access to oxygen is yet to be established via new blood vessel formation. In addition hypoxia is common in areas of inflammation and wound healing, where blood vessels have been shut down to help in recovery. With the use of our Siah knockout mice we have a unique model that allows us, for the first time, ....In this project we aim to define the role of the Siah proteins in tumour angiogenesis and inflammatory responses. Hypoxia, a decrease in oxygen tension, places constrains on tumour growth where access to oxygen is yet to be established via new blood vessel formation. In addition hypoxia is common in areas of inflammation and wound healing, where blood vessels have been shut down to help in recovery. With the use of our Siah knockout mice we have a unique model that allows us, for the first time, to investigate the role of Siah in the hypoxia signalling cascade. How cells sense and react to low oxygen levels is complex and involves several proteins. A key protein is called Hypoxia induced factor, Hif-1. It accumulates under hypoxia and is responsible for the expression of genes enabling the cell to tolerate and function under hypoxic conditions. tolerate and function under hypoxic conditions, which is involved in new blood vessel formation. PHD protein directs the degradation of Hif1, while Siah directs the degradation of PHD, when oxygen is limiting. Loss of Siah proteins (eg in our knockout models) leads to an increase in PHD proteins under hypoxia thus no stabilisation of Hif-1 and impaired response to hypoxia. Thus, sitting on the top of a cascade, which controls the trashing of proteins in the cell (focus of this year's Nobel price for medicine), Siah has primary control on the response to oxygen deprivation. The relative immunity of multicellular organisms to acquired defects is through redundancy. Oxygen is a unique case, for which organisms can not bypass the defect via redundancy, making it an attractive target for future therapy. Therefore, understanding the molecular and cellular response to hypoxia may allow us to identify key molecules which could be targeted for the development of novel anti inflammatory and cancer drugs. The scope of this study is to understand the key role of Siah utilising our knockout mice in models of inflammation and cancer.Read moreRead less
Regulation Of PML By E6AP: Implications For Tumour Development.
Funder
National Health and Medical Research Council
Funding Amount
$537,829.00
Summary
PML is a vital tumour suppressor, but little is known about its regulation. We established that PML levels are affected by another cellular protein E6AP. This study will define the mechanism by which E6AP influences PML. Human cancers will be screened for the involvement of these proteins, to gain new insights into cancer onset. The intended practical outcome of these studies is to aid cancer diagnosis and provide new anti-cancer drugs.
THE ROLE OF A NOVEL NEGATIVE CELL CYCLE REGULATORY PATHWAY DURING ANIMAL DEVELOPMENT
Funder
National Health and Medical Research Council
Funding Amount
$406,980.00
Summary
Cancer is a disease that is likely to affect 1-4 people at some point in their lifetime. Therefore, understanding what causes cancer is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation or apoptosis (programed cell death). Many genes involved in cancer have been identified, however, there are likely to be many more genes, that when disrupted or misexpressed can lead to cancer. We are intereste ....Cancer is a disease that is likely to affect 1-4 people at some point in their lifetime. Therefore, understanding what causes cancer is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation or apoptosis (programed cell death). Many genes involved in cancer have been identified, however, there are likely to be many more genes, that when disrupted or misexpressed can lead to cancer. We are interested in the regulation of cell proliferation, and have been studying this in the genetically amenable animal model system, Drosophila. Central to the control of cell proliferation in all organisms are the Cyclin dependent protein kinases. Cyclin E-dependent protein kinase is required to drive cells from the G1 (resting state) into S phase (where DNA replication occurs). Correct control of Cyclin E is important in limiting cell proliferation and many cancer causing mutations result in up-regulation of this critical cell cycle regulator and premature entry into the cell cycle. We have used a genetic approach using a weak mutation in Drosophila Cyclin E to isolate mutations in other important regulators of the G1 to S phase transition. This proposal focuses on one of these regulators, Phyl, and the proteins that function with it, Sina and Ebi, which act to target and lead to the degradation of key proteins that negatively regulate differentiation and that promote cell proliferation. In this proposal we seek to understand how the Ebi-Phyl-SIna protein complex functions to control cell proliferation in Drosophila. In addition, we will examine whether the Sina complex also acts to inhibit cell proliferation in the mouse. Due to the remarkable conservation of genes involved in cell proliferation control through evolution, this study is directly relevant to the control of cell proliferation and the development of cancer in humans.Read moreRead less
Investigating The Pathogenic Role Of Polyalanine Tract Expansion Mutations In The ARX Homeobox Transcription Factor.
Funder
National Health and Medical Research Council
Funding Amount
$545,619.00
Summary
Intellectual disability is frequent in the population, with as many as 1 in every 50 people in the world directly affected. ARX is one of the most frequent genes mutated in X chromosome-linked intellectual disability. Our study will specifically address the functional impact of these mutations in ARX using cell models relevant to the brain. We will also examine the contribution of other genetic changes to explain the very different symptoms seen in patients with the same gene mutation.
