Receptor Signalling Through Intracellular Calcium Stores In Chromaffin Cells
Funder
National Health and Medical Research Council
Funding Amount
$461,000.00
Summary
The function of cells in the body is controlled by many hormones and neurotransmitters acting on the cell's surface. Hormones and transmitters mediate their effects by producing chemical signals within the cell that regulate its activities. One key cell signalling chemical is calcium, especially in nerve cells which have developed sophisticated mechanisms for using calcium to control their function. Recently, new levels of complexity have been discovered, both in how cell calcium levels are modi ....The function of cells in the body is controlled by many hormones and neurotransmitters acting on the cell's surface. Hormones and transmitters mediate their effects by producing chemical signals within the cell that regulate its activities. One key cell signalling chemical is calcium, especially in nerve cells which have developed sophisticated mechanisms for using calcium to control their function. Recently, new levels of complexity have been discovered, both in how cell calcium levels are modified by hormones and transmitters and in how these complex calcium signals are used by cells to control their function. This project will investigate how hormones and transmitters can produce different types of calcium signals in nerve cells, and how these signals affect different aspects of the nerve cell's function. In particular, it will establish how two different types of specialised calcium stores within nerve cells are used by different classes of hormone and transmitter, and the distinct cellular functions these two calcium stores can regulate. The results will provide fundamental new information on how nerve cells control their activity and may help identify potential new targets for drugs.Read moreRead less
Post Synaptic Density Scaffold Proteins In The Growth Cone: Homer And Shank, Crucial For Calcium Signaling.
Funder
National Health and Medical Research Council
Funding Amount
$237,909.00
Summary
Our brain is a complex, yet precise electrical circuit. Understanding how the embryonic brain is wired has direct implications for all aspects of life, from the growing foetus in mother's womb, to learning algebra and for maintaining the active memories of our ageing population. This project aims to provide new insight into understanding how the embryonic brain is wired, crucial information for future pharmacological or gene therapy approaches to mental illness, ageing, and neuronal injury.
Novel Substance P Receptors On Autonomic And Sensory Neurons Regulating The Viscera
Funder
National Health and Medical Research Council
Funding Amount
$447,750.00
Summary
Potentially harmful stimulation of the skin or the internal organs activates sensory nerves that send signals to the brain. These events often are perceived as painful. One chemical messenger transmitting these signals first to the spinal cord, and then to the brain, is a neuropeptide called substance P. During many chronic inflammatory conditions, such as inflammation of the bowel, these signalling pathways are sensitised so that stimuli that previously were not painful now are perceived as pai ....Potentially harmful stimulation of the skin or the internal organs activates sensory nerves that send signals to the brain. These events often are perceived as painful. One chemical messenger transmitting these signals first to the spinal cord, and then to the brain, is a neuropeptide called substance P. During many chronic inflammatory conditions, such as inflammation of the bowel, these signalling pathways are sensitised so that stimuli that previously were not painful now are perceived as painful. This sensitisation has several different causes. One contributing factor seems to be related to a change in the receptor molecules that recognise substance P. Last year we discovered a new type of receptor for substance P, that is prominent in the nerve pathways between the gut and the spinal cord. This novel receptor has important characteristics that are different from the classical substance P receptor. However, we are still largely ignorant about how substance P interacts with these new receptors to modify the activity of nerve cells in sensory pathways. Indeed, we propose that these new receptors are likely to make a significant contribution to the sensitisation that occurs in inflammation. We will use a combination of sophisticated cellular and molecular techniques to study the way in which substance P acts on these novel receptors in nerves regulating the visceral organs. Our results are likely to make a significant contribution to the development and interpretation of rational new therapies for treating chronic diseases of the gastrointestinal tract, such as inflammatory bowel disease (IBD). Our studies will reveal signalling mechanisms that also are likely to be used by substance P more widely in the nervous system, that are relevant to other inflammatory conditions like arthritis, and even some forms of depression.Read moreRead less