Curing Antibiotic Resistance: Probiotic Plasmids And Microbial Husbandry In The Enterobacteriaceae
Funder
National Health and Medical Research Council
Funding Amount
$560,832.00
Summary
The most troublesome emerging antibiotic resistance is coming in the form of addictive and promiscuous 'pest' plasmids, carrying dangerous genes that defeat antibiotics used for the most severe infections. We currently manage this problem by isolating infected patients and trying to design new antibiotics. Our approach eradicates these plasmids and renders the host bacterium antibiotic susceptible again, thereby restoring the natural ecology in animals and potentially in humans.
Multiple Antibiotic Resistance In An Acinetobacter Baumannii Global Clone
Funder
National Health and Medical Research Council
Funding Amount
$606,580.00
Summary
Antibiotic resistant bacteria that cause infections in hospitals can originate anywhere, then spread world wide. They start off resistant to a few antibiotics, then become resistant to new antibiotics that are introduced to treat them. This project will investigate how resistance to antibiotics was acquired by Acinetobacter baumannii which is now resistant to most antibiotics, and why the old resistance genes are not being lost. This will help track these bacteria moving into and around Australi ....Antibiotic resistant bacteria that cause infections in hospitals can originate anywhere, then spread world wide. They start off resistant to a few antibiotics, then become resistant to new antibiotics that are introduced to treat them. This project will investigate how resistance to antibiotics was acquired by Acinetobacter baumannii which is now resistant to most antibiotics, and why the old resistance genes are not being lost. This will help track these bacteria moving into and around Australia.Read moreRead less
Interactions Between Integrative Genomic Islands And Plasmids; Role In The Spread And Loss Of Antibiotic Resistance And Pathogenicity Determinants
Funder
National Health and Medical Research Council
Funding Amount
$776,465.00
Summary
Mobile elements that integrate into bacterial chromosomes at a specific site contribute pathogenicity and antibiotic resistance determinants to their bacterial host but only a few are able to move themselves into new hosts. Some plasmids and some elements can help certain others. In this project, genetic approaches will be used to investigate how plasmids and integrative elements help one another move into a new bacterium or compete with one another to stay in the same cell.
Molecular Basis For Conjugative Transfer Of Antibiotic Resistance Genes In Gram Positive Pathogens
Funder
National Health and Medical Research Council
Funding Amount
$872,660.00
Summary
There has been growing concern about the increasing level of antibiotic resistance in bacterial pathogens. We will use a model genetic element to determine the mechanism by which an important class of pathogenic bacteria can acquire new resistance genes by a process known as horizontal gene transfer. The project will significantly enhance our understanding of how major hospital and community acquired pathogenic bacteria can rapidly evolve to become resistant to different antimicrobial agents.
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.
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.
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.
The Mechanism Of Conjugative Transfer Of Antibiotic Resistance Genes In Gram Positive Pathogens
Funder
National Health and Medical Research Council
Funding Amount
$628,459.00
Summary
Antibiotic resistant bacteria pose a serious threat to the health of Australians. We will determine how antibiotic resistance genes spread from one bacterium to another. Using a disease-causing bacterium as model we will determine the mechanism by which this gene transfer process occurs and the structure and function of the key components. The result will be major advances in our understanding of the evolution of the antibiotic resistant bacteria that are major causes of human disease.
Molecular Genetics And Evolution Of Antibiotic Resistant Staphylococci
Funder
National Health and Medical Research Council
Funding Amount
$432,750.00
Summary
Potentially life-threatening 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 h ....Potentially life-threatening 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. 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 staphylococcal multiresistance plasmids efficiently replicate in the host cell and are stably maintained in growing bacterial populations or when acquired by a new host after transfer; such mechanisms may well provide novel drug targets. The results will also lead to the development of improved methods for the characterisation of clinical strains and the monitoring of antibiotic resistance, and will be of broad relevance to the problem of antimicrobial resistance in bacterial pathogens. Most importantly, the application of knowledge arising from these studies to the design and implementation of rational antibiotic usage policies has the potential to extend the efficacy of existing and future anti-staphylococcal therapies.Read moreRead less