Identification And Characterisation Of Phosphorylation Events Taking Place During Human Sperm Capacitation
Funder
National Health and Medical Research Council
Funding Amount
$280,400.00
Summary
Male infertility affects one in every twenty Australian males and one third of all infertile couples worldwide. The most common cause of human infertility is not a failure to produce sperm, but a failure of these cells to express a normal capacity for fertilization. The cause of this loss of functional competence is unclear. We are going to use our technical expertise in proteomics to characterize the molecular pathways responsible for the defective sperm function seen in infertile patients.
Altering Macrophage Phenotype For The Treatment Of Chronic Airway Disease And Lung Cancer
Funder
National Health and Medical Research Council
Funding Amount
$904,556.00
Summary
The aim of this proposal is to identify mechanisms through which the Src family kinase Hck promotes innate immune cell-dependent, chronic lung inflammation and lung cancer development. Our preliminary data suggest that excessive Hck activity provides a molecular mechanism to skew macrophage polarization towards an alternatively activated, M2-like phenotype associated with chronic airways disease, and the tumour promoting microenvironment.
Defining The Role And Contribution Of Cdc37 To Signal Transduction And Tumourigenesis By Src-family Kinases
Funder
National Health and Medical Research Council
Funding Amount
$411,430.00
Summary
Cells respond to extracellular stimuli, such as growth factors and hormones, by activating intracellular networks of signaling molecules. It is the activation of these signaling networks that is ultimately responsible for mediating the biological responses of cells to extracellular stimuli (e.g. insulin stimulating glucose metabolism by cells). Members of the Src-family of tyrosine kinases are paramount among signaling molecules, as they are able to directly initiate the activation of a cascade ....Cells respond to extracellular stimuli, such as growth factors and hormones, by activating intracellular networks of signaling molecules. It is the activation of these signaling networks that is ultimately responsible for mediating the biological responses of cells to extracellular stimuli (e.g. insulin stimulating glucose metabolism by cells). Members of the Src-family of tyrosine kinases are paramount among signaling molecules, as they are able to directly initiate the activation of a cascade of signaling networks that regulate the activity of the cell. Significantly though, the inappropriate activation of Src-family kinases has been implicated in the development of cancer, particularly breast and colon cancer, in humans. To fulfill their signaling functions however, Src-family kinases must first be folded into an active conformation upon their synthesis in the cell then be maintained in this conformation. Although previous studies, including our own, have implicated a class of proteins called molecular chaperones in this process, little is known about how the folding of Src-family kinases by these proteins is achieved and regulated. The overall aim of this study is to determine how the folding of Hck, one member of the Src-family of tyrosine kinases, into a conformation that enables it to participate in signaling networks is achieved and regulated. It is expected that the results from this study will provide significant new insight into how this process might influence the ability of cells to respond to extracellular stimuli and potentially contribute to the conversion of a normal cell into one with tumourigenic properties. Findings from this project may be particularly important in the context of human cancer. A better knowledge of how the signaling activity of Src-family kinases is regulated by molecular chaperones might provide a new avenue of investigation for the identification of novel chemotherapeutic agents.Read moreRead less
Tumour Suppressor Networks: The Role Of SHIP-1 And Lyn In Suppressing Haematopoietic Tumours
Funder
National Health and Medical Research Council
Funding Amount
$469,526.00
Summary
Haematopoietic malignancies kill a large number of Australians each year. Improving our understanding of the molecular mechanisms that underlie these diseases is essential for the design of more effective treatments. Lyn and SHIP-1 are enzymes that are found in blood cells, and both participate in terminating cellular responses. As such, these enzymes are critically important for maintaining stability in the immune system. While these enzymes have unique roles, we also have good evidence that in ....Haematopoietic malignancies kill a large number of Australians each year. Improving our understanding of the molecular mechanisms that underlie these diseases is essential for the design of more effective treatments. Lyn and SHIP-1 are enzymes that are found in blood cells, and both participate in terminating cellular responses. As such, these enzymes are critically important for maintaining stability in the immune system. While these enzymes have unique roles, we also have good evidence that in some instances Lyn and SHIP-1 participate in the same biochemical pathway. We have created mice that are unable to make Lyn protein, and have found that these mice develop blood cell tumours. Mice lacking SHIP-1 develop a number of haematological defects, but die at a young age due to an inflammatory lung condition, making an assessment of the role of SHIP-1 in age-dependent tumour development difficult. We now wish to study the role of SHIP-1 in tumour development, by generating mice that lack SHIP-1 in specific white blood cell compartments. We are also investigating how SHIP-1 and Lyn cooperate in tumour suppression, and we have recently generated mice that simultaneously lack both SHIP-1 and Lyn. Preliminary studies indicate that compound mutant mice develop multiple haematological malignancies. We will fully characterize tumour development in these animals, and determine the molecular basis for this pathology. We will focus on two pathways that have been previously implicated in oncogenesis. These studies will improve our insight into how Lyn and SHIP-1 cooperate in blood cell development, cellular homeostasis and oncogenesis, and add to our biological and biochemical understanding of tumour suppressor networks.Read moreRead less
A New Function For An Old Enzyme: Src Protein Kinase Directs Excitotoxic Neuronal Death In Stroke
Funder
National Health and Medical Research Council
Funding Amount
$513,975.00
Summary
In our previous investigation of how brain cells die in patients suffering from stroke, we found that stroke causes aberrant activation of an enzyme called Src in the affected brain cells. Furthermore, this aberrantly activated Src directs the brain cells to undergo cell death. Our proposal, which aims to decipher this neurotoxic mechanism of the aberrantly activated Src will benefit development of new therapeutic strategies to reduce brain damage in stroke patients.
Targeting TRPV4 Activation Mechanisms To Reveal Novel Pain Therapies
Funder
National Health and Medical Research Council
Funding Amount
$580,938.00
Summary
Pain nerves sense painful chemical and physical stimuli, by opening protein "ion channels" which let small electric currents traverse the cell membrane. This pain signal is transmitted to the spinal cord and then the brain, where it is perceived as pain and elicits a reaction. But we don't know how the ion channels open. This project will investigate how receptors for painful substances open ion channels to cause pain. Understanding this mechanism will help us to make new drugs to treat pain.