Differentiation Of Multiple Phenotypes Of Rostral Ventromedial Medulla Neurons And Their Role In Pain
Funder
National Health and Medical Research Council
Funding Amount
$285,990.00
Summary
Chronic pain, defined as pain experienced in three out of a six month pre-interview period affects 17% of males and 20% of females in the Australian population. Opioid drugs such as morphine and codeine are the most effective drugs used to treat moderate to severe pain. However, the utility of these drugs is hampered by the development of a blunted response with repeated use. Furthermore, some clinically important pain states, particularly those caused by nerve injury, do not respond well to opi ....Chronic pain, defined as pain experienced in three out of a six month pre-interview period affects 17% of males and 20% of females in the Australian population. Opioid drugs such as morphine and codeine are the most effective drugs used to treat moderate to severe pain. However, the utility of these drugs is hampered by the development of a blunted response with repeated use. Furthermore, some clinically important pain states, particularly those caused by nerve injury, do not respond well to opioid drugs. Recent basic neurosceince research has identified groups of nerve cells deep within the brain that control sensitivity to pain as pain signals enter the spinal cord. Unfortunately in the presence of some chronic pain conditions, or chronic use of high doses of opioid drugs, these neurons undergo functional changes or adaptations that distort and increase the severity of pain sensation in a more or less permanent manner. This project uses electrical and chemical techniques to identify the basic physiology and pharmacology of single nerve cells in this brain region, so that their normal functions can be properly understood. We will then identify the cellular and molecular adaptations that occur in the nerve cells in animal models of chronic nerve injury and chronic morphine treatment to identify the nature of adaptations responsible for their aberrant function. We will then be in a position to rationally identify novel drug targets that can normalise the function of these nerve cells. This knowledge will provide potential targets for development of novel therapeutics to manage chronic pain.Read moreRead less
Structure-function Studies Of Ion Permeation And Selectivity In Recombinant Glycine Receptor Channels
Funder
National Health and Medical Research Council
Funding Amount
$331,300.00
Summary
Ligand-gated ion channels (LGICs) are members of a superfamily of receptor channels, with very significant structural and functional similarities, which play a major role in fast synaptic neurotransmission within the brain and spinal cord, and underlying the complex behaviour of the nervous system, but when dysfunctional can result in major neurological problems. Glycine is one of the two most important inhibitory neurotransmitters in the central nervous system. Impaired glycine-mediated neurotr ....Ligand-gated ion channels (LGICs) are members of a superfamily of receptor channels, with very significant structural and functional similarities, which play a major role in fast synaptic neurotransmission within the brain and spinal cord, and underlying the complex behaviour of the nervous system, but when dysfunctional can result in major neurological problems. Glycine is one of the two most important inhibitory neurotransmitters in the central nervous system. Impaired glycine-mediated neurotransmission underlies a range of inherited neurological diseases and already, it has been shown that the human disorder, familial Startle disease (hyperekplexia) occurs because of point mutations that have impaired the permeation and activation of the glycine receptor (GlyR). Similarly, certain epilepsies are now known to be caused by mutations in, or close to, the channel region in the excitatory acetylcholine receptors (AChRs), which affect channel activation and ion permeation. However, because of their very significant structural and functional similarities, information obtained in one member of the LGIC family of receptors has strong potential application to the other members and the GlyR with its simpler structure has certain advantages for investigation. The first aim of this project is to investigate how the molecular biological structure of these ion channels controls permeation, how it affects how different ions are selectively allowed to move through it and how it affects channel activation. A second related aim is to learn more about the process of desensitization of GlyR receptors, whereby a sustained presence of a high concentration of agonist can cause a reduction in receptor response. A third aim is to specifically investigate the mechanisms underlying the mode of molecular disruption resulting from two new Startle disease mutations, which, in addition to their own inherent clinical value, can also give general information about receptor function.Read moreRead less
Mechanism Of Signal Transduction And Receptor Activation In Ligand Gated Ion Channel Receptors
Funder
National Health and Medical Research Council
Funding Amount
$456,000.00
Summary
This project seeks to provide fundamental new information about the means by which neurotransmitter receptors, which mediate fast synaptic neurotransmission, operate. It will use a range of molecular advances made by this and other laboratories to clarify how neurotransmitters enable their receptors to activate and signal. This fundamental information is of major medical significance as defective synaptic transmission, caused by mutations in ligand gated ion channel receptors, give rise to a num ....This project seeks to provide fundamental new information about the means by which neurotransmitter receptors, which mediate fast synaptic neurotransmission, operate. It will use a range of molecular advances made by this and other laboratories to clarify how neurotransmitters enable their receptors to activate and signal. This fundamental information is of major medical significance as defective synaptic transmission, caused by mutations in ligand gated ion channel receptors, give rise to a number of neurological and psychiatric disease states. The ligand gated receptors are also major targets for therapeutic drugs and the information gained in this study may also provide insights into new ways in which drugs could be used to enhance or inhibit synaptic signalling.Read moreRead less