Molecular Basis For The Emergence Of Community Acquired Staphylococcus Aureus
Funder
National Health and Medical Research Council
Funding Amount
$427,518.00
Summary
Golden Staph is a major problem in our hospitals but serious Golden Staph infections are increasingly common in the community, among otherwise healthy people who have had no contact with hospitals. This project will find out how Golden Staph is evolving to become more likely to cause disease in the community. This knowledge can then be used to design new strategies for early detection, prevention and treatment.
Helicobacter Pylori VacA Toxin: Modulation Of Human Mitochondrial Function By A Bacterial Pathogen
Funder
National Health and Medical Research Council
Funding Amount
$508,003.00
Summary
This work will greatly further our understanding of how a bacterium, Helicobacter pylori, causes stomach ulcers and cancer. We will use cutting edge model systems to study the VacA toxin that is secreted from the bacteria and is targeted to human cells. We will examine where the toxin goes and how it affects our cells. It is expected that the improved understanding that will arise from this work will assist researchers to better devise drugs against this prevalent pathogen.
Host innate defence relies on the activation of several signalling pathways that regulate inflammation and cell death. Several important bacterial pathogens of humans inject virulence “effector” proteins into infected cells that interrupt host cell signalling pathways. We recently discovered a family of new effector proteins that directly degrade host proteins and block cell death. Here we will characterise this and other members of the family to understand their role during infection.
Manipulation Of Clathrin-mediated Trafficking By Coxiella
Funder
National Health and Medical Research Council
Funding Amount
$667,857.00
Summary
This research will uncover how Coxiella causes the serious infectious disease Q fever by commandeering human cells and replicating to high numbers within a specialised vacuole. We will investigate virulence factors of Coxiella, learning how and why they target an essential human vesicular trafficking process. Our innovative approach and unique expertise will elucidate interaction between this pathogen and the human cell, providing fundamental knowledge towards public health outcomes.
Defining Pathogenic Mechanisms Of Intracellular Bacteria
Funder
National Health and Medical Research Council
Funding Amount
$494,691.00
Summary
This study explores how the bacterium Coxiella burnetii causes the serious infectious disease Q fever. Coxiella is a potential biological weapon because it is very stable in the environment and few organisms are required to cause disease. Coxiella is able to commandeer human cells to replicate in a specialized vacuole but little is understood about how they do this. We will examine the virulence factors of Coxiella and investigate how they allow the bacteria to replicate inside human cells.
How The Intracellular Pathogen Coxiella Burnetii Manipulates Host Small GTPases To Facilitate Disease
Funder
National Health and Medical Research Council
Funding Amount
$534,510.00
Summary
This study explores how the bacterium Coxiella burnetii causes the serious infectious disease Q fever. Coxiella is a potential biological weapon because it is stable in the environment and few organisms are required to cause disease. Coxiella is able to manipulate human cells to replicate in a unique location within the cell but little is known about how they do this. Here we will study the host proteins that are important during infection and how Coxiella manipulates these factors to facilitate ....This study explores how the bacterium Coxiella burnetii causes the serious infectious disease Q fever. Coxiella is a potential biological weapon because it is stable in the environment and few organisms are required to cause disease. Coxiella is able to manipulate human cells to replicate in a unique location within the cell but little is known about how they do this. Here we will study the host proteins that are important during infection and how Coxiella manipulates these factors to facilitate intracellular replication.Read moreRead less
Functional Characterisation Of The SseK/NleB Family Of Type III Secreted Effectors In Salmonella And E. Coli
Funder
National Health and Medical Research Council
Funding Amount
$510,183.00
Summary
Salmonella and E. coli cause enteritis and diarrhoea in a large proportion of the world's population including Australia. Certain strains of Salmonella also cause a more serious disease called typhoid fever. Together, diseases caused by Salmonella and E. coli are a major cause of illness and death. In order to cause disease Salmonella and E. coli use a specialised apparatus that functions like a needle and syringe to inject Salmonella proteins into human cells. These proteins that are injected i ....Salmonella and E. coli cause enteritis and diarrhoea in a large proportion of the world's population including Australia. Certain strains of Salmonella also cause a more serious disease called typhoid fever. Together, diseases caused by Salmonella and E. coli are a major cause of illness and death. In order to cause disease Salmonella and E. coli use a specialised apparatus that functions like a needle and syringe to inject Salmonella proteins into human cells. These proteins that are injected into human cells actively reprogram human cells to benefit the disease causing bacteria. We have recently discovered a new family of injected proteins and we aim to determine how these new proteins reprogram human cells and what this contributes to diarrhoea and typhoid fever. This information may lead to the development of more effective treatments for these important diseases.Read moreRead less
Interactions Between Integrative Genomic Islands And Plasmids; Role In The Spread And Loss Of Antibiotic Resistance And Pathogenicity Determinants
Funder
National Health and Medical Research Council
Funding Amount
$776,465.00
Summary
Mobile elements that integrate into bacterial chromosomes at a specific site contribute pathogenicity and antibiotic resistance determinants to their bacterial host but only a few are able to move themselves into new hosts. Some plasmids and some elements can help certain others. In this project, genetic approaches will be used to investigate how plasmids and integrative elements help one another move into a new bacterium or compete with one another to stay in the same cell.