KILLING OF MYCOBACTERIUM TUBERCULOSIS IN MACROPHAGES VIA THE P2X7 RECEPTOR
Funder
National Health and Medical Research Council
Funding Amount
$226,320.00
Summary
Tuberculosis remains an enormous global health problem. Some 32% of the world population are infected, with over 1 million persons dying each year. The risk of an infected individual developing clinical disease ranges from 2-23% for their lifetime. We know that both environmental factors, such as declining socio-economic conditions, and genetic risk factors such as HLA type contribute to the likelihood of an individual developing disease, but current known factors are insufficient to fully accou ....Tuberculosis remains an enormous global health problem. Some 32% of the world population are infected, with over 1 million persons dying each year. The risk of an infected individual developing clinical disease ranges from 2-23% for their lifetime. We know that both environmental factors, such as declining socio-economic conditions, and genetic risk factors such as HLA type contribute to the likelihood of an individual developing disease, but current known factors are insufficient to fully account for the risk attributed to genetics. The aim of this project is to investigate another potential risk factor involved in the development of tuberculosis, that of P2X7 receptor function. A natural compound, ATP, when added to macrophages is able to kill tuberculosis organisms residing within the macrophage. This process occurs when ATP activates the P2X7 receptor. We have recently identified a mutation in the P2X7 receptor, which causes a loss of receptor function. Individuals who have this mutation are unable to respond to ATP and hence may be unable to kill tuberculosis. Our studies will determine if the mutation we have identified in the P2X7 receptor prevents or inhibits ATP mediated killing of mycobacteria. Furthermore we will determine the frequency of this mutation in TB patients and the general population to determine if this mutation in the P2X7 receptor is a risk factor for the development of tuberculosis disease.Read moreRead less
Analysis And Regulation Of Leptospiral Virulence Factors.
Funder
National Health and Medical Research Council
Funding Amount
$630,465.00
Summary
Leptospirosis is a globally important infectious disease caused by Leptospira spp. This project aims to identify and characterise factors which play a role in disease development by knocking out genes, then investigating the impact on overall gene-protein expression in the mutant strain and its ability to cause disease. This will allow us to gain insights on mechanisms by which Leptospira spp. cause disease, leading to development of better methods of disease control and prevention.
Regulatory Networks Controlling Virulence In Neisseria Gonorrhoeae And Neisseria Meningitidis.
Funder
National Health and Medical Research Council
Funding Amount
$147,500.00
Summary
Bacteria that cause disease produce substances called virulence determinants, often on their cell surface. These virulence determinants are either directly involved in allowing infection to take place, or cause the damage that we recognize as an infectious disease. Some virulence determinants are produced all the time, while others are only made under particular conditions, that is, their expression is regulated. To target efforts in the development of new vaccines and treatments, it is importan ....Bacteria that cause disease produce substances called virulence determinants, often on their cell surface. These virulence determinants are either directly involved in allowing infection to take place, or cause the damage that we recognize as an infectious disease. Some virulence determinants are produced all the time, while others are only made under particular conditions, that is, their expression is regulated. To target efforts in the development of new vaccines and treatments, it is important to identify all the virulence determinants produced by a particular bacterial species, but also to know which are regulated, and the environmental signals that determine their expression. Neisseria gonorrhoeae and Neisseria meningitidis are two important disease-causing bacteria that exclusively infect humans and cause gonorrhoea, and meningitis. The complete DNA sequence of both of these bacteria is now known. From computer analysis of these data, it appears that these bacteria have few of the specific regulatory systems that are present in other bacteria. Because of the limited repertoire of regulatory systems still present in N. gonorrhoeae and N. meningitidis, it is feasible to mutate each one and determine which are involved in regulation of virulence determinants. We have made copies of every individual gene found in the DNA sequence of these bacteria and have attached each one individually to a glass slide to form a microarray measuring 18mm x 18mm. This microarray will allow us to monitor the expression of every gene in these bacteria in response to environmental signals. This information will be used to identify all the virulence genes controlled by each regulatory system. Such an analysis has never been previously achieved for any bacterial species, because of the number and complexity of the regulatory systems usually present.Read moreRead less
Development Of Improved Preventative Therapeutic Strategies For The Control Of Infectious Disease
Funder
National Health and Medical Research Council
Funding Amount
$4,000,000.00
Summary
