NOD1 Sensing Of H. Pylori Peptidoglycan Promotes Cell Survival And Bacterial Persistence
Funder
National Health and Medical Research Council
Funding Amount
$792,492.00
Summary
The bacterium H. pylori lives in the stomach of half the world’s population and is a major cause of human disease, including peptic ulcers and stomach cancer. This project will investigate how H. pylori is able to manipulate the host immune system by modifying the composition of its outside layer (the cell wall). In so doing, H. pylori causes changes in cells of the stomach lining that allow the bacterium to persist, but that also may predispose the host to cancer.
Toxoplasma Gondii Infection Of Human Retinal Pigment Epithelium
Funder
National Health and Medical Research Council
Funding Amount
$460,668.00
Summary
Ocular toxoplasmosis is a vision-threatening parasitic eye infection that is common in Australia and worldwide. No treatment cures the disease. This work will characterize cellular and molecular events occuring in the eye during an infection, which is an important first step toward the development of more effective treatments for patients with the condition.
Host-pathogen Interactions In Clostridial Myonecrosis
Funder
National Health and Medical Research Council
Funding Amount
$577,573.00
Summary
We will analyse the interaction between the bacteria that cause gas gangrene, and the infected host, from both a host and pathogen perspective. We will examine how the host’s response to infection can be modulated to decrease the severity of disease and we will identify the biochemical processes that are essential for bacterial growth in the host, a necessary prerequisite for disease. Outcomes will be a better understanding of the mechanisms of disease causation and improved disease control.
Combating Infectious Diseases By Harnessing Macrophage Functions
Funder
National Health and Medical Research Council
Funding Amount
$688,152.00
Summary
Infectious diseases present a persistent global health threat. For patients with life-threatening diseases caused by bacterial pathogens, antibiotics provide the last resort. Antibiotic resistance, even for newly developed antibiotics, is widespread within the bacterial community. New strategies are urgently needed to combat most bacterial infections. This proposal will investigate a new strategy to train and boost our immune systems to combat infectious diseases.
Nasal Epithelium As A Portal Of Entry For Burkholderia Pseudomallei, With Special Reference To Neurological Melioidosis
Funder
National Health and Medical Research Council
Funding Amount
$536,419.00
Summary
Melioidosis is a potentially fatal disease of manly tropical Australia and SE Asia and an emerging disease worldwide. It disproportionately affects indigenous Australians. It is caused by a bacterium found in soil and water and infection may be by inhalation in the rainy season. One manifestation of melioidosis is neurological symptoms. This project seeks to establish sites and pathways of infection resulting from inhalation, including the pathway from nasal mucosa to brain.
Inhibition Of Haemostasis As A Novel Host-directed Therapy For Tuberculosis
Funder
National Health and Medical Research Council
Funding Amount
$528,471.00
Summary
Mycobacterium tuberculosis-induced vasculopathy is an important cause of stroke worldwide, and stroke is a common (~20%) complication of tuberculous meningitis, the most dangerous presentation of tuberculosis. Blood clotting may also speed the growth tuberculosis in the body further worsening the situation. We will use zebrafish find out if clotting can be targeted to slow the growth of mycobacteria and then translate our findings to a mouse model of pulmonary tuberculosis.
Role Of Plasmepsin V And PTEX Complex In Plasmodium Liver Infection
Funder
National Health and Medical Research Council
Funding Amount
$848,408.00
Summary
Plasmepsin V and PTEX are essential proteins for malaria parasites to grow inside red blood cells. These proteins control the export of parasite proteins into red cells, causing disease. Before red blood cells are infected, parasites invade liver cells. Plasmepsin V and PTEX are expressed during liver infection but their function is currently unknown. We hypothesise that they allow parasites to export proteins into liver cells in order to survive and, thus, are antimalarial drug targets.
Genes Of Mycobacterium Tuberculosis Essential For Latent Tuberculosis Infection
Funder
National Health and Medical Research Council
Funding Amount
$590,103.00
Summary
One third of the worlds population is latently infected with M. tuberculosis, the bacteria which causes TB. We have identified key genes in M. tuberculosis that enable the bacterium to shut-down and become latent. This project will investigate these genes, identify their role and yield vital information for a new paradigm of drug and vaccine development. Improved vaccines and drugs which can target and inhibit latency would be of enormous benefit to the global community.
Characterising The Role Of IL-37 In The Development Of H. Pylori Infection.
Funder
National Health and Medical Research Council
Funding Amount
$641,992.00
Summary
H. pylori infects more than 50% of the worlds population and is the causative agent of gastric cancer, the second leading cause of cancer-related deaths worldwide. Infection with H. pylori occurs during early childhood and persists within the host for life, causing immune suppression and therefore preventing clearance of the infection from the individual. We will examine a newly identified mechanism of H. pylori-induced immune suppression in humans in an attempt to provide novel treatments.
Novel Perspectives On The Function Of AB5 Toxin B Subunits
Funder
National Health and Medical Research Council
Funding Amount
$1,041,896.00
Summary
AB5 toxins are important virulence factors of pathogenic bacteria. They comprise pentameric B subunits that bind to target cell surfaces and catalytic A subunits that damage host cell functions. This proposal examines a new paradigm wherein the B subunits are significant contributors to cell damage. We will characterize the cytopathic properties of diverse B subunits, particularly those of emerging toxins. This will provide novel insights into pathogenesis and inform development of therapeutics.