Plasmids are additional mini-chromosomes carried by many bacteria. They carry information that enables their hosts to prosper in otherwise hostile environments. Plasmids spread rapidly between bacteria, efficiently disseminating plasmid-borne information throughout bacterial populations. Many plasmids carry information that increases the virulence of their host. The emergence of multi-drug resistant bacteria and the rapid spread of the information enabling bacteria to withstand most antibiotics ....Plasmids are additional mini-chromosomes carried by many bacteria. They carry information that enables their hosts to prosper in otherwise hostile environments. Plasmids spread rapidly between bacteria, efficiently disseminating plasmid-borne information throughout bacterial populations. Many plasmids carry information that increases the virulence of their host. The emergence of multi-drug resistant bacteria and the rapid spread of the information enabling bacteria to withstand most antibiotics available today, were mediated by plasmids. Plasmids also carry information that ensures their own survival. Consequently, their hosts retain the plasmids even when it is no longer beneficial for them to do so. For example, plasmids mediating resistance to antibiotics are not lost when bacterial hosts are grown in the absence of those antibiotics. That is because plasmids have control systems, which ensure both that replication of the plasmid keeps pace with that of its host, and that the plasmid does not produce so many copies of itself that it overwhelms its host or places it at a competitive disadvantage amongst other bacteria. This project examines the intricate regulatory system that enables two groups of antibiotic-resistance plasmids to ensure that, on average, each plasmid molecule is replicated once per bacterial cell cycle. This system uses a tertiary RNA structure as a molecular switch, an antisense RNA as the regulator of this switch, and a protein that interacts with DNA sequences on the plasmid and with a bacterial protein, to initiate replication. Information gained from studies of plasmid systems is essential to the development of treatments for the elimination of antibiotic-resistance and virulence-contributing plasmids from populations of pathogenic bacteria. Antisense RNAs are not only a powerful research tool, but are also being developed for therapeutic use. Understanding how these RNAs interact with their targets will increase their effectiveness.Read moreRead less
Structural Studies Of Bacterial Pore-forming Protein Toxins
Funder
National Health and Medical Research Council
Funding Amount
$267,750.00
Summary
The general aim of this work is to investigate the three-dimensional structures of important target proteins using X-ray crystallography. Protein crystallography is the study of the three-dimensional shapes of proteins at near atomic resolution. In this method proteins are made to form crystals. X-ray beams are then shone on the crystals causing the X-rays to scatter in a pattern which is characteristic of the protein's three-dimensional shape. Knowledge of the structure of proteins is necessary ....The general aim of this work is to investigate the three-dimensional structures of important target proteins using X-ray crystallography. Protein crystallography is the study of the three-dimensional shapes of proteins at near atomic resolution. In this method proteins are made to form crystals. X-ray beams are then shone on the crystals causing the X-rays to scatter in a pattern which is characteristic of the protein's three-dimensional shape. Knowledge of the structure of proteins is necessary for the complete understanding of their biological activity and is also very useful for the rational design of new drugs that may alter their activity. Approximately, one third of the body's proteins are attached to membranes. However, relatively little is known about the three-dimensional structures of this important class of proteins. In this project the structures of proteins that form pores in membrane cell walls are being determined. Thses proteins are bacterial toxins and knowledge of their structure may prove useful in the design of new antibiotics.Read moreRead less
Characterisation Of HiaNm, A Novel Outer Membrane From Neisseria Meningitidis; Vaccine Potential And Functional Studies
Funder
National Health and Medical Research Council
Funding Amount
$356,685.00
Summary
Meningococcal meningitis is a devastating illness which mostly affects children under 5 years. The clinical presentation is of a rapidly progressing disease with high rates of morbidity and mortality. This disease is caused by a bacterium, Neisseria meningitidis (the meningococcus). Vaccines are available against serogroup A and C strains of N. meningitidis, but not for group B strains, which cause the majority of disease in industrialised countries. We have recently identified a gene (designate ....Meningococcal meningitis is a devastating illness which mostly affects children under 5 years. The clinical presentation is of a rapidly progressing disease with high rates of morbidity and mortality. This disease is caused by a bacterium, Neisseria meningitidis (the meningococcus). Vaccines are available against serogroup A and C strains of N. meningitidis, but not for group B strains, which cause the majority of disease in industrialised countries. We have recently identified a gene (designated hiaNm) which encodes a new protein which is located on the surface of the bacterium, in the outer membrane. There has been an enormous body of work done on the immunology, biochemistry and genetics of all components of the outer membrane of Neisseria meningitidis. Therefore the discovery of this novel protein provides an exciting opportunity to take a new direction in vaccine development. For an effective vaccine, the target molecule must be present in most strains; we have already shown that the hiaNm gene is present in all strains examined. In this proposal we describe a study of the vaccine potential and biological function of the hiaNm gene product HiaNm. We will express the protein at high levels, immunise mice, and produce antibodies against HiaNm to discover whether they can protect mice against meningococcal disease. At the completion of this set of experiments we will be in an excellent position to assess the potential for the further development of HiaNm as a component of a meningococcal vaccine.Read moreRead less
Characterisation Of A Newly-discovered, Virulence-associated, Protein Secretion System Of Enteropathogenic E. Coli
Funder
National Health and Medical Research Council
Funding Amount
$582,149.00
Summary
The cell walls of bacteria act as a barrier to the export of any proteins they produce. We recently discovered a protein secretion system, which diarrhoea-causing strains of E. coli require to cause disease. The aim of this study is to characterise this secretory system, and discover how it functions and what it secretes. The knowledge obtained from this research will shed new light on how E. coli causes disease and could reveal novel methods to treat and prevent infections with this bacterium.