A major objective of this Australia Fellowship application is to provide a mechanism whereby, for the first time in my career, I can devote myself full-time to my program of research. This program addresses an issue of global significance, namely the control of bacterial infectious diseases. These continue to cause massive global morbidity and mortality and constitute a profound threat to human health, in spite of the availability of antimicrobial drugs for over 60 years. WHO estimates that bact ....A major objective of this Australia Fellowship application is to provide a mechanism whereby, for the first time in my career, I can devote myself full-time to my program of research. This program addresses an issue of global significance, namely the control of bacterial infectious diseases. These continue to cause massive global morbidity and mortality and constitute a profound threat to human health, in spite of the availability of antimicrobial drugs for over 60 years. WHO estimates that bacterial infections are responsible for >10 million deaths p.a., and the economic impact is inestimable. For most major pathogens, vaccines are either unavailable or have serious shortcomings. Resistance to commonly used antimicrobials is increasing at an alarming rate, and modern travel has assisted the rapid global dissemination of highly resistant and virulent clones. Morbidity and mortality are also predicted to increase as a consequence of human-induced environmental changes and the growing proportion of the population with increased susceptibility to infection. Effective management of bacterial infectious diseases in the 21st century will require a two-pronged approach involving the development of cheaper and more effective vaccines, as well as novel anti-infectives refractory to known resistance mechanisms. However, formulation of optimal therapeutic and preventative strategies demands a thorough understanding of the biology of disease, particularly the complex interactions between bacterial pathogens and their human hosts. I have also played a leadership role in establishing the Pneumococcal Vaccine Consortium, which has just submitted a co-ordinated suite of multicentre proposals to PATH Vaccine Solutions to fund final preclinical testing, GMP scale-up and Phase I-II-III trials of protein-based pneumococcal vaccines that we have developed. The PATH accelerated pneumococcal vaccine development program is of enormous potential significance, because there is now a very real probability of pneumococcal protein vaccines being fast-tracked into human trials. Our aim is to create a direct pipeline from antigen discovery in the collaborators’ laboratories into the clinic. If successful, these vaccines could save millions of lives. This will be of enormous satisfaction to me personally, as it was I who originally proposed and demonstrated “proof of principle” for the vaccine potential of pneumococcal proteins, and I have been advocating assessment of their protective efficacy in humans for over 20 years. Thus, receipt of an Australia Fellowship will undoubtedly further support the internationalisation of Australian medical research.Read moreRead less
Virulence And Oxidative Stress In Streptococcus Pneumoniae
Funder
National Health and Medical Research Council
Funding Amount
$110,125.00
Summary
Streptococcus pneumoniae is an important human pathogen that causes pneumonia, meningitis and bacteraemia as well as otitis media in young children. It is a cause of high morbidity and mortality around the world. S. pneumoniae grows by fermentative metabolism, a characteristic of anaerobic organisms, but it is able to adapt towards oxygen in the environment. This adaptive ability enables S. pneumoniae to live under conditions of high oxygen tension (eg. the upper respiratory tract) or under almo ....Streptococcus pneumoniae is an important human pathogen that causes pneumonia, meningitis and bacteraemia as well as otitis media in young children. It is a cause of high morbidity and mortality around the world. S. pneumoniae grows by fermentative metabolism, a characteristic of anaerobic organisms, but it is able to adapt towards oxygen in the environment. This adaptive ability enables S. pneumoniae to live under conditions of high oxygen tension (eg. the upper respiratory tract) or under almost anaerobic conditions (eg. the middle ear) in the human body. The emergence of antibiotic resistant pneumococci and limitations of current vaccines has led to increased interest in understanding the molecular mechanisms of pathogenesis of this bacterium. Of particular interest has been the pneumococcal surface antigen PsaA, which has been shown to be a protective immunogen in mice. It has also been shown that psaA mutants exhibit massively reduced virulence in mice in intranasal and intraperitoneal challenge models. Taken together, these data have led to the suggestion that PsaA might be an effective vaccine antigen or antimicrobial target. We postulate that PsaA is involved in the oxidative stress response and virulence under aerobic conditions and have devised a study to determine the procise role of this protein in disease caused by Streptococcus pneumoniae.Read moreRead less
Characterising The Role Of Streptokinase Polymorphism In Invasive Pathogenesis Of Streptococcus Pyogenes.
Funder
National Health and Medical Research Council
Funding Amount
$480,535.00
Summary
Invasive bacterial pathogens such as Streptococcus pyogenes, can hijack host proteins and use them to facilitate the disease process. S. pyogenes secrete streptokinase to activate a host protease (plasminogen) which is used by the bacterium to invade through host tissue. This project will characterise the molecular mechanisms involved in streptokinase mediated activation of plasminogen which will assist the generation of novel therapeutics to treat invasive diseases.
Mechanism Of Exacerbations In Cystic Fibrosis Lung Disease
Funder
National Health and Medical Research Council
Funding Amount
$254,876.00
Summary
Cystic Fibrosis lung disease is characterised by infeciton with a bug called Pseudomonas aeruginosa. Patients ultimately die in their mid-30's as a result of this infection, but lung decline is accelerated by episodes of exacerbation when patients cough up large volumes of mucky sputum. We are studying the casue of exacerbations by looking at bacterial behaviour and the response of the immune system. We will use this information to try and develop early warning signals and better treatments.
