Mechanisms Of Stable Gene Inheritance In Multiresistant Staphylococcus Aureus
Funder
National Health and Medical Research Council
Funding Amount
$620,357.00
Summary
Strains of Golden Staph bacteria resistant to many antibiotics are a major cause of serious hospital-acquired, and increasingly community-acquired, infections in Australia and around the world. The bacteria have mechanisms that cause efficient inheritance of resistance genes, even when antibiotics are no longer being used. This project will elucidate key aspects of such mechanisms so that treatments can be devised that interfere with the development and maintenance of resistance.
Horizontal And Vertical Transmission Mechanisms Of Staphylococcus Aureus Multiresistance Plasmids
Funder
National Health and Medical Research Council
Funding Amount
$408,993.00
Summary
Strains of Golden Staph bacteria resistant to many antibiotics are a major cause of serious hospital-acquired, and increasingly community-acquired, infections. The bacteria have mechanisms that cause efficient transmission of resistance genes to their offspring as well as to other strains. This project aims to elucidate key features of these mechanisms so that treatments can be devised that disrupt the maintenance and transfer of resistance, so as to prolong the effectiveness of antibiotics.
Evolution And Pathogenicity Of NDM-1 Positive Escherichia Coli
Funder
National Health and Medical Research Council
Funding Amount
$643,275.00
Summary
Antibiotic resistance (AR), as highlighted by the WHO, is the most pressing medical need of the 21C – some infections are now untreatable. Our research will focus on the new "superbug" NDM-1 positive E. coli. We will correlate AR and pathogenicity and explore the evolution of these "superbugs" using state-of-the-art sequencing. This research will benefit Australian medicine by predicting timelines of AR epidemics and by conducting the first analyses on the virulence potential of these strains.
Redefining Antibiotic Resistance Plasmid Transfer In Staphylococcus Aureus
Funder
National Health and Medical Research Council
Funding Amount
$735,585.00
Summary
Multidrug-resistant Golden Staph bacteria are a major health problem. Resistance develops rapidly because bacteria efficiently acquire/share resistance genes. Our discoveries suggest DNA transfer mechanisms are far more diverse and widespread than previously expected and this has wide-reaching implications for numerous pathogenic organisms. This project aims to define the prevalence and key features of each mechanism so treatments can be devised to disrupt the evolution and spread of resistance.
Non-coding RNA Regulation Of Virulence In Enterohaemorrhagic E. Coli
Funder
National Health and Medical Research Council
Funding Amount
$389,313.00
Summary
Shiga toxins cause potentially fatal haemolytic uremic syndrome (HUS) and are transferred between bacterial pathogens by bacteriophage (bacterial viruses). We have recently found that the Shiga toxin encoding bacteriophage encodes an unusually large number of non-coding RNAs (RNA regulators of gene expression). This Project aims to understand how these RNA regulators benefit the Shiga toxin bacteriophage and use this knowledge to develop interventions that will prevent expression of the toxin.
Genome Wide Investigations Of Mycobacterium Tuberculosis To Reveal Processes Of Pathogenesis
Funder
National Health and Medical Research Council
Funding Amount
$396,341.00
Summary
Tuberculosis remains a global health burden of staggering proportions. Around 1 in 3 people are infected with Mycobacteria tuberculosis, the organism responsible for the disease, which kills 2 million people annually. The emergence of strains now resistant to almost all of our front line drugs has placed extra pressure on researchers who are attempting to develop new protective vaccines and the critical antibiotics required to eradicate the disease. Furthermore the current global HIV pandemic is ....Tuberculosis remains a global health burden of staggering proportions. Around 1 in 3 people are infected with Mycobacteria tuberculosis, the organism responsible for the disease, which kills 2 million people annually. The emergence of strains now resistant to almost all of our front line drugs has placed extra pressure on researchers who are attempting to develop new protective vaccines and the critical antibiotics required to eradicate the disease. Furthermore the current global HIV pandemic is making the situation far worse as HIV kills the very cells of the body that protect us from tuberculosis. This research project will fill the significant gaps in our knowledge of M. tuberculosis infection, specifically identify the genes of the organism which allow it to invade and spread throughout the body. M. tuberculosis infection consists of 3 characteristic stages, i.e. colonisation, spread and long term survival in specialised structures called granulomas. It is from these granulomas that the bacterium can emerge after long periods of inactivity to cause clinical tuberculosis. Using a mouse model of infection I will define the genes needed by the bacterium to survive at these 3 key stages of disease thereby providing for a better knowledge base from which to design new vaccine strategies and to create effective drugs.Read moreRead less
The Pathogenesis Of Melioidosis: The Interaction Of Burkholderia Pseudomallei With Host Cells.
