The Regulation Of IgE Antibody Production By Antigen-specific B Cells
Funder
National Health and Medical Research Council
Funding Amount
$454,105.00
Summary
Asthma and other allergies are caused by the inappropriate production of IgE antibodies by the immune system. IgE is not produced in response to most infections but the controls that normally prevent IgE production are unknown. We have identified two separate molecules that prevent IgE production during immune responses. In this proposal we aim to investigate how these controls work. This information may help to devise strategies for controlling IgE production and therefore allergic disease.
Environmental Regulation Of Virulence In Attaching And Effacing Enterobacteria
Funder
National Health and Medical Research Council
Funding Amount
$569,063.00
Summary
Disease-causing bacteria must respond to the extreme conditions, such as acid and bile, which they encounter in their hosts. They achieve this by sensing their environment and activating genes that enhance their survival and ability to cause disease. In this project we will define the mechanisms by which these sensing and response pathways occur, using E. coli as a model. The information obtained from this research should lead to new strategies to treat and prevent bacterial infections.
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.
QacA-mediated Multidrug Resistance And Export In Staphylococcus Aureus
Funder
National Health and Medical Research Council
Funding Amount
$497,250.00
Summary
Strains of the pathogenic bacterium Staphylococcus aureus (Golden Staph) which are resistant to almost all available anti-staphylococcal agents are responsible for serious infections among hospitalised patients; in some hospitals such outbreaks reach epidemic proportions. In these bacteria, resistance has emerged to all classes of antimicrobial agents, including antibiotics and antiseptics-disinfectants commonly used in the hospital environment, largely due to the acquisition of resistance deter ....Strains of the pathogenic bacterium Staphylococcus aureus (Golden Staph) which are resistant to almost all available anti-staphylococcal agents are responsible for serious infections among hospitalised patients; in some hospitals such outbreaks reach epidemic proportions. In these bacteria, resistance has emerged to all classes of antimicrobial agents, including antibiotics and antiseptics-disinfectants commonly used in the hospital environment, largely due to the acquisition of resistance determinants. These determinants encode for proteins which provide the bacterial cell with a range of different biochemical mechanisms to evade antibiotic chemotherapy. Specifically, this project seeks to increase our understanding of proteins which confer resistance by pumping a variety of structurally-dissimilar antimicrobials out of the bacterial cell. Proteins which recognise such a broad spectrum of compounds are called multidrug resistance proteins and present a disturbing clinical threat since the acquisition of one such system by a cell may simultaneously decrease its susceptibility to a number of antimicrobials. Similar multidrug pumps are widespread in nature and are credited for resistance to antibiotics and other chemotherapeutic drugs in many pathogenic organisms, such as the bacteria responsible for tuberculosis, and in human cancer cells. In this project, we aim to characterise the QacA multidrug resistance protein which is involved in pumping many different antimicrobial compounds from staphylococcal cells. We will identify the regions of the QacA multidrug resistance protein which bind the compounds and examine how the protein expels them to give resistance. These studies are a prerequisite for the design of more effective antibacterial compounds able to bypass or block these drug resistance pumps, and will also provide fundamental knowledge applicable to the problem of multidrug resistance in other infectious diseases and cancer.Read moreRead less
Virulence Strategies Of LEE-negative Shiga Toxigenic Escherichia Coli
Funder
National Health and Medical Research Council
Funding Amount
$230,246.00
Summary
Shiga toxigenic Escherichia coli (STEC) are a diverse group of pathogens that cause serious gastrointestinal disease in humans, which can lead to life-threatening complications. This project is aimed at understanding how these bacteria cause disease, and is focused on a subset of STEC strains that are highly virulent and produce a novel cytotoxin. A better understanding of the pathogenic mechanisms of STEC is essential for development of improved therapeutic and preventative strategies.
