Malaria is a major global health problem. The protein AMA1 plays a key role in the invasion of host cells by malaria parasites, and agents that inhibit this interaction prevent host cell invasion and thus represent leads for the development of anti-malarial drugs. We have identified a number of chemical scaffolds that target a key site on AMA1. In this project we will optimize these leads to generate potent ligands for this site and evaluate the efficacy of these ligands as anti-malarial agents.
Crosstalk Between The Repressive Histone Methyltransferases PRC2 And G9A: Structure-function Investigation To Open New Therapeutic Opportunities
Funder
National Health and Medical Research Council
Funding Amount
$595,205.00
Summary
The gene expression programs need to be precisely regulated and the misregulation of these programs can cause a broad range of human diseases. My research will focus on two protein complexes, which heavily contribute to the regulation of gene expression. My study will open a new path for developing new therapeutic strategies.
Developing new tools for chemical biology. We will develop new synthetic strategies to support the development of small molecule chemical probes that bind with high affinity and specificity to a target protein. Such chemical probes are invaluable in elucidating the role of specific proteins in biological pathways. Our novel strategy aims to be rapid, efficient in its use of materials and widely applicable to a range of different protein targets. The core of our approach involves using biophysica ....Developing new tools for chemical biology. We will develop new synthetic strategies to support the development of small molecule chemical probes that bind with high affinity and specificity to a target protein. Such chemical probes are invaluable in elucidating the role of specific proteins in biological pathways. Our novel strategy aims to be rapid, efficient in its use of materials and widely applicable to a range of different protein targets. The core of our approach involves using biophysical binding assays to characterise compounds that are produced on small scale using parallel chemistry. This approach will enable better chemical probes to be developed more rapidly at lower cost than is currently possible.Read moreRead less
BioPPSy: An open source BIOchemical Property Prediction SYstem. Computer software will be developed for the prediction of the pharmacokinetic properties of small molecules to assist in the development of new compounds with drug-like properties. The software will be made freely available to promote its use and further development.
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
Directed Molecular Evolution Of G Protein-coupled Receptors For Stable And Functional Expression In Escherichia Coli
Funder
National Health and Medical Research Council
Funding Amount
$383,479.00
Summary
Approximately half of all prescription drugs on the market act on G protein coupled receptors (GPCRs). The mechanisms underlying GPCR function are mainly unknown due to a lack of structural information. No solved structures exist for any of the estimated 800 human GPCRs, making it difficult to design new drugs. By applying advanced protein engineering techniques I aim to produce human GPCRs in bacteria to ultimately acquire structural information, which will enable novel drug development.
Many of the most serious diseases of Western societies including obesity, Type 2 diabetes, cancer growth and metastasis and cardiovascular disease have metabolic dimensions. The enzyme AMPK regulates cellular and whole body energy homeostasis by coordinating metabolic pathways to balance energy demand with nutrient supply. We are studying the structure and function of AMPK with the aim of better treating metabolic diseases.
Alzheimer’s disease (AD), is the most common form of dementia, accounting for between 50-70% of all cases. There is general agreement that current treatments for AD/dementia are inadequate so new treatment strategies are desperately needed. I am addressing these challenges by developing new technologies to generate next generation treatments for AD.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100226
Funder
Australian Research Council
Funding Amount
$424,000.00
Summary
Advanced molecular discovery and characterisation facility. Natural product drug discovery in Australia requires access to high throughput functional assays to guide the separation and of novel bioactives with therapeutic potential. By establishing the advanced molecular discovery and characterisation facility in an academic environment across two institutions, research programs in early drug lead discovery and characterisation will be accelerated. It will provide unique capabilities not curren ....Advanced molecular discovery and characterisation facility. Natural product drug discovery in Australia requires access to high throughput functional assays to guide the separation and of novel bioactives with therapeutic potential. By establishing the advanced molecular discovery and characterisation facility in an academic environment across two institutions, research programs in early drug lead discovery and characterisation will be accelerated. It will provide unique capabilities not currently available in Australia, and help Australian researchers remain internationally competitive in breakthrough science and frontier technologies. The research enabled by this facility will lead to development of new drug candidates by the emerging Australian biotechnology industry.Read moreRead less
Molecular Basis For Stress-induced Gene Regulation—a Model System To Understand Transcriptional Deregulation In Cancer And Neurological Disease
Funder
National Health and Medical Research Council
Funding Amount
$384,076.00
Summary
Deregulated gene transcription plays a critical role in cancer formation. It is therefore important to understand the molecular basis of gene transcription and how tumour cells hijack the process. In this Project, we will study the molecular basis of stress-inducible gene expression. This is particularly important for understanding the molecular basis of cancer as stress-inducible genes are activated by transcription factors implicated in breast, colon, lung, and prostate cancers.