Molecular Epidemiology Of Antibiotic Resistant Salmonella Enterica Strains Causing Human Disease
Funder
National Health and Medical Research Council
Funding Amount
$493,767.00
Summary
Salmonella infections are responsible for a substantial proportion of reported food poisoning cases caused by bacteria and many of these infections are due to antibiotic resistant strains. Infections caused by antibiotic resistant organisms are hard to treat and generally more severe, of longer duration, and result in longer hospital stays. These strains are mostly acquired from foods, e.g. meats, dairy products, poultry, eggs, and other contaminated food products but can also be derived from ot ....Salmonella infections are responsible for a substantial proportion of reported food poisoning cases caused by bacteria and many of these infections are due to antibiotic resistant strains. Infections caused by antibiotic resistant organisms are hard to treat and generally more severe, of longer duration, and result in longer hospital stays. These strains are mostly acquired from foods, e.g. meats, dairy products, poultry, eggs, and other contaminated food products but can also be derived from other sources. Salmonella strains harboured by food-producing animals are the source of most of the food contamination.Tracing the source of individual resistant strains is essential for eradication and as there are many Salmonella types, some of which are found associated only with specific animals or birds, accurate identification is needed. The proposed work will make this process more accurate by using molecular techniques to unequivocally establish suspected connections and reveal further ones that are difficult to discern using current data and methods. This should decrease the number of infections due to resistant strains.Read moreRead less
A New Mechanism For Transposition Of Antibiotic Resistance Genes
Funder
National Health and Medical Research Council
Funding Amount
$501,839.00
Summary
Understanding how antibiotic resistance genes are acquired by bacteria is important if we are to understand how bacteria become resistant in so many antibiotics, limiting treatment options. This project will investigate the way a family of insertion sequences captures and then moves resistance genes. This mechanism contributes to resistance in many bacterial pathogens including ones that are resistant to many different antibiotics.
Pathways To Extensive And Pan Antibiotic Resistance In The Globally Disseminated Acinetobacter Baumannii GC2 Clone
Funder
National Health and Medical Research Council
Funding Amount
$865,004.00
Summary
The project will study the evolution of a Acinetobacter baumannii clone that is found all around the world, and has become resistant to most or all of the currently available antibiotics. Resistance has been acquired in a series of steps, and the resistance genes present and the events involved will be used to understand the globalization process. The increased understanding of resistance development should assist in controlling untreatable infections and in preserving antibiotics.
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.
Role Of IS26 In Antibiotic Resistance Gene Recruitment, Dissemination And Expression
Funder
National Health and Medical Research Council
Funding Amount
$457,879.00
Summary
Antibiotic resistance is increasing, compromising the efficacy of front-line antibiotics. Untreatable infections due to bacteria that are resistant to all available antibiotics are being seen more often. To control the spread of resistance, an understanding of how resistance arises and is spread among bacteria is needed. This requires information about how the genetic elements that mobilize them work. This project will study one of the most important of these elements.
Multidrug Recognition And Resistance In Staphylococcus Aureus
Funder
National Health and Medical Research Council
Funding Amount
$598,978.00
Summary
Strains of Staphylococcus aureus (Golden Staph), resistant to almost all available anti-staphylococcal agents, are responsible for serious infections among patients; in some hospitals such outbreaks reach epidemic proportions. Resistance has emerged to all classes of antimicrobial agents. We will increase our understanding of proteins that confer resistance by pumping multiple antimicrobials out of the cell to ultimately design more effective antibacterials able to bypass such drug pumps.
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
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.
Plasmid Specialisation Modules, Microbial Husbandry And Microbiome Resilience
Funder
National Health and Medical Research Council
Funding Amount
$645,005.00
Summary
The epidemiology of plasmids is chiefly determined by small genetic modules that control their entry to cells, their stability after entry, and their capacity to exclude other related plasmids. Understanding this is important for understanding transmission of antibiotic resistance. It is also essential for our newly proven approach to remove resistance plasmids from bacteria.
Molecular Mechanisms Of Low-level Vancomycin Resistance In Clinical Staphylococcus Aureus
Funder
National Health and Medical Research Council
Funding Amount
$437,916.00
Summary
The common bacteria Staphylococcus aureus causes many infections in humans, and is becoming more resistant to antibiotic treatments, especially in hospitals. This project will determine how this bacteria is developing resistance to some of our last available antibiotics. This will provide an important basis for detecting and preventing this antibiotic resistance problem in future.