Towards an influenza virus glycan interaction map (Glycointeractome). This project will use nuclear magnetic resonance (NMR) spectroscopy to map carbohydrate interaction used by the virus to cause infection and spread. This information will provide new direction in anti-influenza drug discovery.
Understanding the cardioprotective effects of flavonols. Heart attack and stroke are a major cause of death and disablement in Australia. Current therapies do not treat the underlying causes of these diseases. In this project we will investigate a promising new drug treatment for these diseases and will determine how this poorly understood drug acts to reduce damage to the heart. This project will lead to new treatments for cardiovascular diseases and will enhance our understanding of the causes ....Understanding the cardioprotective effects of flavonols. Heart attack and stroke are a major cause of death and disablement in Australia. Current therapies do not treat the underlying causes of these diseases. In this project we will investigate a promising new drug treatment for these diseases and will determine how this poorly understood drug acts to reduce damage to the heart. This project will lead to new treatments for cardiovascular diseases and will enhance our understanding of the causes of these disease states.Read moreRead less
Structure-activity relationships in the development of new bioactive isoflavonoids. This project aims to develop new chemical substances based on the structure of a group of naturally occuring compounds called isoflavones. Biological activity related to chronic inflammatory (eg arthritis) and heart disease will be examined in cells and animal models. This information will be used to design compounds with enhanced activity. The eventual aim is to develop potential therapeutic agents to treat chr ....Structure-activity relationships in the development of new bioactive isoflavonoids. This project aims to develop new chemical substances based on the structure of a group of naturally occuring compounds called isoflavones. Biological activity related to chronic inflammatory (eg arthritis) and heart disease will be examined in cells and animal models. This information will be used to design compounds with enhanced activity. The eventual aim is to develop potential therapeutic agents to treat chronic inflammatory and cardiovascular disease.Read moreRead less
Development of small molecule primary sulfonamides as new drugs for malaria. Malaria is a major global health threat, causing approximately 800,000 deaths annually. Lives can be saved if patients are treated. The use of current antimalarial drugs is limited by drug resistance, low activity and poor safety. This project investigates the effectiveness of a new class of molecule as a safe drug treatment option to kill malaria parasites.
Interrogating diarylquinoline toxicity with targeted organic synthesis. Bedaquiline is the only new first-line treatment with a new mechanism of action to treat TB in the last 40 years, approved by the FDA on 31 December 2012. Alarmingly, this compound, has significant toxicities. The hypothesis tested in this project is that decreasing lipophilicity and basicity in this class of compounds while retaining target affinity will decrease toxicity but retain anti-TB activity. The project aims to: sy ....Interrogating diarylquinoline toxicity with targeted organic synthesis. Bedaquiline is the only new first-line treatment with a new mechanism of action to treat TB in the last 40 years, approved by the FDA on 31 December 2012. Alarmingly, this compound, has significant toxicities. The hypothesis tested in this project is that decreasing lipophilicity and basicity in this class of compounds while retaining target affinity will decrease toxicity but retain anti-TB activity. The project aims to: synthesise novel heteroarylalkylamines distinct from bedaquiline and designed to be more polar, less basic, and metabolically more stable; and, test all successfully synthesised target compounds for mechanism-based anti-tuberculosis activity, hERG-mediated cardiotoxicity, metabolic instability, and phospholipidosis.Read moreRead less
Mannosyl transfer processes in leishmania and mycobacteria. The human diseases leishmaniasis and tuberculosis are caused by infectious microorganisms. We will target pathways to the biosynthesis and degradation of parasite-specific mannose containing metabolites that play essential roles in the ability of these pathogens to cause disease. We will develop new ways to study these pathways, and will synthesize novel substrates and inhibitors that will allow the development of antituberculosis and a ....Mannosyl transfer processes in leishmania and mycobacteria. The human diseases leishmaniasis and tuberculosis are caused by infectious microorganisms. We will target pathways to the biosynthesis and degradation of parasite-specific mannose containing metabolites that play essential roles in the ability of these pathogens to cause disease. We will develop new ways to study these pathways, and will synthesize novel substrates and inhibitors that will allow the development of antituberculosis and antileishmanial drugs. This project will contribute to our national competitiveness in the newly emerging area of chemical biology.Read moreRead less
Mannose metabolism in pathogenic microorganisms. Current treatments for tuberculosis and leishmaniasis are failing due to chronic underinvestment by the private sector and public agencies over many decades. The causative agents, the microorganisms Leishmania spp and Mycobacterium tuberculosis, respectively, use sugar processing pathways that differ from humans, and thus represent targets for new drugs. We will study two related sugar-processing biochemical pathways in these organisms. We will de ....Mannose metabolism in pathogenic microorganisms. Current treatments for tuberculosis and leishmaniasis are failing due to chronic underinvestment by the private sector and public agencies over many decades. The causative agents, the microorganisms Leishmania spp and Mycobacterium tuberculosis, respectively, use sugar processing pathways that differ from humans, and thus represent targets for new drugs. We will study two related sugar-processing biochemical pathways in these organisms. We will develop new ways to measure enzyme activity using mass spectrometry, and new reagents to clone several biosynthetic enzymes. Our work will lay a foundation for new antibiotics to combat these insidious diseases, and will foster Australian expertise in chemical biology and innovative basic science.Read moreRead less
Inhibitors of enzymes in the lysine biosynthetic pathway. Recent reports of increasing bacterial resistance to antibiotics highlight the need for continual development of new antibacterial agents. Inhibitors of the biosynthesis of the amino acid lysine - an essential component of bacterial proteins and cell wall - may provide a novel class of antibiotics. This project describes investigations of the mechanism of the first two enzymes in the lysine biosynthetic pathway and the design and synthesi ....Inhibitors of enzymes in the lysine biosynthetic pathway. Recent reports of increasing bacterial resistance to antibiotics highlight the need for continual development of new antibacterial agents. Inhibitors of the biosynthesis of the amino acid lysine - an essential component of bacterial proteins and cell wall - may provide a novel class of antibiotics. This project describes investigations of the mechanism of the first two enzymes in the lysine biosynthetic pathway and the design and synthesis of inhibitors of these enzymes.Read moreRead less
Fragment based screening to deliver drugs targeting tuberculosis and the gametocyte and liver stages of Plasmodium. This project will identify natural products that bind to critical proteins in malaria and tuberculosis to discover new ways to treat these diseases.
Allosteric modulators as novel probes of G-Protein coupled receptor function. This research will provide novel mechanistic understanding on the function of one of the largest protein families in the mammalian genome, and the most important family with respect to drug targets. The insights gained thus have direct relevance to drug discovery. The discovery of novel G protein-coupled receptor (GPCR) allosteric enhancers will not only lead to potentially new therapeutic agents, but can significant ....Allosteric modulators as novel probes of G-Protein coupled receptor function. This research will provide novel mechanistic understanding on the function of one of the largest protein families in the mammalian genome, and the most important family with respect to drug targets. The insights gained thus have direct relevance to drug discovery. The discovery of novel G protein-coupled receptor (GPCR) allosteric enhancers will not only lead to potentially new therapeutic agents, but can significantly value-add to other national research efforts focusing on GPCR structural biology.Read moreRead less