Protein / Protein Interactions Important For AMP-activated Protein Kinase Regulation
Funder
National Health and Medical Research Council
Funding Amount
$242,545.00
Summary
The AMP-activated protein kinase (AMPK) is an enzyme that monitors the energy levels of the body. When oxygen and nutrient levels decrease, the energy levels of a cell also decrease leading to activation of the AMPK. This results in activation of energy-producing pathways and inhibition of energy-consuming pathways, allowing cells to match supply with demand to ensure their survival. The AMPK comprises of three proteins that together form a functional enzyme. In this application I aim to obtain ....The AMP-activated protein kinase (AMPK) is an enzyme that monitors the energy levels of the body. When oxygen and nutrient levels decrease, the energy levels of a cell also decrease leading to activation of the AMPK. This results in activation of energy-producing pathways and inhibition of energy-consuming pathways, allowing cells to match supply with demand to ensure their survival. The AMPK comprises of three proteins that together form a functional enzyme. In this application I aim to obtain a thorough understanding of the molecular basis of how the AMPK functions. I will determine how and where the three proteins interact with each other and determine where in a cell at any given time the AMPK can be found. This is an important question to answer because many proteins are inactive within the cytoplasm but when they are bound to the plasma membrane they are active. I have previously found the AMPK to be localized to the cytoplasm, membrane and nuclear compartments of the cell, but little is known about the AMPK s function in these different locations. Activation of the AMPK is known to depend on another protein that is also activated when cellular energy levels decrease. This protein has remained elusive to many researchers over the past few years. I plan to identify this protein using new bioinformatics together with the vast amount of information provided by the sequencing of the human genome. Exercise and reduced caloric intake activate the AMPK, these are associated with health benefits and reduce the risk of cardiovascular and neurodegenerative diseases, diabetes and obesity. For these reasons information on the role of the AMPK may improve our understanding of the reasons these diseases develop.Read moreRead less
Loss Of Cytostatic Regulation By TGF-beta During EGFR-driven Tumor Development
Funder
National Health and Medical Research Council
Funding Amount
$605,031.00
Summary
Growth factor and cytokine signalling networks control many aspects of cell behaviour such as proliferation, survival, migration, invasive capabilities, transformation and differentiation. In normal cells, these complex signalling pathways are tightly regulated. Alterations of these signals are often found to cause, directly or indirectly, tumour formation. Transforming Growth Factor-b (TGF-b) and Epidermal Growth Factor (EGF) signalling pathways are both independently implicated as key regulato ....Growth factor and cytokine signalling networks control many aspects of cell behaviour such as proliferation, survival, migration, invasive capabilities, transformation and differentiation. In normal cells, these complex signalling pathways are tightly regulated. Alterations of these signals are often found to cause, directly or indirectly, tumour formation. Transforming Growth Factor-b (TGF-b) and Epidermal Growth Factor (EGF) signalling pathways are both independently implicated as key regulators in tumour formation and as such they are potential therapeutic targets. However, while both pathways have been studied extensively, little is known about the cross-talk between the TGF-b and EGF pathways. This project will establish the generality of a new tumor signaling axis, namely EGFR-Stat3-Smad7-TGF-b in EGFR-overexpressing tumors. Practically, it will provide guidelines for the development of new approaches for treating effectively the EGFR-driven tumors.Read moreRead less
Validation Of Stat3 As A Therapeutic Target In Diseases Arising From Its Inappropriate Activation By Gp130 Cytokines
Funder
National Health and Medical Research Council
Funding Amount
$674,142.00
Summary
Stomach cancer is the third most prevalent cancer in the Western World and result in the yearly death of several thousand people in Australia alone. We have discovered a specifice gene mutation of a receptor molecule called gp130 that results in the formation of stomach cancer in mice. We are now aiming to understand the exact molecular events by which this mutation results in the uncontrolled growth of stomach lining cells. We will employ a number of strategies to establish molecularly the exte ....Stomach cancer is the third most prevalent cancer in the Western World and result in the yearly death of several thousand people in Australia alone. We have discovered a specifice gene mutation of a receptor molecule called gp130 that results in the formation of stomach cancer in mice. We are now aiming to understand the exact molecular events by which this mutation results in the uncontrolled growth of stomach lining cells. We will employ a number of strategies to establish molecularly the extent to which this mouse model is informative for gastric cancer inhuman. In aprticular we will identify the genes that are involved in the progression of the disease. One important focus of the project is to see whether or not the moelcule (called Stat3) whose aberrant activation triggers the disease in the mouse could provide a future pharmacological target for intervention with the disease. Similarly with expertise of CIB, we will investigate with novel proteomics techniques whther we can identify a protein in the serum of these mice, which could give us aclue of whether or not the mouse ahs already developed disease. Such a protein could be of potentail diagnostic importance in the future to screen human for gastric cancer which in its eraly stages is usually without any clinical symptoms. In a related Aim we will find out the gene that can genetically cooperate with Stat3 and that is required to enable survival of newborn mice. It may well turn out mOur proposal combines the expertise of the two investigators in signal transduction and that this gene may be an important determinant to ensure that Stat3 triggers physiological rather than pathological responses in many differnet organs.Read moreRead less
