Investigating Immune Regulation In The Tumour Microenvironment
Funder
National Health and Medical Research Council
Funding Amount
$288,650.00
Summary
Suppressive factors made by cells of the immune system or cancers themselves and immune regulatory T cells inhibit an effective anti-tumour response. My project aims to investigate the mechanism by which these factors and cells mediate their suppressive function. Understanding these processes in the cancer environment will allow the design of more effective cancer therapies.
Targeting Immune Suppressive Neutrophils To Improve Cancer Immunotherapy
Funder
National Health and Medical Research Council
Funding Amount
$318,768.00
Summary
Cancer is the leading cause of death in Australia. Despite the recent successes of cancer immunotherapies, there is an unmet need to overcome primary unresponsiveness and acquired resistance. Today mounting evidence has accumulated that neutrophils contribute to therapy resistance by fostering tumour blood supply and an immune suppressive microenvironment. The central aim of this project is, to improve cancer immunotherapy by blocking an immune suppressive neutrophil response.
Using Mouse Models To Decipher The Function Of Caspase-2 In Limiting Aneuploidy Tolerance And Cancer
Funder
National Health and Medical Research Council
Funding Amount
$871,162.00
Summary
Aneuploidy or abnormal chromosome number is a feature of cancer cells. The extent of aneuploidy is often predictive of prognosis and the effectiveness of cancer treatment. We discovered that a tumour suppressing protein, caspase-2, is important for deleting aneuploid cells that may otherwise become cancerous. In this project we will use cancer models to decipher how caspase-2 safeguards against aneuploidy and cancer to better understand how cancer cells can survive and be targeted for treatment.
Targeting Inflammatory Skin Disease Using An Immune-modulatory Human Signal Peptide
Funder
National Health and Medical Research Council
Funding Amount
$698,836.00
Summary
Effective drugs are desperately needed for the improved treatment of inflammatory diseases. We will determine how a modified human peptide, which we have discovered and can make, works to suppress harmful skin inflammation. We will design new formulations to deliver our drug to the skin in order to better treat psoriasis, an autoinflammatory skin disease. We will also trial our new drug in models of atopic dermatitis a debilitating skin disease for which there is limited treatment options.
Attenuating Severe Infections In Chronic Inflammatory Diseases Through Modulation Of Transforming Growth Factor-β Activity
Funder
National Health and Medical Research Council
Funding Amount
$611,793.00
Summary
Asthma and chronic obstructive pulmonary disease (COPD) are characterised by enhanced TGF? expression, which is accompanied by susceptibility to recurrent viral and bacterial infections. Such infections exacerbate lung inflammation in these patients, generally requiring emergency department treatment. This project proposes to clarify the therapeutic potential of TGF? inhibitors to reduce the impact of viral infections in patients with COPD and asthma.
Organ transplantation is the measure of last resort for patients with organ failure. While this is a life-saving procedure, the long-term survival of transplant recipients depends on maintaining the new organ without rejecting it. The proposed research will create novel test systems that allow both patients and clinicians to monitor the concentration of the drugs required to suppress organ rejection. Such a test will reduce the cost of treatment and increase the long term survival of patients.
‘Transcriptional Tumour Suppression’ By Pax5 And Ikaros In B Progenitor Acute Lymphoblastic Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$558,927.00
Summary
B-progenitor acute lymphoblastic leukaemia (B-ALL) is the most common cancer in children. The genes Pax5 and Ikaros are frequently mutated in B-ALL, but how this contributes to leukaemia development and treatment resistance remains unclear. We have recently produced new B-ALL models driven by reversible suppression of Pax5 or Ikaros activity, and propose to use these models to uncover how these genes control leukaemia differentiation and regression.
Mechanism Of Leukaemia Suppression By The Transcription Factor Ikaros
Funder
National Health and Medical Research Council
Funding Amount
$655,630.00
Summary
A subset of acute lymphoblastic leukaemias are characterised by mutations in the Ikaros gene. These leukaemias respond poorly to chemotherapy and require novel therapeutic approaches. We have discovered a new function of Ikaros in regulating leukaemia cell death. This project investigates how Ikaros regulates cell death and whether this is a general mechanism. Understanding Ikaros function is a step toward improved treatments for this aggressive type of leukaemia.