MECHANISMS AND MARKERS OF TUBERCULOSIS TRANSMISSION WITHIN AUSTRALIA
Funder
National Health and Medical Research Council
Funding Amount
$799,978.00
Summary
Tuberculosis (TB) kills nearly 2 million people each year. The emergence of drug resistant TB in the Asia-Pacific region poses a particular threat to Australia, due to frequent population mixing and ongoing TB transmission that may facilitate its spread within vulnerable communities. The proposed study will develop advanced tools to monitor and limit TB transmission within Australia. It will also provide novel insight into the evolution of the global TB epidemic and key factors that sustain it.
Regulation From The Outside: Control Of Transport And Assembly Of Major Cell Wall Components In Mycobacteria
Funder
National Health and Medical Research Council
Funding Amount
$652,019.00
Summary
Tuberculosis (TB) kills nearly two million people each year while the causative bacterial species, Mycobacterium tuberculosis, infects one-third of the entire human population. An alarmingly high rate of TB exists in Australia's indigenous population. This proposal aims to identify and characterise essential processes that regulate synthesis of the outer coat of the bacterium, which are potential targets for new drugs for the treatment of this devastating disease.
Membrane TNF And Lymphotoxin Control Of Chemokine Induction And Inflammation In Tuberculosis
Funder
National Health and Medical Research Council
Funding Amount
$457,500.00
Summary
Tuberculosis (TB) remains an enormous problem worldwide. Most TB is not due to disease at the time of infection, but is a reactivation of dormant disease in people who have never completely eradicated the organisms. Macrophages containing dormant TB organisms are located in lesions called granulomas. Granulomas consist of TB-infected macrophages surrounded by T lymphocytes that actively contain the infection. T lymphocytes prevent the growth of TB organisms in the macrophages and so prevent wide ....Tuberculosis (TB) remains an enormous problem worldwide. Most TB is not due to disease at the time of infection, but is a reactivation of dormant disease in people who have never completely eradicated the organisms. Macrophages containing dormant TB organisms are located in lesions called granulomas. Granulomas consist of TB-infected macrophages surrounded by T lymphocytes that actively contain the infection. T lymphocytes prevent the growth of TB organisms in the macrophages and so prevent widespread infection that would cause illness in the host. Activated T lymphocytes that recognise TB-infected macrophages circulate in blood, are recruited from blood capillaries into the lung, migrate through the tissue and co-localise with infected macrophages. Soluble molecules (cytokines and chemokines) are known to provide the signals that direct cell migration and activation events. This study will investigate in detail cytokines and chemokines that are involved, the cells that produce then and where these cells are located in the lung. We recently showed that tumour necrosis factor (TNF), and the related cytokine lymphotoxin (LT), are essential for lymphocyte migration through the lung. These belong to a family of related molecules that signal through the same panel of receptors and regulate chemokine expression and inflammation. In this study we will use genetically manipulated mice that lack TNF. LT or other family members or that express only membrane-bound TNF to study how each affects production of different chemokines, chemokine receptors and other molecules. Since there are at least 50 known chemokines and 17 chemokine receptors we will use microarray technology to simultaneously screen changes in expression of several thousand genes and laser microdissection to study cells from different location in infected lungs. Understanding signals necessary to direct T cells into granulomas may facilitate new treatments to prevent TB reactivation disease.Read moreRead less
Investigating The Mechanisms Of Regulation Of Mycobacterial Cell Wall Biosynthesis
Funder
National Health and Medical Research Council
Funding Amount
$597,349.00
Summary
Tuberculosis (TB) kills around two million people each year while the causative bacterial species, Mycobacterium tuberculosis, infects one-third of the entire human population. An alarmingly high rate of TB exists in Australia's indigenous population. This proposal aims to identify and characterise essential processes involved in synthesis of the outer coat of the bacterium which are potential targets for new drugs for the treatment of this devastating disease.