Regulation Of Gene Expression: Biomolecular Interactions In Cellular Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$2,998,713.00
Summary
This team consists of three of Australia�s younger researchers Merlin Crossley, Joel Mackay and Jacqui Matthews (as Chief Investigators), who are recognized as authorities in the areas of gene regulation and the structural and functional analysis of proteins. They are joined by Mitchell Weiss, a world authority on blood development and clinical disorders,and Alexis Verger, a molecular and cell biologist recruited from France, both as Principal Investigators. Crossley, Mackay and Matthews have wo ....This team consists of three of Australia�s younger researchers Merlin Crossley, Joel Mackay and Jacqui Matthews (as Chief Investigators), who are recognized as authorities in the areas of gene regulation and the structural and functional analysis of proteins. They are joined by Mitchell Weiss, a world authority on blood development and clinical disorders,and Alexis Verger, a molecular and cell biologist recruited from France, both as Principal Investigators. Crossley, Mackay and Matthews have worked as a team for around six years to date, have published together in high-quality international journals, and have received anumber of accolades for their contributions to Australian science. For example, Crossley has won a number of national awards, including the Gottschalk Medal of the Australian Academy of Science; Mackay was recently awarded the Prime Minister�s Prize for Life Scientist of the Year, and Matthews won the only Charles and Sylvia Viertel Medical Research Fellowship to be awarded in 2003. The members of this team have collaborated extensively on the world stage and Crossley, Mackay and Matthews have also taken leadership roles in the Australian scientific community. Mitchell Weiss has been an important collaborator, exchanging reagents and advice, since he and Crossley trained together as postdocs in Stu Orkin�s lab at Harvard in the early 90s. Most recently Weiss, in collaboration with Mackay, has made important discoveries on a-globin production, which has led to several highly significant publications including a seminal paper in Cell in 2004.The program of research put forward in this proposal centres around understanding the mechanisms through which genes are switched on and off, using blood development as a model system, that is also fundamental to human life. The regulation of gene output is essential both during the development of an organism and throughout the course of its life. Problems with this regulation can result in many different disease states, most notably cancer, which includes the many different types of leukemias. At one level, gene output is controlled by networks of specific proteins known as transcription factors that interact both with each other and with DNA. Currently, however, the details surrounding which complexes regulate which genes and the processes that control the making and breaking up of the complexes are not well understood. Knowledge of how these interactions take place will put us in a position to control the output of chosen genes for therapeutic purposes. We propose to use a combination of cell biological, biochemical, and structural approaches to firstly shed light on these complexes and secondly develop reagents that can be used to manipulate the activity of specific genes.Read moreRead less
Characterization Of HLS5, A Novel Tumor Suppressor Gene
Funder
National Health and Medical Research Council
Funding Amount
$406,980.00
Summary
HLS5 is a novel gene that we recently discovered in our laboratory. Preliminary investigations suggest that HLS5 is similar to a family of genes which act as DNA regulators. We have shown that HLS5 is found on a region of chromosome 8 which is often deleted in human cancers, suggesting that HLS5 is a new tumour suppressor gene i.e.. damage to this gene may be responsible for the formation of certain types of cancer (specifically breast and prostate). Other evidence to support the claim that HLS5 ....HLS5 is a novel gene that we recently discovered in our laboratory. Preliminary investigations suggest that HLS5 is similar to a family of genes which act as DNA regulators. We have shown that HLS5 is found on a region of chromosome 8 which is often deleted in human cancers, suggesting that HLS5 is a new tumour suppressor gene i.e.. damage to this gene may be responsible for the formation of certain types of cancer (specifically breast and prostate). Other evidence to support the claim that HLS5 is a tumour suppressor gene comes from the proteins it associates with these partner molecules are involved in DNA repair or DNA regulation. When we introduced HLS5 into cancer cells, it slowed their growth and reduced their ability to form tumours. The aim of this project therefore, is to undertake a detailed analyses of the HLS5 gene and to determine the function of its protein product. A combination of approaches will be used in this study. We will: (i) alter the amount of HLS5 expression in cancer cells, (ii) characterize the proteins which bind to HLS5, (iii) determining where HLS5 localizes in the cell, (iv) analyze mice with lack the gene for HLS5, (v) assess the involvement of HLS5 in a human leukemia (vi) analyze HLS5 messenger RNA which produces the protein, and (vii) determining the structure of HLS5 protein. These studies should provide valuable information on how HLS5 functions, as well as its role in cancer formation.Read moreRead less
Apoptosis is a fundamental mechanism in regulating normal development and preventing cancer. Cancer cells must avoid apoptosis and also adapt to harsh metabolic environments in order to survive in the absence of effective nutrient supply and to resist the action of certain drugs. This project will provide a detailed analysis of metabolic changes allowing cells to survive long periods when the apoptotic process is absent and nutrients are limiting.