Funder
National Health and Medical Research Council
Funding Amount
$344,375.00
Summary
Melioidosis is an often fatal disease of mainly tropical Australia and SE Asia caused by a bacterium which is found in soil and water. Infection occurs via wounds or by inhalation. Melioidosis has recently become endemic in south-west Western Australia and south-eastern Queensland, and could represent an emerging disease worldwide. Melioidosis disproportionately affects Aboriginal Australians. Melioidosis has many forms including septicemia with damage to most organs, particularly lung, spleen a ....Melioidosis is an often fatal disease of mainly tropical Australia and SE Asia caused by a bacterium which is found in soil and water. Infection occurs via wounds or by inhalation. Melioidosis has recently become endemic in south-west Western Australia and south-eastern Queensland, and could represent an emerging disease worldwide. Melioidosis disproportionately affects Aboriginal Australians. Melioidosis has many forms including septicemia with damage to most organs, particularly lung, spleen and liver, acute localised suppurative infection and pneumonia. Melioidosis may also become latent, and later develop into an acute and fatal infection. It is important to understand, at the molecular level, how and why the causative bacterium is able to cause disease. Only with such an understanding can measures be undertaken to prevent the disease, or novel methods developed to control the disease. Colonisation of a host is a first step in the disease process for all bacteria which cause disease. Large protein molecules located on the surface of disease-causing bacteria are usually neccessary for colonisation of the host since they allow adherence to the surface of host cells. We have previously undertaken a basic study of adherence. This study will build on this research with the aim of identifying molecules which mediate adherence to host cells, using in vivo and in vitro methods, including the techniques of molecular biology. This study will inevitably lead to the development of vaccine candidates which is important to the management of melioidosis, particularly in high risk groups. It may also allow the development of novel antimicrobial compounds.Read moreRead less
Molecular Epidemiology And High Resolution Surveillance Of Salmonella Enterica Serovar Typhimurium In Australia
Funder
National Health and Medical Research Council
Funding Amount
$583,180.00
Summary
Salmonella typhimurium is a leading cause of the food-borne disease – salmonellosis. It is responsible for considerable morbidity and has an enormous economic cost. Molecular typing is the key to rapidly identify and control outbreaks. This project will employ next generation sequencing technology to develop a new molecular typing scheme. A surveillance system that integrates molecular typing data and epidemiological data will be developed for outbreak investigation and disease prevention.
Molecular Mechanisms Of Plasmid Maintenance In Multiply-resistant Staphylococci
Funder
National Health and Medical Research Council
Funding Amount
$543,778.00
Summary
Serious infections caused by Staphylococcus aureus bacteria, commonly known as Golden Staph, often arise as complications in patients within hospitals. These infections compromise the health of the patient and jeopardise their recovery from the condition for which they were initially admitted, which significantly increases healthcare costs. Golden Staph is a major cause of hospital-acquired infections in Australia and globally. The problem is largely due to the presence in hospitals of strains t ....Serious infections caused by Staphylococcus aureus bacteria, commonly known as Golden Staph, often arise as complications in patients within hospitals. These infections compromise the health of the patient and jeopardise their recovery from the condition for which they were initially admitted, which significantly increases healthcare costs. Golden Staph is a major cause of hospital-acquired infections in Australia and globally. The problem is largely due to the presence in hospitals of strains that are resistant to most clinically-useful antibiotics and are therefore very difficult to eradicate; the recent isolation of strains highly-resistant to one of the last resort anti-staphylococcal antibiotics, vancomycin, is particularly worrying, as is the emergence of resistant strains that cause infections in the wider community. The emergence of these multiresistant strains is primarily attributable to the acquisition of pre-existing resistance determinants by cell-to-cell gene transfer, a process in which plasmids, extra-chromosomal DNA elements, play a prominent role. Staphylococcal multiresistance plasmids carry genes that can confer resistance to up to 20 antimicrobial agents and are themselves capable of transfer between bacterial cells. In this project, we will define the molecular mechanisms by which multiresistance plasmids efficiently replicate in the host cell and are stably maintained in bacterial populations. This information will identify targets for agents that can promote the loss of plasmids and hence combat the development of resistance; the activity of one type of agent will be determined in this project. The application of knowledge arising from these studies to has the potential to extend the efficacy of existing and future antimicrobial therapies.Read moreRead less
Optimising Temporal Genomic Surveillance Of Salmonella Infections In Australia
Funder
National Health and Medical Research Council
Funding Amount
$763,447.00
Summary
Salmonella is a leading cause of the food-borne disease – salmonellosis. It is responsible for considerable morbidity and has an enormous economic cost. Molecular typing is the key to rapidly identify and control outbreaks. This project will optimise the use of whole genome sequencing for outbreak investigation and long term epidemiology. A surveillance system that integrates genome sequence and epidemiological data will be highly significant for outbreak investigation and disease prevention.