Adoptive Cell Transfer Incorporating Vaccination (ACTIV) Therapy For Cancer
Funder
National Health and Medical Research Council
Funding Amount
$601,950.00
Summary
We have made a breakthrough in a new treatment for cancer that can destroy large tumours in mice. The treatment involves a transfusion of white blood cells and an injection of a vaccine. In this project, we will seek to understand how the treatment works, and apply it to human white blood cells in preparation for a clinical trial in cancer patients.
Deriving Actionable Strategies To Enhance Cancer Immunotherapy Response
Funder
National Health and Medical Research Council
Funding Amount
$447,193.00
Summary
Cancer immunotherapy is an increasingly common treatment used to treat several types of advanced cancers. Whilst it can be dramatically effective in a minority of patients, many patients do not respond to the treatment and our ability to predict who will not benefit is limited. This project aims to study distinct aspects of tumour immunology in patients receiving immunotherapy treatments in order to identify better predictors and more widely-effective immunotherapy treatment strategies.
Identification And Targeting Of A Potent NK Cell “checkpoint” In Tumour Immunity
Funder
National Health and Medical Research Council
Funding Amount
$470,144.00
Summary
Cancer must evade detection by the immune system in order to develop. Natural Killer (NK) cells can detect and kill cancer cells. We have discovered a potent "checkpoint" in the NK cell activation pathway that desensitizes NK cells to growth factors and switches off their activation and killer function. When this checkpoint is inhibited, NK cells become hyper-activated and prevent most types of cancer metastasis in mice. Targeting this checkpoint in humans could revolutionise cancer therapy
Identification Of CIS As A Potent Checkpoint In NK Cell-mediated Tumour Immunity
Funder
National Health and Medical Research Council
Funding Amount
$959,596.00
Summary
Cancer must evade detection by the immune system in order to develop. Natural Killer (NK) cells can detect and kill cancer cells. We have discovered a potent "checkpoint" in the NK cell activation pathway that desensitises NK cells to growth factors and switches off their activation and killer function. When this checkpoint is inhibited, NK cells are super activated and can prevent most types of cancer metastasis in mice. Targeting this checkpoint in humans could revolutionise cancer therapy.
T Cell Trafficking And Effective Immunotherapy For Cancer
Funder
National Health and Medical Research Council
Funding Amount
$218,807.00
Summary
Cancer is the major cause of death in Australia in 2007. New forms of treatment are needed. The body’s defences against infection can be harnessed to fight some cancers. This project will examine how we can do this better using the signals that tell the body’s killer cells where to go and what to do when they get there.
Although the immune system has the ability to reject tumours, this sometimes does not occur, leading to cancer. There are many different types of cells that make up the immune system, including some which respond very early, called natural killer (NK) and NKT cells. These cells are the first line of defence against some tumours, although we do not understand how they recognise and respond to tumour cells. The aim of this project is to investigate the functional importance of both NK and NKT cell ....Although the immune system has the ability to reject tumours, this sometimes does not occur, leading to cancer. There are many different types of cells that make up the immune system, including some which respond very early, called natural killer (NK) and NKT cells. These cells are the first line of defence against some tumours, although we do not understand how they recognise and respond to tumour cells. The aim of this project is to investigate the functional importance of both NK and NKT cells in response to a range of different tumour types, including melanoma (skin cancer), lung carcinoma, breast carcinoma and sarcoma (connective tissue tumour). We will test the importance of each of these subsets by injecting these tumours into mice that have specific deficiencies in NK and-or NKT cells. If the NK or NKT cells are important, the tumours should grow more effectively when these immune cells are absent. We will also be able to put NK and-or NKT cells back into the mice to show directly that they are responsible for tumour rejection. Using a modification of this cell transfer approach, we will be able to inhibit special molecules that are normally produced by these cells that help them interact with other cells, and also help them attack the tumour cells. Collectively, the approaches outlined in this application allow us to determine which types of cells are important in response to a broad range of different tumour types, and also should tell us how these cells are able to attack the tumours. This information will be invaluable for the development of new strategies to use the patients immune system to attack cancer (known as immuno-therapy).Read moreRead less
Novel Vaccine Formulation For Immunotherapy Of Adenocarcinomas
Funder
National Health and Medical Research Council
Funding Amount
$178,400.00
Summary
We have designed a vaccine based on a unique delivery system. Mice immunised with vaccine were protected from a tumour challenge. We will now design a vacine with a cancer associated protein so that people once immunised can make killer cells. Since humans have different genetic makeup we will produce a vacine which is more effective and will benefit everyone. This vaccine will be more effective than a current vacine in that has yielded promising results in humans.
Evaluation Of Immune Responses To Multiple Tumour Antigens During Tumour Growth
Funder
National Health and Medical Research Council
Funding Amount
$451,980.00
Summary
It is becoming increasingly clear that cancerous tissues are not hidden from the body's immune system and yet, despite the generation of tumour-specific T cells and antibodies, the immune system does not often destroy solid tumour. Tumours express a large number of potential antigens (molecules in or on cancer cells that can be recognised by the immune system), but T cell responses to tumour antigens may be limited to only a few of these antigens (the dominating ones). These T cells could compet ....It is becoming increasingly clear that cancerous tissues are not hidden from the body's immune system and yet, despite the generation of tumour-specific T cells and antibodies, the immune system does not often destroy solid tumour. Tumours express a large number of potential antigens (molecules in or on cancer cells that can be recognised by the immune system), but T cell responses to tumour antigens may be limited to only a few of these antigens (the dominating ones). These T cells could compete with any other T cells that have been, or are being, generated, preventing their expansion and development into fully functional T cells. If this is true, then tumours will 'escape' immune mediated destruction, as a T cell response to only a few antigens is not likely to be enought to seriously perturb growing tumours. In this grant we will use a well established mouse model of cancer to evaluate immune responses to tumour antigens during tumour growth and try to understand why other potential antigens do not invoke a fully functional immune response. If we are successful, we will have made advances that could lead to new therapies for cancer.Read moreRead less
Reactivities Of CD8 T Cells To Mutated Neo-antigens In Lung Malignancies
Funder
National Health and Medical Research Council
Funding Amount
$661,979.00
Summary
Tumours express mutated proteins (called ‘neo-antigens’) which can be targets of powerful killer T cells which can destroy cancer cells. To understand why these cells fail to cure most cancers we will study neo-antigens identified by modern DNA sequencing methods to identify these neo-antigens & the responses to them. Then it will be possible to design trials in individual patients, e.g. personalised vaccines to ‘force’ the immune system to attack cells bearing these neo-antigens.