Chronic pain is a significant global health, economic and social problem, with the annual economic burden estimated at approximately $40 billion in Australia. My research will focus on the discovery and structure-function of venom peptides (trivially called toxins) from cone snails and spiders plus other Australian venomous creatures that modulate sodium and calcium channels in peripheral pain and associated pathways and optimise these for clinical development.
Chronic pain from damage to the nervous system is extremely debilitating and notoriously difficult to treat. The current drug of choice, gabapentin, has serious side effects and only works in two-thirds of patients. We have developed a drug, derived from sea snail venom, that exhibits ten times the activity of gabapentin. This proposal seeks to progress our drug to clinical trials and attract a commercial partner for its development into the market.
Elucidating The Mechanisms Of Alpha-conotoxin-induced Calcium Channel Inhibition Via G Protein-coupled Receptors
Funder
National Health and Medical Research Council
Funding Amount
$419,082.00
Summary
N-type voltage-gated calcium channels (VGCCs) are membrane proteins involved in neurotransmission and play a major role in pain. VGCCs are a well-established target for the development of analgesics. Our recent research identified that VGCCs can be inhibited by ?-conotoxins from the venom of marine snails by targeting ?-aminobutyric acid receptors in sensory neurons. We will characterize this novel form of modulation of VGCCs by ?-conotoxins and define the pathways that lead to VGCC inhibition.
Probing Central And Peripheral Calcium Channel Sybtypes With Novel Omega Conotoxins
Funder
National Health and Medical Research Council
Funding Amount
$383,168.00
Summary
New toxins including omega-conotoxin CVID have been discovered from fish eating cone snails found on the Great Barrier Reef. These toxins discriminate between ion channel receptors on nerve cells that allow calcium ions to enter the cell and nerve transmission to continue. Of great importance is the fact that CVID specifically and potently blocks nerves that transmit pain responses. This project is involved with understanding the nolecular basis for this action with the goal of underpinning the ....New toxins including omega-conotoxin CVID have been discovered from fish eating cone snails found on the Great Barrier Reef. These toxins discriminate between ion channel receptors on nerve cells that allow calcium ions to enter the cell and nerve transmission to continue. Of great importance is the fact that CVID specifically and potently blocks nerves that transmit pain responses. This project is involved with understanding the nolecular basis for this action with the goal of underpinning the design of even more selective agents that will ameliorate pain while reducing side effects.Read moreRead less
GABA(B) Receptor Modulation Of Gastrointestinal Function In Health And Disease By Alpha-Conotoxins
Funder
National Health and Medical Research Council
Funding Amount
$689,050.00
Summary
Chronic visceral pain is a common and debilitating condition arising from numerous diseases that affect our internal organs. There is a desperate need for more information about the mechanisms responsible for signalling chronic visceral pain to provide therapies and potentially find a cure for it. Our research focuses on ?-conotoxins (small peptides from marine cone snail venom) as novel potential therapeutic agents for the treatment of chronic visceral pain.
New Peptide-based Drugs For The Treatment Of Neuropathic Pain
Funder
National Health and Medical Research Council
Funding Amount
$527,171.00
Summary
Chronic pain affects 1 in 5 Australians and neuropathic pain is among the most severe forms of chronic pain. Peptides from cone snail venoms have attracted recent attention as potential therapeutic agents for the treatment of neuropathic pain. Unfortunately, these peptides suffer from the disadvantage of short biological half-lives and poor activity when taken orally. We have developed a new approach to solve these problems that we will apply to develop new drugs for the treatment of pain.
Selectivity And Mode Of Action Of Rho-conopeptide TIA: A Novel Inhibitor Of Alpha1-adrenoceptors.
Funder
National Health and Medical Research Council
Funding Amount
$399,300.00
Summary
A major obstacle to the development of safer and more effective treatments for cardivascular diseases and benign prostatic hyperplasia is the inability to find small molecules with sufficient specificity to be safe and effective. The applicant team brings together a unique set of complementary research interests and skills in using conotoxins to define, at the molecular level, how rho-conotoxins act at the alpha1-adrenoceptor, a major drug target for cardiovascualr and related diseases. Rho-cono ....A major obstacle to the development of safer and more effective treatments for cardivascular diseases and benign prostatic hyperplasia is the inability to find small molecules with sufficient specificity to be safe and effective. The applicant team brings together a unique set of complementary research interests and skills in using conotoxins to define, at the molecular level, how rho-conotoxins act at the alpha1-adrenoceptor, a major drug target for cardiovascualr and related diseases. Rho-conotoxins are novel peptide inhibitors of the alpha1-adrenoceptor that appear to act at an undescribed allosteric site. This Project will use rho-conotoxins and analogues to characterise structurally and functionally how and where this class of conopepides act. The structure activity relationship for rho-conotoxins will be established to guide the development of subtype specific inhibitors. Pairwise interactins between the alpha1-adrenoceptorand TIA will be used to dock TIA onto a homolgy model of the alpha1-adrenoceptor. The long-term goal of the project is to develop new and safer treatments for cardiovascular and related disorders.Read moreRead less
A major obstacle to the development of safer and more effective pain treatments is the poorly defined nature of the different pathways involved in chronic pain. The applicant team bring together a unique set of research expertise in using neurotoxins to define, at the molecular level, how the nervous system functions. The applicants also share a common interest in understanding and improving treatments for pain, especially chronic pain which continues to remain poorly managed Through a focus on ....A major obstacle to the development of safer and more effective pain treatments is the poorly defined nature of the different pathways involved in chronic pain. The applicant team bring together a unique set of research expertise in using neurotoxins to define, at the molecular level, how the nervous system functions. The applicants also share a common interest in understanding and improving treatments for pain, especially chronic pain which continues to remain poorly managed Through a focus on pain research, the Program will significantly enhance the scope of existing multidisciplinary collaborations between the Cis Lewis Alewood, Adams and Christie, which have already made a considerable impact in the fields of pharmacology and neuroscience. The CIs also have considerable experience in the development of pain therapeutics, having discovered two conopeptides now under commercial development with AMRAD (AM336) and Xenome Ltd (Xen2174). This Program will discover and use highly selective conopeptides such as these to dissect the pharmacology of peripheral pain pathways and their projections into the central nervous system, and to identify and characterise new targets amenable to drug intervention. The long-term goal of the Program is to discover new targets in pain pathways and develop conopeptides that act on these targets in animal models of chronic pain. These molecules will be optimised within the Program to the point where they can be considered for pre-clinical development in collaboration with commercial partners.Read moreRead less