Role Of Calcium Channels And Small-conductance Potassium Channels In Myenteric Neurons
Funder
National Health and Medical Research Council
Funding Amount
$131,717.00
Summary
This proposal will investigate the electrical properties of neurons in the wall of the intestine that control movements of the bowel. These neurons form an extensive network that runs the length of the gastrointestinal tract and control mixing and propulsion of food along the intestine. We will determine the basic electrical properties of these neurons and investigate why some of them transmit signals in a continuous manner while others transmit signals intermittently and how these patterns of a ....This proposal will investigate the electrical properties of neurons in the wall of the intestine that control movements of the bowel. These neurons form an extensive network that runs the length of the gastrointestinal tract and control mixing and propulsion of food along the intestine. We will determine the basic electrical properties of these neurons and investigate why some of them transmit signals in a continuous manner while others transmit signals intermittently and how these patterns of activity fit into the overall activity of the gut. This study will build on a large body of data obtained from our laboratory that has shown that some of these neurons act as sensors of the presence-absence of food in the intestine while others send signals to the muscle in the wall of the intestine to either relax or contract it so that the food can be processed properly. By knowing what makes these neurons different from each other we will be able to understand what goes wrong in functional bowel disorders where motility is affected, resulting in pain and discomfort.Read moreRead less
How The Intestinal Microenvironment Controls Propulsion And Mixing Of Food In The Gut: Parallel Transduction Pathways
Funder
National Health and Medical Research Council
Funding Amount
$1,157,350.00
Summary
This project will identify the mechanisms that control the mixing of food with digestive juices, the absoprtion of nutrients from the gut to the blood stream and the excretion of waste. Disruption of these processes causes significant health problems and is associated with normal aging and many diseases. We will identify nutrients and other food components (eg spices) that switch gut from mixing to propulsion and hence identify targets to treat disorders of gut movement.
Long Term Changes In Excitability Of Enteric Neurons
Funder
National Health and Medical Research Council
Funding Amount
$198,414.00
Summary
A large proportion of the community, about 20% at any one time, suffer from functional bowel disorders, the most common of which is the irritable bowel syndrome (IBS). The bowel in these patients appears normal; there are no overt changes in its appearance. However, the patients have discomfort, pain, abdominal bloating and altered bowel habits, which can include constipation and-or diarrhoea. There is general agreement that an alteration in the responsiveness of sensory neurons of the digestive ....A large proportion of the community, about 20% at any one time, suffer from functional bowel disorders, the most common of which is the irritable bowel syndrome (IBS). The bowel in these patients appears normal; there are no overt changes in its appearance. However, the patients have discomfort, pain, abdominal bloating and altered bowel habits, which can include constipation and-or diarrhoea. There is general agreement that an alteration in the responsiveness of sensory neurons of the digestive tract occurs in IBS. Until our recent discovery of long-term increases in excitability of intrinsic sensory neurons in the small intestine, no possible cellular basis for altered sensory neuron responsiveness that could underlie IBS had been found. We will investigate the mechanism of the long-term increase in excitability and will investigate drugs that are expected to modify its induction and-or maintenance. We expect that this work will aid in unravelling the genesis of IBS and will eventually lead to strategies to treat this common debilitating condition.Read moreRead less
The applicant aims to improve treatment of digestive disease by identifying and understanding the interactions between the nervous system and the gastrointestinal (GI) tract, with emphasis on sensory systems.
Mechanisms Of Long Term Excitability Changes In Enteric Neurons
Funder
National Health and Medical Research Council
Funding Amount
$308,250.00
Summary
The intestine contains within its walls a nerve circuitry, the enteric nervous system, that controls many of its activities. The intestine itself adapts to circumstances, such as diet, and to pathological changes, such as infection or inflammation. In fact, changes in the intestine can outlast the events that cause them. This implies that there are prolonged changes in properties of control systems in the intestine. We have discovered that the intrinsic sensory neurons of the intestine exhibit l ....The intestine contains within its walls a nerve circuitry, the enteric nervous system, that controls many of its activities. The intestine itself adapts to circumstances, such as diet, and to pathological changes, such as infection or inflammation. In fact, changes in the intestine can outlast the events that cause them. This implies that there are prolonged changes in properties of control systems in the intestine. We have discovered that the intrinsic sensory neurons of the intestine exhibit long-term excitability increases following prolonged, low frequency, stimulation of their inputs from other neurons. This phenomenon has been called sustained slow postsynaptic excitation (SSPE). We have begun to examine the mechanisms behind the SSPE, and have discovered that it involves the enzymatic modification of molecules in the intrinsic sensory neurons. In this work, we will identify the enzymes and their molecular targets. This will add to basic knowledge of how the digestive system performs its task and adapts over time. It will provide data that can be used to predict molecules that might be of therapeutic value in dealing with chronic disorders in the intestine, such as irritable bowel syndrome.Read moreRead less
Characterisation Of Ion Channels That Are Potential Therapeutic Targets In Enteric Neurons
Funder
National Health and Medical Research Council
Funding Amount
$535,141.00
Summary
Disorders of intestinal movement (motility) are common and cause considerable suffering, absenteeism and social disruption. Disorders include motility disturbances that occur in irritable bowel syndrome (IBS); constipation, which is a considerable problem in the aged; slow transit disorders; and diarrhoea. The movements of the intestine are controlled by the enteric nervous system. This project aims to find targets for therapy of motility disorders within the enteric nervous system
Distribution, Pharmacology, Molecular Identity And Roles Of Purine Receptors In Enteric Neurons
Funder
National Health and Medical Research Council
Funding Amount
$395,250.00
Summary