MOLECULAR ANALYSIS OF VIRULENCE FACTORS OF GROUP B STREPTOCOCCI
Funder
National Health and Medical Research Council
Funding Amount
$211,527.00
Summary
Streptococcus agalactiae, more commonly referred to as group B streptococcus (GBS), is the commonest cause of life-threatening infection (specifically bacteraemia, pneumonia and meningitis) in neonates. Mortality is high even in developed countries where antimicrobial therapy is readily available. In spite of the importance of GBS disease, the precise molecular mechanisms whereby the organism colonizes, invades and damages host tissues are poorly understood. The long term goal of this project is ....Streptococcus agalactiae, more commonly referred to as group B streptococcus (GBS), is the commonest cause of life-threatening infection (specifically bacteraemia, pneumonia and meningitis) in neonates. Mortality is high even in developed countries where antimicrobial therapy is readily available. In spite of the importance of GBS disease, the precise molecular mechanisms whereby the organism colonizes, invades and damages host tissues are poorly understood. The long term goal of this project is to gain a complete understanding of the pathogenesis of GBS disease and to apply this to development of improved preventative strategies. We propose to carry out a comprehensive molecular characterization of genes encoding putative GBS virulence determinants, with particular reference to those which encode the capacity to adhere to and invade host cells. GBS carrying defined mutations in these genes will be constructed and their virulence will be compared with that of the otherwise isogenic parental GBS. This will enable us to determine the precise contribution of each putative virulence factor to the pathogenesis of disease. Moreover, proteins shown to be important in this process will be tested for vaccine potential.Read moreRead less
Shigella Flexneri O Antigen Polysaccharides: Biosynthesis, Function In Virulence, And Interaction With IcsA/VirG
Funder
National Health and Medical Research Council
Funding Amount
$468,055.00
Summary
Shigella flexneri bacteria cause dysentery in millions of humans each year. The bacterium invades and replicates within the cells of the large intestine. Inside cells, S. flexneri is able to use the host cell's actin-based motility machinery to become motile within the cells, and this can be seen as F-actin comet tails extending from one end of the cell. Bacterial cell surface components residing in the outer membrane are important for the bacterium's ability to cause disease. Two of these compo ....Shigella flexneri bacteria cause dysentery in millions of humans each year. The bacterium invades and replicates within the cells of the large intestine. Inside cells, S. flexneri is able to use the host cell's actin-based motility machinery to become motile within the cells, and this can be seen as F-actin comet tails extending from one end of the cell. Bacterial cell surface components residing in the outer membrane are important for the bacterium's ability to cause disease. Two of these components (lipopolysaccharides (LPS) and their polysaccharide chains (O antigens), and IcsA-VirG protein)) are required for initiating actin polymerisation, and mutations affecting synthesis of these components reduce ability to cause disease. In previous studies we have found that O antigen and the synthesis and function of IcsA are interrelated. This project will study how the O antigens are synthesised and their chain length determined by the Wzz protein, and the Wzz structure in relation to its function will also be characterised. The role played by O antigen in intracellular motility will be studied to determine the mechanisms involved. Infection of cells and cell free extracts, antibodies, and an enzyme which specifically degrades the O antigen, will be used to study how O antigen affect the interaction between bacteria with human cell proteins. The relationship between O antigen and IcsA function will be studied using monoclonal antibodies raised to IcsA. The effect of LPS on the outer membrane protease IcsP will be investigated, as will the effect of LPS lipid A mutations on O antigen and virulence. These studies will contribute to a better understanding of the biosynthesis of an ubiquitous bacterial cell surface component (O antigen), its function as a virulence factor in bacterial interactions with host cells. This may lead to novel therapeutic strategies to prevent and control Shigellosis and other bacterial infections.Read moreRead less
Characterisation Of Enterohaemorrhagic Escherichia Coli Lacking Classical Virulence Markers
Funder
National Health and Medical Research Council
Funding Amount
$140,660.00
Summary
Some intestinal infections with the intestinal bacterium, E. coli, can result in severe, often fatal, kidney disease called the haemolytic uraemic syndrome. It is important for the diagnosis and treatment of this condition that the infections are detected swiftly. Current means of identifying this virulent form of E. coli are inadequate and do not account for all types of the bacteria that can cause severe disease. Children are particularly susceptible to life threatening infections with this ty ....Some intestinal infections with the intestinal bacterium, E. coli, can result in severe, often fatal, kidney disease called the haemolytic uraemic syndrome. It is important for the diagnosis and treatment of this condition that the infections are detected swiftly. Current means of identifying this virulent form of E. coli are inadequate and do not account for all types of the bacteria that can cause severe disease. Children are particularly susceptible to life threatening infections with this type of E.coli and usually acquire the infection by consuming contaminated food or water. This organism is currently a global food safety problem and the bacteria are especially prevalent in ground beef products and water or vegetables that have been contaminated with cattle faeces. In this study we aim to identify new bacterial genes and proteins that may be used to improve current means of detecting and diagnosing this kind of E.coli. A great deal is known about the way in which the classical strains of this virulent E .coli colonise the intestine however a small but significant group of these organisms do not carry known colonisation factors. We aim to identify bacterial proteins in these non-classical strains of E.coli which are needed for attachment of the bacteria to the host. Identifying how these bacteria interact with the host may help us to develop improved means of detecting and diagnosing this life-threatening infection.Read moreRead less