Mechanism Of Signal Transduction And Receptor Activation In Ligand Gated Ion Channel Receptors
Funder
National Health and Medical Research Council
Funding Amount
$551,560.00
Summary
This project seeks to provide fundamental new information about the means by which neurotransmitter receptors, which mediate fast synaptic neurotransmission, operate. This knowledge is important since the Cys-loop family of ligand gated ion channel receptors are responsible for a wide range of neuronal signalling and the control of both excitatory and inhibitory receptors. The Cys-loop receptors are modulated by both therapeutic drugs (eg. benzodiazepines, barbiturates, antiemetics) and by recre ....This project seeks to provide fundamental new information about the means by which neurotransmitter receptors, which mediate fast synaptic neurotransmission, operate. This knowledge is important since the Cys-loop family of ligand gated ion channel receptors are responsible for a wide range of neuronal signalling and the control of both excitatory and inhibitory receptors. The Cys-loop receptors are modulated by both therapeutic drugs (eg. benzodiazepines, barbiturates, antiemetics) and by recreational drugs (eg. alcohol, nicotine). They are also targets for development of new therapeutic drugs, such as allosteric modulators of nAChR for memory enhancement, or modulating GlyR to relieve spasticity or chronic pain. The project 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, gives 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
Cartilage Destruction In Arthritis: Mechanism Of Aggrecanase And Matrix Metalloproteinase Action In Vivo And In Vitro
Funder
National Health and Medical Research Council
Funding Amount
$703,180.00
Summary
Arthritis is a disease that causes pain, deformity and disability. The lack of adequate therapies for arthritis is partly a reflection of our limited understanding of the biochemical events involved in disease progression and cartilage destruction. Two distinct families of enzymes are present in cartilage. These are the MMP and the ADAMTS family. These enzyme families are important for cartilage turnover in normal growth and skeletal development. However unregulated enzyme activity resulting in ....Arthritis is a disease that causes pain, deformity and disability. The lack of adequate therapies for arthritis is partly a reflection of our limited understanding of the biochemical events involved in disease progression and cartilage destruction. Two distinct families of enzymes are present in cartilage. These are the MMP and the ADAMTS family. These enzyme families are important for cartilage turnover in normal growth and skeletal development. However unregulated enzyme activity resulting in accelerated cartilage breakdown leads to the pathology recognised as arthritis. While some activities of the MMP and ADAMTS families have been studied in the laboratory, there have been no in vivo studies to determine which family is responsible for cartilage destruction, and which is therefore most appropriate for targeting by drugs. This project will create genetically-modified mice, resistant to either the MMP or the ADAMTS enzymes. The mice will be used in experimental arthritis models to determine which enzymes play the major role in initiating disease, which enzymes are involved in disease progression and which enzymes may be important for repair. In parallel studies, the highly specialised matrix molecule, keratan sulphate, will be studied for its role in cartilage destruction. There is preliminary evidence to suggest that keratan sulphate may be involved in the regulation of ADAMTS activity. The possible direct and indirect modalities of keratan sulphate action will be investigated. The results of this arthritis project will (a) yield new information on the mechanism of disease action; (b) identify targets for the rational design of disease-modifying drugs; (c) elucidate biochemical processes involved in normal skeletal growth and cartilage repair; and (d) provide new in vivo models for testing the efficacy of arthritis therapies.Read moreRead less