Outer Membrane Proteins Of Leptospira; Role In Immunity And Pathogenesis
Funder
National Health and Medical Research Council
Funding Amount
$88,500.00
Summary
Leptospirosis is a significant cause of death in tropical regions of the world. Recent outbreaks in Nicaragua and Brazil are timely reminders of the seriousness of disease caused by the Leptospira bacteria. In these outbreaks >10% of people developing the disease did not recover. Spread of the disease does not occur from person to person, but rather from animal to human. Leptospira are shed from infected animals via the urine; human infection may occur through contact with infected urine or u ....Leptospirosis is a significant cause of death in tropical regions of the world. Recent outbreaks in Nicaragua and Brazil are timely reminders of the seriousness of disease caused by the Leptospira bacteria. In these outbreaks >10% of people developing the disease did not recover. Spread of the disease does not occur from person to person, but rather from animal to human. Leptospira are shed from infected animals via the urine; human infection may occur through contact with infected urine or urine contaminated materials. In Australia, leptospirosis is an occupational hazard with dairy farmers, pig handlers, banana pickers and abattoir workers being those most at risk. A recent and alarming development is the emergence of new risk groups associated with certain leisure activities. For example, in the USA three triathletes died from leptospirosis and it was subsequently determined that the source of infection was contaminated swimming water. This project will investigate aspects of the development of disease and immunity during infection by Leptospira. This will be achieved by analysing the set of proteins located on the surface of the bacterium. These proteins play a key role in the development of disease. Using state of the art technology, each of the proteins will be purified and identified. This will enable experiments that will enhance our understanding of the development of disease at a molecular level.Read moreRead less
QacA-mediated Multidrug Resistance And Export In Staphylococcus Aureus
Funder
National Health and Medical Research Council
Funding Amount
$437,545.00
Summary
Strains of the pathogenic bacterium Staphylococcus aureus (Golden Staph) which are resistant to almost all available anti-staphylococcal agents are responsible for serious infections among hospitalised patients; in some hospitals such outbreaks reach epidemic proportions. In these bacteria, resistance has emerged to all classes of antimicrobial agents, including antibiotics and antiseptics-disinfectants commonly used in the hospital environment, largely due to the acquisition of resistance deter ....Strains of the pathogenic bacterium Staphylococcus aureus (Golden Staph) which are resistant to almost all available anti-staphylococcal agents are responsible for serious infections among hospitalised patients; in some hospitals such outbreaks reach epidemic proportions. In these bacteria, resistance has emerged to all classes of antimicrobial agents, including antibiotics and antiseptics-disinfectants commonly used in the hospital environment, largely due to the acquisition of resistance determinants. These determinants encode for proteins which provide the bacterial cell with a range of different biochemical mechanisms to evade antibiotic chemotherapy. Specifically, this project seeks to increase our understanding of proteins which confer resistance by pumping a variety of structurally-dissimilar antimicrobials out of the bacterial cell. Proteins which recognise such a broad spectrum of compounds are called multidrug resistance proteins and present a disturbing clinical threat since the acquisition of one such system by a cell may simultaneously decrease its susceptibility to a number of antimicrobials. Similar multidrug pumps are widespread in nature and are credited for resistance to antibiotics and other chemotherapeutic drugs in many pathogenic organisms, such as the bacteria responsible for tuberculosis, and in human cancer cells. In this project, we aim to characterise the QacA multidrug resistance protein which is involved in pumping many different antimicrobial compounds from staphylococcal cells. We will identify the regions of the QacA multidrug resistance protein which bind the compounds and examine how the protein expels them to give resistance. These studies are a prerequisite for the design of more effective antibacterial compounds able to bypass these drug resistance pumps, and will also provide fundamental knowledge applicable to the problem of multidrug resistance in other infectious diseases and cancer.Read moreRead less
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
Molecular and immunological approaches to managing Australia's seafood allergy epidemic. Seafood is an increasingly important cause of food allergy. Novel insight into the functions of why and how proteins from seafood develop to potent allergens will lead to the development of better diagnostics and therapeutics. This will assist patients to better manage their serious food allergy.
Plasmids are extra mini-chromosomes that are present in many bacteria. They carry information that enables their hosts to survive and prosper in hostile environments. Plasmids are able to spread rapidly between bacteria, ensuring that the information they carry is rapidly disseminated throughout bacterial populations. Many plasmids carry information that increases the virulence of their host bacteria, because it adds to their repertoire of toxins and other adjuncts to invasiveness and colonisati ....Plasmids are extra mini-chromosomes that are present in many bacteria. They carry information that enables their hosts to survive and prosper in hostile environments. Plasmids are able to spread rapidly between bacteria, ensuring that the information they carry is rapidly disseminated throughout bacterial populations. Many plasmids carry information that increases the virulence of their host bacteria, because it adds to their repertoire of toxins and other adjuncts to invasiveness and colonisation, or enables them to survive in the presence of antibiotics. The emergence of multi-drug resistant bacteria and the rapid spread of the ability of bacteria to withstand most antibiotics available to date were mediated by plasmids. Plasmids also carry information that ensures their own survival. The consequence of this is that their bacterial hosts retain the plasmids, even when it is no longer beneficial to do so. For example, plasmids carrying information for resistance to antibiotics are not lost when their bacterial hosts grow in the absence of antibiotics. This is because plasmids have control systems, which ensure that on the one hand, replication of the plasmid keeps pace with the replication of its host, and on the other hand that the plasmid does not produce so many copies of itself that it overwhelms its host. This project examines the intricate regulatory system that a group of antibiotic-resistance plasmids uses to ensure that on average each plasmid molecule is replicated once per bacterial cell cycle. This system uses an antisense RNA, a tertiary RNA structure (pseudoknot) that acts as a translational switch, and a protein that interacts with different sequences on the plasmid to initiate replication. Detailed knowledge of the processes underlying this complex system is required if we are to develop new treatments that will lead to elimination of antibiotic-resistance and virulence-contributing plasmids from populations of pathogenic bacteria.Read moreRead less