Digestive function needs to be adapted to the great variety of foods that we eat, and to our variable dietary habits. Adaptation is controlled through an extensive nervous system in the wall of the gastrointestinal tract, the enteric nervous system, and through digestive system hormones. The enteric nervous system detects the volume and key chemical components in the gastrointestinal lumen and, through an integrating nerve circuitry, causes changes in the patterns of movement, fluid secretion an ....Digestive function needs to be adapted to the great variety of foods that we eat, and to our variable dietary habits. Adaptation is controlled through an extensive nervous system in the wall of the gastrointestinal tract, the enteric nervous system, and through digestive system hormones. The enteric nervous system detects the volume and key chemical components in the gastrointestinal lumen and, through an integrating nerve circuitry, causes changes in the patterns of movement, fluid secretion and local blood flow. Digestive system diseases, for example irritable bowel syndrome, can involve disordered function of the enteric nervous system, and there is considerable research and development focus to identify drug targets in the enteric nervous system that can be used in therapy. Amongst potential targets are receptors for purines that are located on enteric neurons and are one of the important classes of receptor that is involved in communication between the neurons. These studies aim to identify the purine receptors, their roles in controlling digestive function and their potential as therapeutic targets in the treatment of digestive disease.Read moreRead less
The Role Of Voltage-gated Na+ And Ca2+ Channels In Post-inflammatory Hyperexcitability Of Enteric Neurons
Funder
National Health and Medical Research Council
Funding Amount
$520,000.00
Summary
Gastrointestinal inflammation causes changes in neurons that control gut functions (motility and secretion). These changes in neuronal properties lead to the development of post-inflammatory motility disorders. This will be the first detailed study of neuronal ion channels that are changed after inflammation in the gut. Our study will open the way to the development of therapeutic agents to treat post-inflammatory IBS and other conditions that involve disorders of motility.
Properties And Electro-Physiology Of The Intrinsic Nervous System
Funder
National Health and Medical Research Council
Funding Amount
$419,214.00
Summary
The gut contains a very large number of nerve cells which fall into several functionally distinct groups. We have identified virtually all these functional groups in the guinea-pig small intestine and have begun an analysis of the ways the different groups communicate with each other. We have developed methods to identify the functions of any nerve cell from which we record and have also developed novel methods for specifically stimulating individual functional classes of nerve cells that contac ....The gut contains a very large number of nerve cells which fall into several functionally distinct groups. We have identified virtually all these functional groups in the guinea-pig small intestine and have begun an analysis of the ways the different groups communicate with each other. We have developed methods to identify the functions of any nerve cell from which we record and have also developed novel methods for specifically stimulating individual functional classes of nerve cells that contact them. The aim of the proposed research is to exploit these methods to identify the chemicals used by specifc types of nerve cell in transmission of information to other nerve cells during the normal behaviour of the intestine. We will record the behaviour of individual nerve cells in the gut wall while stimulating specific nerve pathways that contact them. We will then use drugs that block the activity of the chemicals of interest (small proteins called tachykinins, and certain amine compounds) to try and block the transmission of information between the nerve cells involved. Identification of the nature of the chemicals used at specific connections between different functional groups of nerve cells in the gut will allow the design of drugs for treatment of gastrointestinal disorders that will have minimal side effects. Further because the chemicals that are used for communication in the gut are also found in the brain, the results will provide evidence about the functions of these chemicals elsewhere in the nervous system.Read moreRead less
Mechanisms Regulating Nutrient Induced Motor Patterns In The Isolated Small Intestine
Funder
National Health and Medical Research Council
Funding Amount
$427,750.00
Summary
The movements of the small intestine are essential for the digestion and absorption of a meal and consist of two basic patterns during a 3-4 hour period after a meal. These are mixing (or segmentation) and propulsion (or peristalsis). Although it is the subject of ongoing study, much is known about the basic mechanisms that control propulsion, largely because this behaviour is readily seen in isolated segments of gut so it is possible to undertake highly controlled experiments to identify the va ....The movements of the small intestine are essential for the digestion and absorption of a meal and consist of two basic patterns during a 3-4 hour period after a meal. These are mixing (or segmentation) and propulsion (or peristalsis). Although it is the subject of ongoing study, much is known about the basic mechanisms that control propulsion, largely because this behaviour is readily seen in isolated segments of gut so it is possible to undertake highly controlled experiments to identify the various cellular components of the system. By contrast, mixing has only been reliably seen in intact animals making studies of the detailed mechanisms responsible for this behaviour much more difficult. What is known is that the composition of a meal controls the relative amount of mixing and propulsion seen at any location along the small intestine. We have recently identified a pattern of contractions in isolated small intestine (duodenum and-or jejunum) that is induced by the presence of a nutrient in the intestine and appears very similar to the mixing behaviour seen in the intact animal. We have shown that this pattern depends on the activity of nerve cells including those that excite the gut muscle and that it depends on the activity of a hormone released from the lining of the gut wall by fats and other nutrients. The aims of this proposal are to identify how nutrients interact to produce this pattern of contractions, the relative roles of specific types of nerve cells and the sites at which the local hormones released by nutrients act. This is important because increasing the proportion of mixing to propulsion enhances the absorption of nutrient from a meal, so if the mechanisms that initiate mixing behaviour can be regulated in a predictable way by specific nutrient, absorption can be enhanced in various malabsorption syndromes.Read moreRead less