Mechanisms Of Nedd4/Nedd4-2-mediated Regulation Of The Epithelial Sodium Channel
Funder
National Health and Medical Research Council
Funding Amount
$471,000.00
Summary
The epithelial sodium channel (ENaC) is a highly specific ion channel expressed in the apical membrane of some tissues. In the kidney, ENaC activity is responsible for maintaining sodium balance, blood volume and blood pressure. In the lung ENaC function is required for fluid clearance. Abnormal regulation of ENaC is associated with conditions such as hypertension, cystic fibrosis and pulmonary oedema. Delineating the molecular basis of the regulation of ENaC is vital in understanding disease me ....The epithelial sodium channel (ENaC) is a highly specific ion channel expressed in the apical membrane of some tissues. In the kidney, ENaC activity is responsible for maintaining sodium balance, blood volume and blood pressure. In the lung ENaC function is required for fluid clearance. Abnormal regulation of ENaC is associated with conditions such as hypertension, cystic fibrosis and pulmonary oedema. Delineating the molecular basis of the regulation of ENaC is vital in understanding disease mechanisms and in defining targets for novel therapeutics for the treatment of disorders that arise due to sodium imbalance. Furthermore, ENaC and the molecules involved in the channel regulatory cascade are potential candidate genes in defining the genetic causes of human hypertension and salt wasting disorders. Previous studies from our laboratories and by other groups have shown that Nedd4 and Nedd4-2 proteins are key players in regulating ENaC activity. Our recent NHMRC supported work has identified another important protein, Grk2, as a regulator of ENaC. The work proposed in this application is an extension of our recent findings and will enable us to fully define how Nedd4-Nedd4-2 and Grk2 regulate the activity of ENaC.Read moreRead less
The future of cancer therapy lies in the tailoring of treatment to the characteristic of individual tumour. We have previously identified a subset of breast tumours that are characterised by the presence of large excess of proteins called D-type cyclins. Similar overexpression of cyclin D1 has been shown to lead to the development of cancer in mammary gland in animal models. In normal cells, D-type cyclins are degraded rapidly, therefore the regulation of protein degradation, or proteolysis, is ....The future of cancer therapy lies in the tailoring of treatment to the characteristic of individual tumour. We have previously identified a subset of breast tumours that are characterised by the presence of large excess of proteins called D-type cyclins. Similar overexpression of cyclin D1 has been shown to lead to the development of cancer in mammary gland in animal models. In normal cells, D-type cyclins are degraded rapidly, therefore the regulation of protein degradation, or proteolysis, is crucial in preventing the accumulation of D-type cyclins. In the subset of breast cancers we have identified, D-type cyclin proteolysis is defective. We, and others, have obtained evidence for the involvement of the SKP2 gene in the proteolysis of D-type cyclins. SKP2 has also been shown to be required for the proteolysis of another important protein, called p27. In the clinic, accumulation of p27 in tumours is used as a good prognostic indicator. However, some exceptions have been found where the accumulation of p27 correlates with aggressive tumours. As D-type cyclins are able to counteract the effect of p27, we hypothesise that the aggressive behaviour of these tumours is due to the simultaneous accumulation of D-type cyclins and that this is due to a mutation in the SKP2 gene. The experiments described in this proposal are designed to test this hypothesis. As the choice of treatment is affected by the interpretation of p27 levels, the results obtained from this study may have a direct impact in the clinic.Read moreRead less
Physiological Function Of Nedd4-2 In Regulating The Epithelial Sodium Channel
Funder
National Health and Medical Research Council
Funding Amount
$805,797.00
Summary
The epithelial sodium channel (ENaC) controls sodium balance, blood volume and blood pressure. Abnormal regulation of ENaC is associated with conditions such as hypertension and pulmonary oedema. Delineating the regulation of ENaC is vital in understanding disease mechanisms and in defining targets for novel therapeutics for the treatment of disorders that arise due to sodium imbalance. This grant will enable us to understand how ENaC is regulated by a novel protein known as Nedd4-2.
Regulation Of The Nedd4 Family Of Ubiquitin Ligases By Adaptor And Accessory Proteins In Normal Physiology And In Disease
Funder
National Health and Medical Research Council
Funding Amount
$609,424.00
Summary
In part this proposal is to understand how the body controls iron uptake through iron transporters DMT1 and Nramp1. We will study the regulation of these transporters by proteins called Ndfip1, Ndfip2 and arrestins. We will also study the functions of these proteins in controlling ubiquitination, a fundamental process required for cellular homeostasis. The results from this study may ultimately contribute to the development of novel therapies for certain human diseases.
Mature red cells develop from hemopoietic stem cells in the adult bone marrow. The production of red blood cells is primarily controlled by the hormone erythropoietin (Epo). Previously we had identified that the protein Lyn must be present inside primitive red blood cells for Epo to stimulate them to become mature functional cells. We will determine the role of several molecules that interact with Lyn including Cbp, Liar and LACM, towards apects of red blood cell development.
Leukaemia-cancer cells have altered biochemical properties resulting in their high rate of growth compared to normal cells. One of these is augmented activity of enzymes called tyrosine kinases including members of the Src family. One called Lyn has been implicated in several leukaemias as well as cancer. We have identified a novel mechanism of down-regulating this family of enzymes mediated by small proteins. These may allow us to develop novel therapeutics for cancer-leukaemia treatment.