Molecular Mechanisms Of G Protein-Coupled Receptor Cross Talk
Funder
National Health and Medical Research Council
Funding Amount
$256,980.00
Summary
The normal function of all living cells depends on how they respond to the multitude of physical and chemical stimuli to which they are constantly exposed. The majority of chemical stimuli acting on cells do so not by directly entering the cell, but rather by acting on specific types of receiver proteins on the cell's surface called receptors. One important family of receptors transmit their message to the inside of the cell by coupling to yet another type of protein known as the G protein. Aber ....The normal function of all living cells depends on how they respond to the multitude of physical and chemical stimuli to which they are constantly exposed. The majority of chemical stimuli acting on cells do so not by directly entering the cell, but rather by acting on specific types of receiver proteins on the cell's surface called receptors. One important family of receptors transmit their message to the inside of the cell by coupling to yet another type of protein known as the G protein. Aberrations in the normal function of these G protein-coupled receptors have been implicated in a wide variety of disorders, such as schizophrenia, pain and dementia. To date, most therapeutic approaches to treating these disorders have targeted individual types of G protein-coupled receptors thought to play a role in each disease state, but this has met with mixed success. One of the reasons for this is that each disorder actually involves more than one type of G protein-coupled receptor communicating with other types in a complex way. Our current proposal specifically focuses on some of the newer mechanisms that have been suggested to play an important role in the communication between different types of G protein-coupled receptors located in the same type of cell. An understanding of how such receptor proteins can communicate with one another in this situation is absolutely vital in unravelling processes involved in the maintenance of health, abnormalities that lead to disease and in the development of more effective treatments.Read moreRead less
The maintenance of optimum health and function of living cells, and consequently that of the whole organism, depends on how cells respond to a multitude of physical and chemical stimuli that continually bombard them. The majority of the chemical stimuli such as hormones and neurotransmitters impart their actions not by directly entering the cell, but instead, by binding to a specific receiver protein at the cell surface called a receptor. In one class of such receptors called G protein coupled r ....The maintenance of optimum health and function of living cells, and consequently that of the whole organism, depends on how cells respond to a multitude of physical and chemical stimuli that continually bombard them. The majority of the chemical stimuli such as hormones and neurotransmitters impart their actions not by directly entering the cell, but instead, by binding to a specific receiver protein at the cell surface called a receptor. In one class of such receptors called G protein coupled receptors, the transmission of the message to the interior of the cell involves yet another protein called G protein. It is extremely important to unravel how each of these components, the stimulating agent, the receptor and G protein, works in order to understand how the cells respond to various chemical signals. To make this process even more complex, it was recently shown that another newly discovered group of proteins called receptor activity modifying proteins (RAMPs) too play a critical role in some systems. Understanding what actually is the role of these new players, and how they team-up with the other components to elicit a specific response to a chemical stimulus, forms the basis of this proposal. Such knowledge is central to the unraveling of the processes involved in the maintenance of health, abnormalities that lead to disease, and in the development of new treatments.Read moreRead less
Alteration Of Glucose Metabolism By GPCR Activation
Funder
National Health and Medical Research Council
Funding Amount
$444,796.00
Summary
In type 2 diabetes the effect of insulin to stimulate glucose transport in fat cells and skeletal muscle is impaired so there is great interest in identifying insulin-independent mechanisms that increase glucose transport. Several G protein-coupled receptors (GPCRs) regulate glucose transport independently of insulin but the mechanisms involved in these effects are largely unknown. This project investigates how GPCRs regulate glucose homeostasis and will evaluate them as potential treatments.
Understanding The Mechanisms Used By G-protein Coupled Receptors To Regulate Insulin-independent Glucose Transport
Funder
National Health and Medical Research Council
Funding Amount
$105,590.00
Summary
In type 2 diabetes, stimulation of glucose transport in fat cells and skeletal muscle by insulin is impaired. As a result there is great interest in identifying insulin-independent mechanisms that increase glucose transport. Several G-protein coupled receptors (GPCRs) regulate glucose transport independently of insulin but the mechanisms involved in these effects are largely unknown. This project investigates how GPCRs regulate glucose transport for potential as treatments.
The Molecular Mechanism Of Ion-coupled Transport In The Brain
Funder
National Health and Medical Research Council
Funding Amount
$441,407.00
Summary
Cells in the brain communicate through chemical signals called neurotransmitters. Neurotransmitter transporters reside in the membranes of cells and are responsible for regulating levels of these chemicals in the brain. They play an important role in the normal function of the human brain but their dysfunction is responsible for many diseases including Alzheimer's disease and motor neuron disease. It is crucial to understand how these proteins work in both normal and disease states.