Vaccine Discovery For Human Mucosal Pathogens: Identifying Novel Vaccine Antigens That Are Stably Expressed During Host Interactions, Using Analysis Of Cell-contact And Phasevarion Mediated Expression Profiles
Funder
National Health and Medical Research Council
Funding Amount
$418,482.00
Summary
The control of several human pathogens depends on vaccine development due to antibiotic resistance and the devastating outcome of infection. This work aims to identify new vaccine targets for diseases including gonorrhoae, ear infections, meningitis and sepsis, based on proteins required for interaction with human cells. Proteins that are randomly switched on and off in these bacteria will also be studied to better understand disease and to rule out variably expressed genes from new vaccines.
Defining The Role Of Plasminogen Activation In Group A Streptococcal Invasive Disease
Funder
National Health and Medical Research Council
Funding Amount
$425,763.00
Summary
The "flesh-eating" bacteria group A streptococcus (GAS) causes life threatening invasive diseases such as necrotizing fasciitis and toxic shock syndrome (>600,000 cases and 163,000 deaths per year). For some types of GAS, plasminogen binding is essential for virulence.The aim of this work is to determine the extent to which plasminogen binding contributes to disease caused by highly virulent GAS. These studies will allow the development of new therapeutics and treatments.
Understanding Respiratory Infections To Improve Vaccines
Funder
National Health and Medical Research Council
Funding Amount
$268,497.00
Summary
Indigenous children have the highest rates of ear disease (OM) and associated hearing loss in the world. Papua New Guinea has the highest child mortality rates in the Western Pacific Region with 23% of deaths from pneumonia. OM and pneumonia vaccines can be improved through broadening their coverage of disease-causing pathogens. This study will identify the pathogens that currently cause OM in Indigenous children and pneumonia in PNG, and will measure the immune responses to these pathogens, in ....Indigenous children have the highest rates of ear disease (OM) and associated hearing loss in the world. Papua New Guinea has the highest child mortality rates in the Western Pacific Region with 23% of deaths from pneumonia. OM and pneumonia vaccines can be improved through broadening their coverage of disease-causing pathogens. This study will identify the pathogens that currently cause OM in Indigenous children and pneumonia in PNG, and will measure the immune responses to these pathogens, in order to develop improved vaccines.Read moreRead less
Structural Characterization Of A Novel AB5 Cytoxin - SubAB
Funder
National Health and Medical Research Council
Funding Amount
$210,760.00
Summary
The proposed research program, using a combinantion of structural biology and biophysical techniques will provide insight into the role of novel AB5 toxin from E. coli. This study will not only improve our fundamental understanding the mode of action of this toxin from this devastating pathogen, but could lead to the design of rational antimicrobials. The knowledge gained will increase Australian international research profile.
Impact Of Pneumococcal Vaccination And Environmental Factors On Pneumococcal Carriage And Disease.
Funder
National Health and Medical Research Council
Funding Amount
$455,872.00
Summary
Pneumonia is the leading killer of children <5y of age worldwide, and the pneumococcal bacterium is a common cause. Pneumococci are carried in the noses of healthy children. In this project we will determine 1) whether carriage can be used to monitor the impact of vaccination in resource-poor settings, 2) the effect of new vaccines on ear disease and transmission using infant mouse models and 3) if exposure to smoke effects the ability of pneumococci to cause disease and altered gene expressi ....Pneumonia is the leading killer of children <5y of age worldwide, and the pneumococcal bacterium is a common cause. Pneumococci are carried in the noses of healthy children. In this project we will determine 1) whether carriage can be used to monitor the impact of vaccination in resource-poor settings, 2) the effect of new vaccines on ear disease and transmission using infant mouse models and 3) if exposure to smoke effects the ability of pneumococci to cause disease and altered gene expression.Read moreRead less
Bacterial Pathogenomics: Whole-genome Sequencing To Investigate Infection Transmission, Pathogenesis And Antibiotic Resistance
Funder
National Health and Medical Research Council
Funding Amount
$475,946.00
Summary
As bacterial superbugs – resistant to multiple antibiotics – dominate the headlines, the pipeline for new antibiotics has all but dried up. High-throughput DNA sequencing heralds a golden opportunity for infectious disease research. By studying the entire collection of genes - the genome - of large numbers of multidrug resistant bacterial strains, we aim to better understand the genetic changes that govern the emergence and global spread of superbugs and translate these findings into the clinic.
Structural And Drug Discovery Studies Of Medically Important Protein Complexes
Funder
National Health and Medical Research Council
Funding Amount
$438,577.00
Summary
My research is focused on structural studies of medically important biological systems, where specific protein complex formation contributes to human illnesses. I use X-ray crystallography to visualize the whole complex at atomic resolution as well as to determine whether binding partners have undergone changes in shape upon complex formation. This structural information then helps me in drug design with goals to either disrupt or modulate the complex.
DNA sequencing allows us to see into the microbial world in fine detail. This enables us to investigate how bugs like bacteria cause infections and other diseases. In this fellowship, I will use DNA sequencing and analysis to investigate how bacterial infections are transmitted in hospitals and cities, how bacteria become resistant to the antibiotic drugs we use to treat infected people, and how the bacteria that live in our nose and throat contribute to development of asthma in young children.
My research is focused on understanding the aetiology of brain disorders. I am interested in the interaction of genetic and environmental factors in the development of these disorders. In particular, I will evaluate the validity of rodent models for schizophrenia and Alzheimer’s disease and investigate the therapeutic potential of the endocannabinoid system for both disorders and whether environmental enrichment (e.g. physical exercise) can have beneficial effects in these models.