Regulation Of Cellular Responses To Neuropeptides.
Funder
National Health and Medical Research Council
Funding Amount
$83,510.00
Summary
Neuropeptides are chemicals released from nerves that are responsible for communication between the nerves, glands, muscles or other nerves. Neuropeptides exert their diverse biological effects by interacting with small structures on the cells they wish to communicate with. These structures bind the neuropeptide and are termed neuropeptide receptors. The responses of tissues to neuropeptides, for example, contraction of muscle, decrease with continued exposure to the neuropeptide. This reduction ....Neuropeptides are chemicals released from nerves that are responsible for communication between the nerves, glands, muscles or other nerves. Neuropeptides exert their diverse biological effects by interacting with small structures on the cells they wish to communicate with. These structures bind the neuropeptide and are termed neuropeptide receptors. The responses of tissues to neuropeptides, for example, contraction of muscle, decrease with continued exposure to the neuropeptide. This reduction in response is termed desensitization is thought to turn off the response to cells following stimulation by neuropeptides. In this study, I will investigate the mechanisms behind the desensitization of VPAC receptors which are a found throughout the body and have many important roles for example, gastrointestinal, pancreatic and reproductive function and control of muscle. VPAC receptors are also highly expressed in certain many cancers such as breast, prostate and colon carcinoma. The wide variety of functions that these receptors perform and the wide distribution in the body suggest that these are very important receptors. To date research into the responses and desensitisation of these receptors has been lacking, and the work that has been done has become confusing as more receptors and neuropeptides which bind them are discovered. The current project aims to carefully study these receptors and to determine their role in health and disease. The understanding the interaction of receptor and neuropeptide can perhaps lead to development of new therapeutic agents.Read moreRead less
The Role Of Urotensin II In Diabetes-Associated Atherosclerosis
Funder
National Health and Medical Research Council
Funding Amount
$405,594.00
Summary
People with diabetes most commonly die from stroke or heart attack and we need to determine what makes them more prone to these problems. The recently discovered UII system is increased in people with diabetes and has been found in diseased parts of blood vessels. Thus, the aim of this project is to characterise the UII system in the setting of diabetes using 2 unique genetically altered mice and a blocker a to study the effects of high cholesterol, diabetes and a deletion of UII.
Spatio-temporal Analysis Of Rat Intestinal Motility In Physiological And Disease Models
Funder
National Health and Medical Research Council
Funding Amount
$358,750.00
Summary
This project addresses the question of how the movements of the gut are controlled in health and disease. The progress of food along the gut is due to movements of the involuntary muscle of the wall of the intestine. Three fundamental mechanisms are involved. One is the spontaneous ability of the intestinal muscle to contract rhythmically and is driven by a delicate net of pacemaker cells. Fast propulsion of food contents depends on nerve circuits in the gut wall that generate a powerful pumping ....This project addresses the question of how the movements of the gut are controlled in health and disease. The progress of food along the gut is due to movements of the involuntary muscle of the wall of the intestine. Three fundamental mechanisms are involved. One is the spontaneous ability of the intestinal muscle to contract rhythmically and is driven by a delicate net of pacemaker cells. Fast propulsion of food contents depends on nerve circuits in the gut wall that generate a powerful pumping behaviour to prevent over-filling or to eject toxic or irritating substances (eg: some laxatives activate this mechanisms). This is often called peristalsis. A third mechanism consists of activity of nerve cells in the gut, that slowly propagates along the intestine and causes the muscle to contract, sweeping along any remnants. The movements generated by these three mechanisms occur in segments of intestine isolated from rats. The major difficulty up until now has been to relate the actual movements in living animals to these fundamental mechanisms. It is now possible to bridge this gap because we have developed methods to record, display and measure graphically the actual movements. Movements are transformed into spatio-temporal maps which show all of the contractions over a period of time. Coordinated activity is visible in these maps as recognisable patterns or visual objects. Measurements can be readily made with conventional statistics. The literature in gastroenterology is full of descriptions of motility based on indirect methods of recordings. In this project we will be able to correlate the previous indirect methods with the new graphic methods and thus establish a clearer, simpler and more accurate classification of normal patterns of intestinal motility. We will then use this to establish what goes wrong in a number of experimental diseases known to affect adversely the movements of the intestine.Read moreRead less