Development Of New Antibacterial Peptoids To Combat Antibiotic Resistant Bacteria
Funder
National Health and Medical Research Council
Funding Amount
$181,500.00
Summary
The recent emergence of super bug bacterial strains has posed a situation where infections can not be treated. This health problem is growing rapidly with the spread of the resistant bacteria. This proposal intends to develop some of our designed anti-bacterial drugs to the point where they may be incorporated into mass clinical trials. A successful result will yield both a new antibiotic as well as an antibiotic to treat the super bugs.
Rapid HIV-1 Tropism Testing Using Novel, Soluble Mimics Of The HIV-1 Coreceptors CCR5 And CXCR4
Funder
National Health and Medical Research Council
Funding Amount
$163,426.00
Summary
This proposal seeks to develop an inexpensive assay to determine whether HIV patients will benefit from treatment with new drugs referred to as CCR5 antagonists. These are effective against HIV strains that use the CCR5 coreceptor, therefore a patient�s HIV coreceptor usage must be assessed before commencing therapy. Current assays are complicated, slow and expensive. Using novel, soluble mimics of the coreceptors we will develop an ELISA based test that can be operated using standard equipment.
Inhibitors Of Bacterial Protein Synthesis - A New Class Of Antibiotics
Funder
National Health and Medical Research Council
Funding Amount
$120,000.00
Summary
Pioneering work by CSIRO scientists has identified specific peptide motifs in the DNA replication machinery of bacteria that are critical for the correct functioning of the organism. In collaboration with CI Alewood potent (Kd ~ nM) lead compounds that inhibit bacterial DNA replication have been designed and synthesised. Through the application of a number of novel bioinformatics approaches to the analysis of the complete genome sequences of bacteria, the key sites of interaction of a number of ....Pioneering work by CSIRO scientists has identified specific peptide motifs in the DNA replication machinery of bacteria that are critical for the correct functioning of the organism. In collaboration with CI Alewood potent (Kd ~ nM) lead compounds that inhibit bacterial DNA replication have been designed and synthesised. Through the application of a number of novel bioinformatics approaches to the analysis of the complete genome sequences of bacteria, the key sites of interaction of a number of protein families (DNA synthesis and repair enzymes) with the beta subunit of bacterial DNA Polymerase III have been identified. The nature of the sites, and preliminary experimental data, suggests that the approach will be generally applicable to all species of bacteria. In addition a wide range of novel assays for the identification of inhibitors of the interaction of proteins with the beta subunit have been developed. In this proposal we wish to demonstrate that our in vitro nanomolar inhibitors of the beta subunit can inhibit bacterial cell growth. The development program proposes to develop methods and strategies to gain bacterial cell entry of inhibitors of the interaction of proteins with the beta subunit of bacterial DNA Polymerase III. Proof of concept will be demonstrated by inhibition of bacterial cell growth. Stable compounds with good binding characteristics and able to be taken up by cells will be developed based on structure-function assay results, structural studies and modelling of inhibitors bound to the target. Antimicrobial activity of compounds will be demonstrated in standard FDA approved NCLLS (National Centre of Clinical Laboratory Standards USA) tests. Spectrum of activity will be demonstrated by testing compounds against bacterial species representative of the range of pathogenic organisms in standard FDA assays.Read moreRead less
Proof Of Concept Studies On A Novel Class Of Antibiotics
Funder
National Health and Medical Research Council
Funding Amount
$199,700.00
Summary
The rise of drug-resistant superbugs is a major healthcare concern in hospitals across the world. New antibiotics are needed to combat infections caused by bacteria that are resistant to current drugs. One collaborative team of researchers is addressing the issue. They have discovered a new compound effective against Staphylococcus aureus, the cause of Golden Staph. Using a combination of scientific disciplines the team are now developing this compound into a new antibiotic.