Understanding The Role Of The Atypical Cadherin Fat4 In Lymphatic Vascular Development
Funder
National Health and Medical Research Council
Funding Amount
$1,006,248.00
Summary
This application will define the role of a large cell adhesion molecule, FAT4, in lymphatic vascular development. By understanding how FAT4 functions in lymphatic vessels, we will gain insight to the mechanisms by which mutations in the gene that encodes this protein cause a human lymphoedema syndrome.
The Mezzanine T Cell Response: Intervening At The Coal Face
Funder
National Health and Medical Research Council
Funding Amount
$765,585.00
Summary
In an initial immune response, specialised cells in lymph nodes tell T cells to multiply; the stimulated T cells depart and enter target tissue (e.g. lung in the case of flu). We describe a new response whereby the target tissue itself can tell T cells to multiply further. This response in target tissues reveals a new way of altering immune responses. This is especially important as in many diseases, the primary lymph node response has already occurred, so cannot be therapeutically intervened.
Ubiquitin And SUMO DNA Damage Response Signalling At Deprotected Telomeres During The Cell Cycle
Funder
National Health and Medical Research Council
Funding Amount
$302,627.00
Summary
Following genome damage cells stop the cell division process and initiate DNA repair. We discovered that at specific times during cell division his does not happen if the damage signals originate from the chromosome ends (i.e. “telomeres”). We anticipate this is necessary to prevent genomic instability in healthy cells and may be driving genomic instability in cancer cells. Experiments described here will elucidate the molecular mechanisms and biological significance of our observation.
Investigating The Cellular Response To Iron-Depletion: The Trilogy Of ASK1, Thioredoxin And Ribonucleotide Reductase
Funder
National Health and Medical Research Council
Funding Amount
$552,572.00
Summary
Iron is crucial for many essential biological processes. Recently, we demonstrated that iron-depletion can affects important signalling pathways (e.g., JNK and p38) that play important roles in growth arrest and apoptosis. This study is designed to investigate the cellular and molecular effects of iron depletion which currently remains unclear. The research is crucial for understanding: (1) the effects of iron deficiency and (2) for understanding the effects of iron chelators that are used for t ....Iron is crucial for many essential biological processes. Recently, we demonstrated that iron-depletion can affects important signalling pathways (e.g., JNK and p38) that play important roles in growth arrest and apoptosis. This study is designed to investigate the cellular and molecular effects of iron depletion which currently remains unclear. The research is crucial for understanding: (1) the effects of iron deficiency and (2) for understanding the effects of iron chelators that are used for treating various diseases.Read moreRead less
Targeting Adenosine Mediated Immunosuppression To Enhance CAR T Cell Activity
Funder
National Health and Medical Research Council
Funding Amount
$633,447.00
Summary
The use of white blood cells genetically engineered to eradicate cancer cells specifically has been a major breakthrough in cancer treatment. These cells (CAR T cells) are very effective in blood cancers, but do not currently work well in other cancers. This is due to the immune suppressing nature of the cancer environment. I propose to use strategies to overcome this by genetically reprogramming the CAR T cells to be resistant to suppression by the cancer and therefore be more effective.
Interplay Between Metabolic Reprogramming And Oncogenic Signalling In The Cellular Response To Chemotherapy
Funder
National Health and Medical Research Council
Funding Amount
$654,035.00
Summary
Chemotherapy resistance is a major barrier to the treatment of triple-negative breast cancer (TNBC). We seek to uncover an intimate link between cell metabolism and oncogenic signalling pathways in regulating the cellular response to chemotherapy. Our studies will identify a critical mechanism limiting the therapeutic efficacy of chemotherapy and investigate combination therapy strategies that could improve the treatment of TNBC.
A Simple Method To Improve Stem Cell Transplant Therapy
Funder
National Health and Medical Research Council
Funding Amount
$831,652.00
Summary
Despite the success of hematopoietic stem cell transplantation and years of promise, almost all other stem cell therapies are considered experimental and remain in preclinical or early-phase clinical testing. This study aims to improve the efficiency of stem cell transplantation by manipulating cellular metabolism prior to transplantation, if effective these results may offer hope to patients suffering from a broad range of disorders.
Cancers of the skin are the most common tumours in humans, and their diagnosis and treatment impose the largest costs on Australia’s cancer budget. While much has been learned about the roles of sunlight and skin type as risk factors for skin cancer, relatively little is known about the genes conferring risk. This study will compare the genetic profiles of over 6000 patients with skin cancer to 3000 people without skin cancer to pinpoint the genes responsible for skin cancer.
Evaluation Of Molecular Mechanisms Driving Metastasis Using Integrated Intravital Imaging
Funder
National Health and Medical Research Council
Funding Amount
$885,271.00
Summary
Metastasis is the leading cause of cancer-associated death. Understanding key steps that drive the spread of cancer is critical to improve current treatment strategies. Using cutting-edge imaging technology and 3-dimensional model systems that mimic the disease, we will pinpoint key events that are susceptible to drug intervention and identify new therapeutic targets.
Aurora Kinase: Molecular, Cellular And Functional Studies Deciphering Its Role In Stroke Injury
Funder
National Health and Medical Research Council
Funding Amount
$580,993.00
Summary
In stroke patients, oxygen deprivation indirectly induces massive nerve cell death by activating an enzyme called aurora kinase A (AURKA). We aim at unravelling (i) how AURKA is activated by oxygen deprivation, (ii) where the activated AURKA is localised in cells, and (iii) how the activated AURKA induces nerve cell death.The study will benefit development of therapeutic strategies to protect against brain damage in stroke since this is novel and different target for drug targeting.