The Pathogenesis Of Infections Caused By Clostridium Sordellii.
Funder
National Health and Medical Research Council
Funding Amount
$400,232.00
Summary
The bacterium Clostridium sordellii causes necrosis and multiorgan failure with a very high mortality rate of 70% in infections of drug users, transplant and post-abortion patients, and 100% for post-partum patients. Little is known about how C. sordellii causes such devastating disease; treatment of these infections is currently ineffective. This project will make a major contribution to our understanding of how disease is caused and may lead to improved prevention and treatment stratetegies.
Antibiotic Resistance And The Ecological Effects Of Selective Decontamination Of The Digestive Tract In Intensive Care Units
Funder
National Health and Medical Research Council
Funding Amount
$901,396.00
Summary
We will study patients within a large trial of gut decontamination, in which antibiotics are given in advance to reduce the risk of infection. Specifically, we will determine whether there is any increased antibiotic resistance and even biodiversity loss, as some fear. This is a one-off chance to provide essential data that can help us design better national policies for antibiotic resistance control and a true personalised medicine approach to resistance and infection in ICU.
A New Class Of Inhibitors For The Treatment Of Tuberculosis
Funder
National Health and Medical Research Council
Funding Amount
$720,691.00
Summary
Tuberculosis (TB) remains a major cause of mortality and morbidity worldwide, with 1.3 million deaths annually. Some strains of the TB bacterium are resistant to all available drugs. We have identified novel chemical structures that display potent and specific activity against pathogenic mycobacteria. In this proposal we will develop optimised derivatives with more potent activity against mycobacteria, assess their stability and toxicity and determine their mode of action.
An Ace Up Their Sleeve: Characterisation Of A Novel Family Of Drug Efflux Systems Represented By The Acinetobacter AceI Exporter
Funder
National Health and Medical Research Council
Funding Amount
$400,286.00
Summary
Chlorhexidine is widely used as an antiseptic in products such as skin washes, soaps, mouthwashes, disinfectants and preservatives. We have recently discovered a novel bacterial protein which pumps chlorhexidine out of bacterial cells to make them resistant to this antiseptic agent. This proposal aims to understand this resistance mechanism and to find inhibitors which could be applied in clinical settings to augment the activity of chlorhexidine.
Reversing Antibiotic Resistance With Efflux Pump Inhibitors
Funder
National Health and Medical Research Council
Funding Amount
$494,174.00
Summary
Antibiotic resistance in dangerous pathogens is one of the greatest threats to human health of the 21st century. The main cause of multidrug resistance is the presence of drug efflux pumps, which remove antibiotics from the bacterial cell thereby lowering the antibiotic concentration inside the cells to sub-toxic levels. We will use our expertise on these efflux pumps and on how to inhibit them to develop compounds that could reverse resistance and restore the activity of antibiotics.
Design, Development And Analysis Of New Tuberculosis Drugs
Funder
National Health and Medical Research Council
Funding Amount
$736,628.00
Summary
Serious issues of drug resistance have emerged in tuberculosis prevention and are placing enormous pressure on global health systems. We have identified an enzyme of M. tuberculosis that is essential for its survival. This project will develop potent inhibitory compounds for this enzyme. Further, we will identify new drug targets through a screen to specifically identify the genes of the organism essential for its survival in the body. This information will be used to develop new TB drugs.
Exploitation Of Bacterial Transcription Initiation As A Target For New Antimicrobials
Funder
National Health and Medical Research Council
Funding Amount
$540,356.00
Summary
Antibiotic resistant infections from 'superbugs' are a major health problem. We will exploit information we have gathered on the machinery that copies genetic information into a message to discover chemical compounds that can be used for the development of new antibiotics with a novel mechanism of action.
Determining The Bacterial Contributions To Tuberculosis And Identification Of Drug Targets
Funder
National Health and Medical Research Council
Funding Amount
$443,946.00
Summary
Serious issues of drug resistance have emerged in tuberculosis prevention and are placing enormous pressure on global health systems. We have identified an enzyme of M. tuberculosis that is essential for its survival. This project will develop potent inhibitory compounds for this enzyme. Further, we will identify new drug targets through a screen to specifically identify the genes of the organism essential for its survival in the body. This information will be used to develop new TB drugs.
Once treatable infections are becoming deadly because bacteria are developing broad antibiotic resistance. New medicines are urgently needed. Microbes themselves are the richest known source of new antibiotics but finding the 'good bugs' is like finding a needle in a microbial haystack. This project will use state-of-the art science to screen a previously overlooked source of rich microbial biodiversity and find new antibiotics.
Developing New Therapies To Combat Tuberculosis Through Inhibition Of Vitamin B5 Metabolism In The Organism That Causes The Disease
Funder
National Health and Medical Research Council
Funding Amount
$311,760.00
Summary
The metabolism of vitamin B5 by pathogenic microorganisms has been recognised as an attractive target for developing drugs to combat various infectious diseases. The aim of the proposed work is to develop inhibitors of vitamin B5 metabolism in the bacterium that causes tuberculosis, using a powerful, multidisciplinary approach known as “fragment-based drug discovery”. This work is likely to yield potent inhibitors of the target bacterium, which could ultimately be used to treat tuberculosis.