Structural Investigations Of Bacterial Evasion Of IgA Mucosal And Systemic Immunity
Funder
National Health and Medical Research Council
Funding Amount
$488,812.00
Summary
Nose, throat and skin infections are often caused by streptococcal and staphylococcal bacteria, known as Strep Throat and Golden Staph. Infections can be life-threatening in newborns, the elderly or individuals with weak immune systems. These bacteria make proteins bind and inactivate immune proteins. Our research examines the structural basis for bacterial interactions with a key immune system protein (an antibody called IgA) and may lead to new prevention and treatment strategies.
Crohn's disease is a severe, chronic inflammatory disease of the gut which affects up to 50,000 Australians. The majority of patients develop the disease in their twenties, with significant impact on their quality of life. Our preliminary work has identified a novel gene, which could potentially cause a critical reduction in the production of anti-bacterial proteins by cells in the small bowel. Exploring the function of this gene in relation to clinical outcome could lead to better treatment.
Some of the world's most important diseases, including important diseases of indigenous chilren and the hospitalised elderly are caused by bacteria that carry a surface coating called a capsule. It is not clear how this capsule is retained by bacteria. Resolution of this question could lead to the development of new disinfectants that will stop hospital-acquired infections, to new reagents that can be incoporated into medical devices where bacteria frequently grow, and new antibiotics.
This program will investigate the strategies used by pathogenic bacteria to cause human diseases. The research will focus on how bacteria initiate infections, how they invade, cause cell and tissue damage and respond to their human host. It will also examine how the host’s innate immune system interacts with these bacteria. The results will provide new insights into host-pathogen interactions and reveal new targets for the development of novel antibacterial drugs and vaccines.
The Molecular Basis Of Bacterial Infectious Diseases
Funder
National Health and Medical Research Council
Funding Amount
$16,230,996.00
Summary
Bacterial infectious diseases are a serious threat to human health, accounting for over 10 million deaths each year. This multidisciplinary collaborative team is investigating the complex interactions between major disease-causing bacteria and their human hosts, in order to determine how they cause disease. These studies will make a major contribution to fundamental knowledge in this field. This information is also essential for the development of cheaper and more effective vaccines, as well as ....Bacterial infectious diseases are a serious threat to human health, accounting for over 10 million deaths each year. This multidisciplinary collaborative team is investigating the complex interactions between major disease-causing bacteria and their human hosts, in order to determine how they cause disease. These studies will make a major contribution to fundamental knowledge in this field. This information is also essential for the development of cheaper and more effective vaccines, as well as novel drugs. These are urgently needed to reduce death and illness due to bacterial infectious diseases in the 21st century. 11Read moreRead less
Bacterial Inhibition Of Cell Signalling And Apoptosis During Gastrintestinal Infection
Funder
National Health and Medical Research Council
Funding Amount
$542,011.00
Summary
E. coli are a major cause of severe diarrhoeal disease. In order to establish infection, E. coli inhibits a host response where cells with bacteria stuck to them are ‘killed off’ and excreted as waste. This recent discovery illuminated an unknown role for cell death in the immune response during bacterial gastroenteritis. This project will study this phenomenon further to better understand the host immune response to infection and also other gut diseases such as inflammatory bowel disease.
Evolution And Function Of A Novel Lateral Flagellar Locus, Flag-2, In Pathogenic Escherichia Coli
Funder
National Health and Medical Research Council
Funding Amount
$465,158.00
Summary
This project will study how the bacteria that cause infant diarrhoea colonize the intestine and induce disease. We have identified a novel genetic region that allows E. coli to survive and persist in the intestine. Similar genes are also present in closely related organisms. This project will help us to undestand how new diseases evolve and emerge and may lead to the development of new vaccines to protect against infant diarrhoea.
Contribution Of Nuclear Targeting Of The NleE-OspZ Family Of Proteins To Escherichia Coli And Shigella Virulence
Funder
National Health and Medical Research Council
Funding Amount
$542,462.00
Summary
This project will study how the bacteria that cause infant diarrhoea colonize the intestine and induce disease. We have identified new bacterial proteins that allow E. coli to manipulate the normal host cell processes involved in killing an invading bacterium. Similar proteins are also present in the closely related organism, Shigella which causes dysentary. We will determine how these proteins act by finding the host cell proteins they bind.
The Development Of Novel, Biofilm-resistant Biomaterials
Funder
National Health and Medical Research Council
Funding Amount
$147,360.00
Summary
Almost all patients who are catheterised long term develop a bacterial infection. Most often, the infection is the result of colonisation of the catheter surface by bacteria. Bacterial colonisation of the surface of biomedical devices represents a significant health threat as such bacterial biofilms are extremely resistant to traditional antibiotic regimens. This project aims to develop novel materials that prevent bacterial colonisation on catheters and other biomedical related devices. Our tec ....Almost all patients who are catheterised long term develop a bacterial infection. Most often, the infection is the result of colonisation of the catheter surface by bacteria. Bacterial colonisation of the surface of biomedical devices represents a significant health threat as such bacterial biofilms are extremely resistant to traditional antibiotic regimens. This project aims to develop novel materials that prevent bacterial colonisation on catheters and other biomedical related devices. Our technology is based on compounds identified from a marine alga that prevent bacterial colonisation of its surface. Similarly, we have shown that these compounds, when coated onto test surfaces, prevent bacterial colonisation of a range of materials.Read moreRead less
Characterisation Of A Novel Type Of Promoter Controlling Expression Of Virulence Genes In Neisseria.
Funder
National Health and Medical Research Council
Funding Amount
$200,880.00
Summary
This project will investigate how two different types of bacteria control genes that are involved in determining their disease-causing ability. The expression of many bacterial genes is controlled by a sophisticated battery of regulatory systems that respond to individual, very specific, environmental signals. Such regulatory systems are capable of exerting very precise control over the level of gene expression, in response to the concentration of specific molecules in the immediate environment. ....This project will investigate how two different types of bacteria control genes that are involved in determining their disease-causing ability. The expression of many bacterial genes is controlled by a sophisticated battery of regulatory systems that respond to individual, very specific, environmental signals. Such regulatory systems are capable of exerting very precise control over the level of gene expression, in response to the concentration of specific molecules in the immediate environment. However, there is evidence to suggest that many important disease-causing bacteria are much less reliant on specific regulatory systems. Instead, these bacteria rely more heavily what have been termed global systems for the regulation of gene expression. Such systems typically respond to less specific signals, such as the growth rate of the bacterial cell, but nevertheless appear capable of very precise control. We have evidence for a previously uncharacterised type of global control system that appears to be widespread amongst bacteria. It is likely that many virulence genes in a variety of disease-causing bacteria will prove to be controlled by similar means. Therefore this project will not only provide an insight into how expression of these particular virulence determinants is regulated, but will yield data that may help in our understanding of precise global regulatory processes in other bacterial species of medical importance.Read moreRead less