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.
Dissecting catalysis and inhibition of a unique endo-acting mannose-processing glycosidase. Defects in the attachment of carbohydrates to proteins are a hallmark of diseases such as cancer and viral infection. This project will dissect the molecular details of the bond-making and breaking steps that occur during the synthesis of glycoproteins assisting in the development of innovative new drugs.
Novel antimicrobial surface coatings for Cochlear implants. The objective of this project is to develop new antimicrobial coatings for materials used to manufacture biomedical devices. Infection associated with the use of biomaterials such as biomedical implants, catheters and orthopaedic prostheses is a major barrier to the use of these devices. The coatings that the project plans to develop are based on novel antimicrobials which have been shown to prevent adhesion and colonisation of biomater ....Novel antimicrobial surface coatings for Cochlear implants. The objective of this project is to develop new antimicrobial coatings for materials used to manufacture biomedical devices. Infection associated with the use of biomaterials such as biomedical implants, catheters and orthopaedic prostheses is a major barrier to the use of these devices. The coatings that the project plans to develop are based on novel antimicrobials which have been shown to prevent adhesion and colonisation of biomaterials by bacteria in vivo. This strategy has the potential to prevent device-related infections and revolutionise the biomaterials industry.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.
Novel antimicrobial surface coatings for biomedical applications. There are currently no effective biomaterial coatings to reduce device related infections. Such materials are needed to address the high rates of infection that can occur. The melimine technology proposed here has the potential to significantly reduce rates of infection, reduce health care costs and advantage the Australian biomaterials industry.
Novel peptide mimics for the disruption of chemical communication in bacteria. It is now well established that bacteria communicate with each other via small diffusible signalling molecules and coordinate their activities such as biofilm formation, swarming and expression of virulence factors in a coordinated manner. This project will investigate the synthesis of novel organic molecules that have the capacity to disrupt chemical communication in bacteria. This could allow control of the unwante ....Novel peptide mimics for the disruption of chemical communication in bacteria. It is now well established that bacteria communicate with each other via small diffusible signalling molecules and coordinate their activities such as biofilm formation, swarming and expression of virulence factors in a coordinated manner. This project will investigate the synthesis of novel organic molecules that have the capacity to disrupt chemical communication in bacteria. This could allow control of the unwanted microbial activity without the use of growth inhibitory agents such as antibiotics, preservatives and disinfectants that select for the resistant organisms. This elegant approach to eradicating the virulence behaviour of microbes represents a novel strategy to combat antimicrobial resistance.Read moreRead less
New scaffolds for antimicrobial discovery. This project aims to investigate the synthesis of novel glyoxylamide antimicrobial peptide mimics that have the capacity to disrupt bacterial membranes. The innovative interdisciplinary approach expects to generate new, small molecular antimicrobial mimics that possess a low propensity for developing resistance. This could allow control of the unwanted microbial activity without the use of antibiotics that select for the resistant organisms. It will pro ....New scaffolds for antimicrobial discovery. This project aims to investigate the synthesis of novel glyoxylamide antimicrobial peptide mimics that have the capacity to disrupt bacterial membranes. The innovative interdisciplinary approach expects to generate new, small molecular antimicrobial mimics that possess a low propensity for developing resistance. This could allow control of the unwanted microbial activity without the use of antibiotics that select for the resistant organisms. It will provide excellent training for young researchers and lead to high quality research publications in international journals.Read moreRead less
Chemical probes for the study of a unique enzyme from Mycobacterium tuberculosis. The design and chemical synthesis of molecules that selectively inhibit pathogen-specific enzymes is a validated approach toward new therapeutic agents. Mycobacterium tuberculosis contains a unique cytochrome P450 enzyme that catalyses an unusual chemical transformation to generate the product mycocyclosin. This research project will synthesise chemical probes to study the mechanism of this enzyme and the biologica ....Chemical probes for the study of a unique enzyme from Mycobacterium tuberculosis. The design and chemical synthesis of molecules that selectively inhibit pathogen-specific enzymes is a validated approach toward new therapeutic agents. Mycobacterium tuberculosis contains a unique cytochrome P450 enzyme that catalyses an unusual chemical transformation to generate the product mycocyclosin. This research project will synthesise chemical probes to study the mechanism of this enzyme and the biological role of mycocyclosin. Selective inhibitors of the enzyme will be developed, which will provide a foundation for the exploitation of these molecules in cellular research and medicine.Read moreRead less
Molecular Interactions with an antibiotic target in DNA replication. This project aims to develop and use new technologies to address mechanistic aspects of anti-bacterial compounds in development, and of the development of resistance to them. The project will focus on the sliding clamp subunit of the bacterial replicative polymerase by studying its association with many other proteins in vitro and in vivo, using novel techniques in solid-state NMR, single-molecule fluorescence and molecular mic ....Molecular Interactions with an antibiotic target in DNA replication. This project aims to develop and use new technologies to address mechanistic aspects of anti-bacterial compounds in development, and of the development of resistance to them. The project will focus on the sliding clamp subunit of the bacterial replicative polymerase by studying its association with many other proteins in vitro and in vivo, using novel techniques in solid-state NMR, single-molecule fluorescence and molecular microbiology. The outcomes are expected to be an increased understanding of bacterial DNA replication and mechanisms of antibiotic action and resistance. This project expects to generate new knowledge to assist in combatting antibiotic resistance in Gram-negative bacterial pathogens.Read moreRead less
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.