Role Of Novel Mobile Elements In The Infiltration Of Antibiotic Resistance Genes Into Clinical Isolates.
Funder
National Health and Medical Research Council
Funding Amount
$421,650.00
Summary
Bacteria have a remarkable ability to capture and spread antibiotic resistance genes. This phenomenon is a particular problem in our hospitals and in the community as multi-drug resistant pathogenic organisms have been selected over time as a result of the use of antibitoics. Moreover the incidence of resistance appears to be on the increase. Once resistant strains appear they can greatly complicate the treatment of infections and the eradication of such pathogens from a hospital is both difficu ....Bacteria have a remarkable ability to capture and spread antibiotic resistance genes. This phenomenon is a particular problem in our hospitals and in the community as multi-drug resistant pathogenic organisms have been selected over time as a result of the use of antibitoics. Moreover the incidence of resistance appears to be on the increase. Once resistant strains appear they can greatly complicate the treatment of infections and the eradication of such pathogens from a hospital is both difficult and costly. We have been working on the problem of how antibiotic resistance genes are spread for a number of years and have identified a novel genetic element that can capture resistance genes by a process of site-specific recombination. This element, the integron, is common in mutli-drug resistant clinical isolates. To be captured by an integron, an antibiotic resistance gene has to be part of a mobile element known as a gene cassette. Although the application of antibiotics acts to amplify pathogens that are resistant and favours their persistance in hospitals, it is generally recognized that neither the gene cassette nor the drug resistance gene evolve in the hospital. Rather, these genes make their way into human pathogens from bacteria that normally reside in other environments, for example soil or water. In this project, we will investigate one route by which drug resistance genes and integrons might find their way into clinically relevant strains and what the sources of the resistance genes and gene cassettes might be. A greater understanding of these processes will help in developing strategies to limit the spread of drug resistant bacteria into and around hospitals.Read moreRead less
Molecular Genetics And Evolution Of Antibiotic Resistant Staphylococci
Funder
National Health and Medical Research Council
Funding Amount
$437,545.00
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. Hospital-acquired infections caused by Golden Staph are a major problem in Australia and globally. The problem is largely due to the pre ....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. Hospital-acquired infections caused by Golden Staph are a major problem in Australia and globally. The problem is largely due to the presence in hospitals of strains that have become resistant to most clinically-useful antibiotics and are therefore very difficult to eradicate. This research project will reveal detailed information about strains of Golden Staph that are currently prevalent in hospitals in Australia, USA, Europe, and South East Asia. It will also provide important insights into the mechanisms that enable this organism to become resistant so readily, and identify factors that promote the development of resistant strains. The results of this research project will lead to improved methods for the characterisation of clinical strains and the monitoring of antibiotic resistance. The findings will also be of relevance to other types of antibiotic resistant bacteria. Most importantly, the application of knowledge arising from these studies has potential to minimise the emergence of strains that are even more resistant, thereby extending the effectiveness of existing and future antibiotics. The design and implementation of strategies to limit the proliferation of resistant bacteria are essential if we are to avoid a scenario similar to that prior to the introduction of antibiotics, when serious infectious diseases were often untreatable.Read moreRead less
The rapid emergence and spread of antibiotic resistance in bacteria that cause infectious diseases is of major concern to public health authorities throughout the world. Many of the genes that are responsible for this resistance are carried on mobile genetic elements, which are discrete segments of genetic material that can move from one bacterium to another. These genetic elements are important vehicles for the transmission of virulence and antibiotic resistance genes in most bacteria. This pro ....The rapid emergence and spread of antibiotic resistance in bacteria that cause infectious diseases is of major concern to public health authorities throughout the world. Many of the genes that are responsible for this resistance are carried on mobile genetic elements, which are discrete segments of genetic material that can move from one bacterium to another. These genetic elements are important vehicles for the transmission of virulence and antibiotic resistance genes in most bacteria. This project is centred on bacteria that cause intestinal diseases and have the potential to transfer genetic information to other bacteria that are present in the intestine. The focus will be on elucidating the mechanism of action of an enzyme encoded by two of these genetic elements. This enzyme is responsible for the movement of these elements from one site in the bacterial genome to another, by a process that is being increasingly recognised as important in antibiotic-resistant disease-causing bacteria. The project will employ the latest tools of molecular biology to determine the function of this enzyme, and its associated genetic elements, at the detailed molecular level. These studies will contribute to our understanding of how these antibiotic resistance elements are transferred within and between different bacterial cells. In the longer term the project will contribute towards the development of improved methods for the control and treatment of infectious diseases.Read moreRead less