Targeting Redox Homeostasis To Prevent Mycobacterium Tuberculosis Persistence
Funder
National Health and Medical Research Council
Funding Amount
$396,025.00
Summary
Tuberculosis is now the leading cause of death from infectious disease worldwide. This reflects the ability of its causative agent to persist, leading to failure of antibiotic treatment and development of drug resistance. In this project, we propose to overcome this by inhibiting a unique metabolic pathway that is activated when the pathogen enters its persistent state. We will use a cutting-edge combination of techniques to develop this pathway for next-generation therapies.
Human Genetic Susceptibility To Pulmonary Tuberculosis
Funder
National Health and Medical Research Council
Funding Amount
$760,432.00
Summary
Tuberculosis (TB) infects about a third of the world population, causing significant disease in 10% of infected individuals. We propose to undertake a genome-wide study to investigate human susceptibility to this devastating disease. Identifying novel gene associations from this study may explain why some people are more vulnerable to TB. Understanding these processes may lead to more effective treatments which is essential for the long term control of disease not only in China, but worldwide
RP105 Is A New Innate Immune Receptor For Mycobacterium Tuberculosis
Funder
National Health and Medical Research Council
Funding Amount
$525,583.00
Summary
Tuberculosis (TB) is a major global health threat that causes 1.7 million deaths every year. This study will characterise the interactions between the bacteria that cause TB and a new immune sensor. We found that this sensor is involved in controlling TB and this project will determine how it contributes to the immune defence against the infection. Such knowledge will help improve patient management and develop an effective vaccine and better treatments for this devastating disease.
Genetics And Biochemistry Of Biosynthesis Of The Cell Wall Of Mycobacteria
Funder
National Health and Medical Research Council
Funding Amount
$260,831.00
Summary
Mycobacteria commolnly cause human disease. The major killer in the group is Mycobacterium tuberculosis which annually causes millions of deaths from tuberculosis (TB) worldwide. Another pathogen from this group is Mycobacterium avium which often infects immunosuppressed people such as those with advanced HIV-AIDS. Mycobacteria have evolved a specialised wall that surrounds their cells which protects them from chemical attack from antibiotics and helps them to establish infections. The major ant ....Mycobacteria commolnly cause human disease. The major killer in the group is Mycobacterium tuberculosis which annually causes millions of deaths from tuberculosis (TB) worldwide. Another pathogen from this group is Mycobacterium avium which often infects immunosuppressed people such as those with advanced HIV-AIDS. Mycobacteria have evolved a specialised wall that surrounds their cells which protects them from chemical attack from antibiotics and helps them to establish infections. The major antibiotic used for TB stops cells from synthesising the protective layer thereby making them very vulnerable to human immune defences. Unfortunately, resistance to this antibiotic is common and new antibiotics are needed to treat mycobacterial infections. We are studying how mycobacteria make the cell wall and are looking for key steps where new drugs might be able to inhibit the process. Our approach is to inactivate genes in the mycobacteria that make the enzymes which control cell wall synthesis. The gene inactivation results in crippled mycobacteria that are unable to make proper cell walls. We analyse the cell wall changes that gene inactivation cause studying the chemical composition of the cell. This helps to identify the steps in cell wall biosynthesis and each step becomes a potential target for new drugs. Each of the weaken mycobacteria can be tested to see how well they can resist antibiotics and to see if they can survive host defences. In this way we can identify which components of the cell wall are critical for them to establish infections and resist antibiotic treatments. Enzymes that participate in the synthesis of such components are prime targets for us to concentrate on to design new antibiotics.Read moreRead less
Innate Immune Signalling In Mycobacterium Tuberculosis Infection
Funder
National Health and Medical Research Council
Funding Amount
$562,857.00
Summary
Tuberculosis (TB) is a major global health threat that causes 1.5 million deaths every year. This study will characterise a new molecular control mechanism that optimises the immune response to the bacteria that cause TB and determine how it contributes to controlling the infection. Such knowledge is essential to help improve patient management and develop better treatments for this devastating disease.