Combination Immunotherapeutic Strategies For Haematological Cancers
Funder
National Health and Medical Research Council
Funding Amount
$421,747.00
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 novel 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 lymph ....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 novel 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.Read moreRead less
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.
T-cells: The Key To Unlocking Immunity Against Aggressive Lymphoma
Funder
National Health and Medical Research Council
Funding Amount
$322,951.00
Summary
By investigating several aspects of patients’ immune defenses against the cancer cells in Diffuse large B-cell lymphoma, this project will provide critical insights on ways to harness the patient’s own immune system to effectively mount anti-tumour responses. These results will pave the way for future therapeutic strategies to successfully treat and prevent lymphoma.
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.
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
Targeting Human Dendritic Cells In A Multiple Myeloma Humanized NOD/SCID Model
Funder
National Health and Medical Research Council
Funding Amount
$425,696.00
Summary
Adoptively transferred dendritic cells (DC) loaded with tumor associated antigen (TAA) have been shown to induce anti-tumor immunity in animal models; however, their therapeutic efficacy in cancer patients has not been established. Protective immunity has failed in the tumor-bearing host and the ability of human DC to induce anti-tumor responses in the abnormal environment of the cancer patient requires further investigation. Due to the limited capacity to investigate the DC-tumor interaction in ....Adoptively transferred dendritic cells (DC) loaded with tumor associated antigen (TAA) have been shown to induce anti-tumor immunity in animal models; however, their therapeutic efficacy in cancer patients has not been established. Protective immunity has failed in the tumor-bearing host and the ability of human DC to induce anti-tumor responses in the abnormal environment of the cancer patient requires further investigation. Due to the limited capacity to investigate the DC-tumor interaction in patients, humanized animal models containing human DC and tumor provide an opportunity to obtain important new information. We propose to develop multiple myeloma (MM) as a human tumor in our humanized (hu)NOD-SCID model containing human DC, and to use this in vivo MM-huNOD-SCID model to restore immunity by correcting the human DC-tumor interaction.This knowledge will act as a fast track to select and design a new (simplified) DC-based immunotherapy to treat cancer patients and will be translated directly into our MM clinical trials program, potentially by targeting human DC based on CD205 recognition.Read moreRead less
We seek to understand how white blood cells detect and destroy disease, and how molecules of the immune system punch holes in diseased cells. We wish to learn how cancer can sometimes evade the immune system. Our work will also find out how some common treatments for cancer, like chemotherapy, can be used to boost the immune system and eliminate tumours. Through knowledge gained from these studies, we aim to develop new therapies that can help patients with devastating diseases like cancer.
Investigating The Dynamic Interactions Between Immune And Cancer Cells Using Two-photon Intravital Microscopy
Funder
National Health and Medical Research Council
Funding Amount
$401,361.00
Summary
Immune cells normally aid tumour destruction, but in some situations do the reverse and promote tumour spread. We will utilize cutting edge techniques including 2-photon microscopy together with novel transgenic mouse models to track immune cells in real time during tumour development in order to identify what factors determine a positive versus negative outcome. This will give us an unprecedented opportunity to ‘see’ how these cells interact with malignant cells which could lead to novel therap ....Immune cells normally aid tumour destruction, but in some situations do the reverse and promote tumour spread. We will utilize cutting edge techniques including 2-photon microscopy together with novel transgenic mouse models to track immune cells in real time during tumour development in order to identify what factors determine a positive versus negative outcome. This will give us an unprecedented opportunity to ‘see’ how these cells interact with malignant cells which could lead to novel therapeutic approaches.Read moreRead less