Novel Compounds For Use As Inhibitors Of Virulence Of Human Pathogens
Funder
National Health and Medical Research Council
Funding Amount
$220,500.00
Summary
There is growing concern over the emergence of multi-drug resistant strains of bacteria which are no longer treatable with the current generation of antibiotics. This highlights the urgent need for development of the next generation of therapeutic agents to supplement or replace the current antibiotics. Our research team has identified a class of compounds which are naturally produced by a marine alga that may be effective in the control of bacterial pathogens. These compounds work by interferin ....There is growing concern over the emergence of multi-drug resistant strains of bacteria which are no longer treatable with the current generation of antibiotics. This highlights the urgent need for development of the next generation of therapeutic agents to supplement or replace the current antibiotics. Our research team has identified a class of compounds which are naturally produced by a marine alga that may be effective in the control of bacterial pathogens. These compounds work by interfering with the way many pathogens regulate the production of virulence traits. Some bacteria are able to signal members of their population by the specific uptake and recognition, through a receptor protein, of chemical cues they secrete into the environment. Accumulation of these cues or signals triggers expression of the genes that code for the virulence traits. Moreover, one particular class of these signal response proteins has been identified in many pathogens and has been shown to regulate protease production and production of a protective extracellular slime layer called a capsule. If one or more of these traits can be blocked, then the virulence of the bacterium can be reduced. We have preliminary data which demonstrates that the algal compounds do in fact prevent the expression of virulence traits and thus should be useful as new agents for the treatment of disease. The causative agents of cholera and severe gatroenteritis, Vibrio cholerae and V. parahaemolyticus respectively, have one or the other of these virulence traits, but the pathogen Vibrio vulnificus has all three and therefore is an excellent model pathogen. We propose to explore the ability of the algal compounds to specifically shut down expression of virulence factors with a long term aim for the development of these compounds as novel antimicrobial therapies for the post-antibiotic era.Read moreRead less
Infectious diseases are one of the leading causes of death and morbidity worldwide. In the last two decades the incidence of diseases caused by bacteria has increased dramatically with old pathogens re-emerging, often in a more virulent form, and new infectious agents appearing. Many pathogenic microbes are becoming increasingly resistant to antibiotics so that the need for new therapeutic targets is urgent. We will develop new antimicrobial chemotherapies by targeting DsbA, a specific factor in ....Infectious diseases are one of the leading causes of death and morbidity worldwide. In the last two decades the incidence of diseases caused by bacteria has increased dramatically with old pathogens re-emerging, often in a more virulent form, and new infectious agents appearing. Many pathogenic microbes are becoming increasingly resistant to antibiotics so that the need for new therapeutic targets is urgent. We will develop new antimicrobial chemotherapies by targeting DsbA, a specific factor involved in the generation of bacterial virulence. This protein is found in most bacteria and contributes to pathogenicity by promoting the formation of toxins and virulence factors. We will design specific inhibitors of DsbA by using a structure-based approach, implementing the leading edge technologies of fragment-based lead discovery by crystallography and NMR. We will then optimise the fragments to develop lead compounds and evaluate their suitability as DsbA inhibitors by in vitro and in vivo assays.Read moreRead less
The Team brings together a unique grouping of people with backgrounds in molecular biology, medical microbiology, microbiology, marine ecology and immunology to tackle a significant health problem infections caused by bacteria. Using a novel approach, based on understanding how marine organisms specifically interfere with bacterial colonisation, the Team over the past seven years has identified a group of compounds that represent a novel group of antibiotics. Publications and patenting by the Te ....The Team brings together a unique grouping of people with backgrounds in molecular biology, medical microbiology, microbiology, marine ecology and immunology to tackle a significant health problem infections caused by bacteria. Using a novel approach, based on understanding how marine organisms specifically interfere with bacterial colonisation, the Team over the past seven years has identified a group of compounds that represent a novel group of antibiotics. Publications and patenting by the Team has demonstrated that the Team is at the forefront of research in this area. The novel antibiotics work by preventing bacteria sticking to surfaces and by preventing the bacteria from releasing toxins. The studies will concentrate on those bacteria that produce infections in the lungs (acute pneumonia), eyes (corneal infection), ear (middle ear disease), and abscesses.Read moreRead less
Structure-based Design Of Inhibitors Of Oxidative Protein Folding In Enterobacteriaceae.
Funder
National Health and Medical Research Council
Funding Amount
$523,540.00
Summary
Antibiotic resistance represents a major public health problem. For gram-negative bacteria in particular, the situation is increasingly bleak, with the accumulation of resistance to existing drugs and few if any new drugs in the pipeline. We are using structure-based drug design to develop novel strategies for the treatment of gram-negative bacterial infections.