Unraveling Fibrosis By Pharmacological Targeting Of The G Protein-coupled Receptor, RXFP1
Funder
National Health and Medical Research Council
Funding Amount
$798,618.00
Summary
Peptides, with their high specificity and low toxicity profiles, are highly attractive alternatives to small molecule drugs. H2 relaxin, a peptide hormone, has a strong potential for treating fibrosis. However, the large size of H2 relaxin makes it difficult and expensive to manufacture. Once administered to patients, it is also quickly degraded. We have developed a small anti-fibrotic relaxin peptide, and propose to understand its mechanism of action and improve its therapeutic indices.
Modulation Of Feeding Through Pharmacological Targeting Of The Relaxin-3 Receptor RXFP3
Funder
National Health and Medical Research Council
Funding Amount
$584,955.00
Summary
Relaxin-3 is a neuropeptide that regulates a number of physiological processes, including food intake, suggesting that the relaxin-3 receptor RXFP3 may be a new target for treatment of eating disorders such as obesity. This project will develop new selective and high-affinity ligands for RXFP3, which will be critical pharmacological tools for the preclinical studies and evaluation of this system.
Gastrokine 2 Promotes Gastric Homeostasis And Inhibits Bacterial Pathology
Funder
National Health and Medical Research Council
Funding Amount
$621,335.00
Summary
Gastrokine 2 is a small regulatory protein secreted by the stomach lining. Its function is unknown but data from our lab suggests that it may be important in maintaining stomach integrity. This project will investigate how gastrokine 2 maintains stomach function, how this can be compromised when bacterial infection is ongoing, and how we might be able to turn up gastrokine 2 expression to prevent inflammation and precancerous changes in the stomach lining.
Development of Insulin-like peptide 5 (INSL5) peptide analogues as novel therapeutics. Insulin-like peptide 5 (INSL5) is a naturally-occurring hormone in the body that likely plays a role in the control of appetite. This project aims to develop new molecules based on INSL5 that could be suitable for use as drugs to treat various appetite-related disorders, such as obesity (where patients eat too much) or anorexia (where patients eat too little).
Solid phase synthesis of side-chain cross-linked peptide oligomers. This research will provide a unique opportunity to investigate the biological pathways and causative factors leading to diseases such as Alzheimer’s disease. Such information will guide the design and development of therapeutic strategies and diagnostic reagents.
Discovery And Development Of Better Pain Treatments
Funder
National Health and Medical Research Council
Funding Amount
$9,613,850.00
Summary
Many forms of pain remain poorly treated, leading to significant quality of life and economic losses. This Program grant will discover and characterise new peptides from cone snails and spiders that modulate specific channels in nerves that are critical to the transmission of pain signals to the brain. Using advanced chemical and structural approaches, promising leads will be optimised for potency and stability and evaluated in disease and pathway-specific models of pain to establish their clini ....Many forms of pain remain poorly treated, leading to significant quality of life and economic losses. This Program grant will discover and characterise new peptides from cone snails and spiders that modulate specific channels in nerves that are critical to the transmission of pain signals to the brain. Using advanced chemical and structural approaches, promising leads will be optimised for potency and stability and evaluated in disease and pathway-specific models of pain to establish their clinical potential.Read moreRead less
Novel Approaches To Understanding Peptide G-protein-coupled Receptor Activation
Funder
National Health and Medical Research Council
Funding Amount
$665,043.00
Summary
G protein-coupled receptors (GPCRs) are proteins that exist on every human cell, where they sense, and respond to environmental stimuli. Because of their importance they are targeted by drugs to treat many diseases. However little is known about the molecular steps that underlie cellular responses upon drug binding and this has hindered new drug development. This project uses new technology to determine the complex pathway of GPCR activation upon drug binding which will aid new drug development.
Unravelling The Binding And Activation Mechanism Of A Complex G Protein-coupled Receptor
Funder
National Health and Medical Research Council
Funding Amount
$1,041,638.00
Summary
The peptide hormone relaxin is currently in a Phase III trial for the treatment of heart failure. However the peptide is not a good drug as it can't be taken orally and is very expensive to produce. We will study the interaction of relaxin with its cell surface receptor and the mechanisms by which the receptor functions. The knowledge gained will aid in the design of smaller, more potent and orally active forms of relaxin for the treatment of heart failure
Towards the development of orally active antimicrobial peptides with distinctive mode of action. This project aims to design and develop novel antibacterial compounds to address one of humankind's greatest health concerns, that of antibacterial resistance. These will be further modified to make them orally available, thus enhancing their therapeutic and clinical potential.
Novel target of amiloride analogues - picornaviral RNA polymerase. Picornaviruses cause a range of diseases such as poliomyelitis, meningitis, myocarditis, hepatitis A, neonatal sepsis and common cold. No antiviral treatment is available for these infections. Nearly 50% of antiviral drugs used in medicine are viral polymerase inhibitors; however picornaviral RNA polymerase has been largely overlooked as a drug target. We have discovered a group of compounds that inhibit picornaviral RNA polymera ....Novel target of amiloride analogues - picornaviral RNA polymerase. Picornaviruses cause a range of diseases such as poliomyelitis, meningitis, myocarditis, hepatitis A, neonatal sepsis and common cold. No antiviral treatment is available for these infections. Nearly 50% of antiviral drugs used in medicine are viral polymerase inhibitors; however picornaviral RNA polymerase has been largely overlooked as a drug target. We have discovered a group of compounds that inhibit picornaviral RNA polymerase. This project aims to define the inhibition mechanism and to evaluate a potential use of these compounds for antiviral drug development.Read moreRead less