Patient Tailored Anti-tumour T Cells To Prevent Relapse In Patients With Acute Myeloid Leukaemia Undergoing Allogeneic Haemopoietic Stem Cell Transplantation
Funder
National Health and Medical Research Council
Funding Amount
$190,445.00
Summary
Acute myeloid leukaemia (AML) is the most common acute leukaemia in adults. Patients with high-risk AML have a 2-year survival of less than 20%. Blood or bone marrow transplant from a healthy donor is often the only chance of cure but the leukaemia frequently returns. Dr Blyth will perform a clinical trial giving leukaemia fighting immune cells from the transplant donor to patients with high risk AML to prevent relapse after transplant.
A Polyepitope HPV16 E7 DNA Vaccine Restricted Through Multiple Class 1 Haplotypes Protects Against E7-expressing Tumour
Funder
National Health and Medical Research Council
Funding Amount
$218,244.00
Summary
Evidence that cervical cancer is caused by Human Papillomavirus is compelling. Once the virus enters the cells of the cervix, it produces a protein named E7 which functions to make the cells cancerous. Cervical cancer is the 5th commonest cause of death in women in Australia, and the major killer of women world-wide.The disease is particularly severe in those women whose immune systems are impaired, indicating immunological control of the cancerous cells . Current therapies including surgical re ....Evidence that cervical cancer is caused by Human Papillomavirus is compelling. Once the virus enters the cells of the cervix, it produces a protein named E7 which functions to make the cells cancerous. Cervical cancer is the 5th commonest cause of death in women in Australia, and the major killer of women world-wide.The disease is particularly severe in those women whose immune systems are impaired, indicating immunological control of the cancerous cells . Current therapies including surgical removal are frequently inadequate, and the r is no effective drug to combat the virus.These observations indicate that a vaccine is warranted, and that the E7 protein may be an ideal target for the vaccine. Cervical tumour cells are killed by specialised immune system cells named CTLs which recognise fragments of foreign antigen(E7) on their surface bound to selfMHC molecules. Our work has shown that multiple antigen fragments can be encoded and stitched together in a genetic vaccine which will stimulate CTLs to function in a number of 'self'molecule situations Our laboratory has developed several mouse models of human cervical cancer , and (along with others) has worked out which parts of the E7 protein are importatnt in developing an appropriate immune response to control tumour growth when given as a vaccine. One animal model consists of mice which are genetically engineered to produce several types of selfmolecules and also E7. Thes mice develop skin tumours as result of E7 expression. This system provides model of cervical epithelial tumours caused by E7 expression in women.Thus we can ask the questions o can we elicit CTL responses which function in the context of humanself ? o Will these CTL responses prevent the growth of E7-induced epithelial tumours? The OUTCOME of the project will be a vaccine which will prevent the establishment of cervical cancer which can progress directly into clinical trials in women bearing appropriate selfmolecules.Read moreRead less
Understanding And Modulating The Human Immune System
Funder
National Health and Medical Research Council
Funding Amount
$470,144.00
Summary
T cells are the sentinels of our immune system continually scanning our tissue for abnormalities and eliminating threats in many forms. They are our second and last line of defence against microorganisms and cancer. Unfortunately, T cells can also cause harm through accidental crossreactvity or overzealous function. My work is directed at understanding how T cells work and how they can be controlled using drugs and gene therapy. If we can ‘tune’ the power of this master immune lineage we can unl
A Trial Of Tumour Antigen Targeted Donor T Cells In High Risk Acute Myeloid Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$404,081.00
Summary
Acute myeloid leukaemia (AML) is the most common acute leukaemia in adults. Patients with high-risk AML have a 2-year survival of less than 20%. Blood or bone marrow transplant from a healthy donor is often the only chance of cure but the leukaemia frequently returns. We will perform a clinical trial giving leukaemia fighting immune cells from the transplant donor to patients with high risk AML to prevent relapse after transplant.
Therapeutic Vaccine Against Non-Hodgkin's Lymphoma Targeting The Immune Adjuvant Properties Of Natural Killer T Cells.
Funder
National Health and Medical Research Council
Funding Amount
$451,606.00
Summary
Patients with lymphoma cancers initially respond well to treatment, but later relapse with disease. The immune system can be effective at controlling cancer. A potential treatment option is to boost the natural immune response against cancer. This study investigates a vaccine that activates a certain immune cell, NKT cells, to fight lymphomas by delivering an NKT cell-activating molecule. Outcomes will allow assessment of combining an NKT-based vaccine with established treatments for lymphoma.
Cancer Immunotherapy Utilizing A Novel Receptor For Programmed Cell Death-1 Ligand 2
Funder
National Health and Medical Research Council
Funding Amount
$577,857.00
Summary
Immuno-modulators utilize the patient’s own immune system to eliminate or slow the growth of cancerous cells. We have identified a novel immuno-modulator which could be a significant player in immune-modulation therapy for the treatment of cancer. We will use the development grant to develop a product which has significant potential to be the next generation treatment for cancer.
Characterisation Of An Antigen Presenting Cell Unique To Spleen
Funder
National Health and Medical Research Council
Funding Amount
$420,606.00
Summary
The body depends on a range of defence mechanisms to remove invaders that enter by various routes. Antigen presenting cells are central to immunity in that they engulf and destroy dead cells and pathogens and present pieces of those pathogens or 'antigens' to white blood cells called T and B lymphocytes. These cells then start to fight the infection or disease. A new type of antigen presenting cell will be investigated for its particular ability to arrest blood-borne pathogens and disease.
Generating Tumour-Specific Dendritic Cells For Cancer Therapy
Funder
National Health and Medical Research Council
Funding Amount
$288,210.00
Summary
Therapies using the immune system are showing promise for cancer treatment, particularly for melanoma, but complete durable responses are few and improvements are needed. We believe that such immunotherapies, in their current form, fail to sufficiently mimic a natural immune reaction to disease, and therefore fall short of effectively controling cancer. In particular, an alarm (danger signal) is not produced within tumour as it would be when the body is challenged by infectious agents. Such dang ....Therapies using the immune system are showing promise for cancer treatment, particularly for melanoma, but complete durable responses are few and improvements are needed. We believe that such immunotherapies, in their current form, fail to sufficiently mimic a natural immune reaction to disease, and therefore fall short of effectively controling cancer. In particular, an alarm (danger signal) is not produced within tumour as it would be when the body is challenged by infectious agents. Such danger signals are critical for the immune system to respond effectively and for white blood cells of the immune system to find their way to the disease organism and eliminate it. The strongest danger signals are produced by a type of white blood cell known as a dendritic cell (DC). These cells detect infectious agents and produce biochemical alarm molecules that alert the entire immune system to the danger resulting in powerful action against the disease. However, tumours are really just a part of our own body and no danger signal is produced. It is our aim to use genetic modification to make DC see tumours as a threat and produce danger signals. These gene-modified DC either alone, or in combination with other immunotherapies, may lead to destruction of tumours.Read moreRead less