Multidrug Resistance Regulatory Protein QacR From Staphylococcus Aureus
Funder
National Health and Medical Research Council
Funding Amount
$459,750.00
Summary
One of the most significant mechanisms of drug resistance is the export of antibiotics and other chemotherapeutic drugs from the cell. Drug export systems are an important medical problem due to their frequent occurrence in bacteria and parasites which cause human disease, and in human cancer cells. Proteins which recognise and export a broad range of drugs from a cell are called multidrug efflux pumps. These multidrug efflux systems present a serious threat to patient care and to successful the ....One of the most significant mechanisms of drug resistance is the export of antibiotics and other chemotherapeutic drugs from the cell. Drug export systems are an important medical problem due to their frequent occurrence in bacteria and parasites which cause human disease, and in human cancer cells. Proteins which recognise and export a broad range of drugs from a cell are called multidrug efflux pumps. These multidrug efflux systems present a serious threat to patient care and to successful therapy, since the ability to produce a single protein simultaneously renders the cell or organism resistant to several different drugs. Strains of the bacterial pathogen Staphylococcus aureus or Golden Staph, which are endemic in hospitals world-wide, contain an example of such a multidrug exporter, the QacA multidrug efflux pump. QacA exports at least 30 different antimicrobial compounds, including antiseptics and disinfectants. Production of this protein is regulated by a sensor protein, QacR, which detects the presence of a number of these antimicrobial compounds. To understand how the QacR sensor protein can recognise such a wide variety of compounds, we will identify and structurally characterise the regions of the QacR multidrug regulatory protein which bind these compounds. Additionally, we will examine the means by which QacR regulates the production of the QacA pump protein. This project will provide fundamental knowledge that will not only help with understanding the important process of multidrug resistance but will also enable the rational design of more effective antibacterial compounds that either block or evade these multidrug efflux systems.Read moreRead less
Multidrug Resistance Regulatory Protein QacR From Staphylococcus Aureus
Funder
National Health and Medical Research Council
Funding Amount
$196,527.00
Summary
One of the most significant mechanisms of drug resistance is the export of antibiotics and other chemotherapeutic drugs from the cell. Drug export systems are an important medical problem due to their frequent occurrence in bacteria and parasites which cause human disease and in human cancer cells. Proteins which recognise and export a broad range of drugs from a cell are called multidrug efflux pumps. These multidrug efflux systems present a serious threat to patient care and to successful ther ....One of the most significant mechanisms of drug resistance is the export of antibiotics and other chemotherapeutic drugs from the cell. Drug export systems are an important medical problem due to their frequent occurrence in bacteria and parasites which cause human disease and in human cancer cells. Proteins which recognise and export a broad range of drugs from a cell are called multidrug efflux pumps. These multidrug efflux systems present a serious threat to patient care and to successful therapy, since the ability to produce a single protein simultaneously renders the cell or organism resistant to several different drugs. Strains of the bacterial pathogen Staphylococcus aureus or Golden Staph, which are endemic in hospitals world-wide, contain an example of such a multidrug exporter, the QacA multidrug efflux pump, which exports at least 30 different antimicrobial compounds, including antiseptics and disinfectants. Production of this protein is regulated by a sensor protein, QacR, which detects the presence of a number of these antimicrobial compounds. To understand how the QacR sensor protein can recognise such a wide variety of compounds, we will identify and structurally characterise the regions of the QacR multidrug regulatory protein which bind these compounds. Additionally, we will examine the means by which QacR regulates the production of the QacA pump protein. This project will provide fundamental knowledge that will not only help with understanding the important process of multidrug resistance but will also enable the rational design of more effective antibacterial compounds that either block or evade these multidrug efflux systems.Read moreRead less
Functional Genomic Analysis Of Multidrug Efflux In The Emerging Pathogen Acinetobacter Baumannii
Funder
National Health and Medical Research Council
Funding Amount
$550,226.00
Summary
Infections due to antimicrobial resistant organisms are a major public health issue. Acinetobacter baumannii is a bacterium that is increasingly being identified as a significant cause of serious antibiotic resistant infections, especially in the intensive care unit setting. Molecular studies in Acinetobacter to identify and characterise drug resistance proteins that pump antibiotics out of the cell will help understand the resistance capabilities and potential of this bacterium.