Signaling Pathways To Enhance Potency Of AMPK-targeting Drugs
Funder
National Health and Medical Research Council
Funding Amount
$661,966.00
Summary
Sedentary lifestyles and consumption of high energy foods has led to epidemics of obesity-related metabolic diseases that place enormous financial and medical burden on the Australian economy. An attractive drug target to treat these diseases is AMP-activated protein kinase (AMPK) which functions as both a cellular fuel gauge and co-ordinator of whole-body metabolism. Our goal is to improve AMPK drug potency by identifying novel processes that sensitize AMPK to drugs.
Molecular Basis For Stress-induced Gene Regulation—a Model System To Understand Transcriptional Deregulation In Cancer And Neurological Disease
Funder
National Health and Medical Research Council
Funding Amount
$384,076.00
Summary
Deregulated gene transcription plays a critical role in cancer formation. It is therefore important to understand the molecular basis of gene transcription and how tumour cells hijack the process. In this Project, we will study the molecular basis of stress-inducible gene expression. This is particularly important for understanding the molecular basis of cancer as stress-inducible genes are activated by transcription factors implicated in breast, colon, lung, and prostate cancers.
DYRK1A As A Novel Target For Glioblastoma Therapies
Funder
National Health and Medical Research Council
Funding Amount
$620,294.00
Summary
Glioblastoma is a form of brain cancer that is currently incurable. We have discovered that switching-off an enzyme called DYRK1A (using ‘DYRK1A inhibitors’) kills glioblastoma cells. This therapeutic advantage is even greater when combined with drugs approved for other cancers. This project will develop new DYRK1A inhibitors and examine a novel combination treatment for glioblastoma patients. This could initiate a novel therapy that could significantly extend patients’ lives.
Structural Characterisation Of The Co-inhibitory Complex Formed By The Tumour Suppressor PTEN And The Metastatic Factor PREX2
Funder
National Health and Medical Research Council
Funding Amount
$563,602.00
Summary
Metastasis is a major cause of cancer mortality. Characterisation of key proteins that regulate metastasis is therefore a priority. PTEN and PREX2 are enzymes that play key roles in metastasis in melanoma, and other cancers. We will determine the structural basis of PTEN:PREX2 co-inhibition, and determine how cancer-associated PREX2 mutations dysregulate this inhibitory complex. This study will provide the necessary knowledge for future drug development programs targeting PTEN:PREX2 in cancer.
Structural And Functional Characterisation Of The Oncogene P-Rex1
Funder
National Health and Medical Research Council
Funding Amount
$623,447.00
Summary
The spread of cancer to other parts of the body (metastasis) is a major cause of mortality. The characterisation of proteins that regulate metastasis is therefore a priority. P-Rex1 plays a crucial role in promoting metastasis in breast and other cancers. We will determine the structural basis of P-Rex1 activity, and investigate how its dysregulation promotes aberrant cell growth. This study will provide the knowledge to build future drug development programs targeting P-Rex1 in cancer.
Many of the most serious diseases of Western societies including obesity, Type 2 diabetes, cancer growth and metastasis and cardiovascular disease have metabolic dimensions. The enzyme AMPK regulates cellular and whole body energy homeostasis by coordinating metabolic pathways to balance energy demand with nutrient supply. We are studying the structure and function of AMPK with the aim of better treating metabolic diseases.
A Structural Understanding Of Class B G Protein-coupled Receptor Function
Funder
National Health and Medical Research Council
Funding Amount
$1,289,570.00
Summary
G protein-coupled receptors (GPCRs) are the largest family of cell surface proteins that enable communication from external signals to the inside of cells of the body. Class B GPCRs are a therapeutically important subclass of these receptors and they play crucial roles in bone and energy homeostasis, cardiovascular control and immune response. This grant will uncover fundamental knowledge on how these receptors work, and will enhance future development of therapeutics.
Resolving And Targeting The Complex Molecular Mechanisms Underlying GPCR Signalling
Funder
National Health and Medical Research Council
Funding Amount
$1,071,370.00
Summary
Receptors are located on the surface of all human cells to allow our cells to respond to their environment. Over 30% of prescription drugs act through particular receptors called GPCRs, however effective drugs without side effects are difficult to develop because we do not have a deep understanding of how GPCRs transmit complex signals. In this proposal we seek to resolve the atomic-level details of GPCR signalling to assist in the development of better drugs for a diverse range of diseases.
Cancer Risks From Low-dose Ionising Radiation Following Diagnostic Medical Procedures
Funder
National Health and Medical Research Council
Funding Amount
$750,579.00
Summary
Our study investigates cancer risk following exposure to low doses of ionising radiation from medical procedures. Our first major paper linked over 800,000 CT exposures to cancer outcomes in a cohort of almost 11 million young Australians, and found that CT exposure predicted an increased incidence of leukaemia and most solid cancers. In our ongoing work we will incorporate nuclear medicine and other diagnostic x-rays, and estimate radiation dose for individual procedures and to specific organs.
Genomic Analysis Of DNA Binding And Gene Regulation By The Chromatin Remodelling Factor UBF
Funder
National Health and Medical Research Council
Funding Amount
$624,254.00
Summary
Synthesis of ribosomes, the cellular protein synthetic machinery, is the major anabolic event of a growing cell and is frequently dysregulated during disease such as cancer. This grant will examine a protein termed UBF that we think plays an important role in orchestrating the cellular response to dysregulated ribosome biogenesis. By understanding how UBF functions we hope to uncover novel therapeutic approaches to treat diseases associated with ribosome stress .