Characterization Of The 72 KDa Inositol Polyphosphate 5-phosphatase
Funder
National Health and Medical Research Council
Funding Amount
$454,050.00
Summary
Cells respond to external signals and the enviroment to undergo cell growth, secretion and or other specialized functions including control of cell death and or cell size. We have identified a new enzyme (72 kDa 5-phosphatase) which resides inside the cell, which we have evidence plays a role in regulating both the movement of intracellular vesicles and also lipid signals stimulated by insulin. We have characterised the phospholipids that the enzyme cleaves and demonstrated the generation of new ....Cells respond to external signals and the enviroment to undergo cell growth, secretion and or other specialized functions including control of cell death and or cell size. We have identified a new enzyme (72 kDa 5-phosphatase) which resides inside the cell, which we have evidence plays a role in regulating both the movement of intracellular vesicles and also lipid signals stimulated by insulin. We have characterised the phospholipids that the enzyme cleaves and demonstrated the generation of new cell signals at specific subcellular localizations on intracellular membranes. We predict the generation of these specific lipid signals may play a significant role in controlling the transport of intracellular cargo to specific sites in the cell. In this grant proposal we aim to examine the regulation of specialised cargo called the glucose transporter, which is found in fat and muscle cells, and also the mannose 6-phosphate receptor, which regulates the trafficking of specific enzymes which mediate digestion of proteins. These studies include the clarification of which phospholipid signals the enzyme terminates and where in the cell this occurs. Secondly, we will examine the movement of the glucose transporter GLUT-4 in unstimulated cells and in response to insulin and furthermore how expression of the novel enzyme regulates its movement. We will also examine the movement of the mannose 6-phosphate receptor and the specific phospholipid signals which control the route the receptor traffics, using inhibitors of lipid signals and expression of lipid phosphatases and kinases. We will also examine how our novel enzyme forms complexes with other molecules in the cell and characterise these novel molecules using basic biochemical assessment of enzyme activity and function. Finally we will examine the regulation of intracellular messages by our novel enzyme following insulin stimulation, which facilitates glucose uptake into the cell.Read moreRead less
Breast cancer is the most frequent malignancy among women, with an estimated 1 million new cases per year worldwide. A family of enzymes known as protein tyrosine kinases (PTKs) are fundamental in the initiation and progression of tumour growth and they are frequently hyperactivated in breast cancer. This proposal will examine whether inactivation of the enzyme known as TCPTP contributes to PTK hyperactivation and tumorigenicity in breast cancer.
Tyrosine Kinases And Phosphatases In Cell Cycle Checkpoint Responses
Funder
National Health and Medical Research Council
Funding Amount
$513,946.00
Summary
In order for an organism to grow and develop, the cells that make up the tissues and organs need to undergo a process of cellular division, wherein individual cells grow and then divide into two cells. During this process of cellular growth and division the entire genome needs to be duplicated (this occurs during S-phase) and then divided equally into the two daughter cells. In S-phase several so-called 'checkpoint' mechanisms exist which ensure that this occurs in an orderly and precise manner. ....In order for an organism to grow and develop, the cells that make up the tissues and organs need to undergo a process of cellular division, wherein individual cells grow and then divide into two cells. During this process of cellular growth and division the entire genome needs to be duplicated (this occurs during S-phase) and then divided equally into the two daughter cells. In S-phase several so-called 'checkpoint' mechanisms exist which ensure that this occurs in an orderly and precise manner. The so-called 'DNA replication checkpoint' delays S-phase progression in response to 'replication stresses' that may otherwise cause DNA damage. Protein tyrosine kinases (PTKs) are hyperactivated in many human solid tumours and blood malignancies contributing to varied aspects of tumour progression. Our preliminary studies indicate that the inactivation of PTKs by protein tyrosine phosphatases may be essential for the suppression of S-phase progression in response to replication stress. Our goal is to understand the molecular mechanisms by which PTKs and tyrosine phosphatases contribute to S-phase checkpoints. Our studies will provide important insights into DNA replication stress-induced checkpoint responses in mammals and identify unprecedented mechanisms by which hyperactivated PTKs may contribute to tumour development.Read moreRead less