Dissemination And Virulence Properties Of The She Pathogenicity Island Of Shigella Flexneri.
Funder
National Health and Medical Research Council
Funding Amount
$110,625.00
Summary
Bacterial species belonging to the genus Shigella are responsible for intestinal diseases ranging from mild diarrhoea to life threatening bacillary dysentery. Such diseases kill over a million people, mainly infants in developing countries, every year and lead to serious morbidity and mortality even in industrialised countries with well developed health care systems. In many cases the virulence of Shigella species is augmented by large fragments of DNA, called pathogenicity islands, that carry g ....Bacterial species belonging to the genus Shigella are responsible for intestinal diseases ranging from mild diarrhoea to life threatening bacillary dysentery. Such diseases kill over a million people, mainly infants in developing countries, every year and lead to serious morbidity and mortality even in industrialised countries with well developed health care systems. In many cases the virulence of Shigella species is augmented by large fragments of DNA, called pathogenicity islands, that carry genes which contribute to the development of disease (pathogenesis) in humans. Pathogenicity islands are important genetic elements which appear to spread independantly throughout bacterial populations and therefore contribute to the emergence of new virulence traits in bacteria. Recently, we identified two related pathogenicity islands carried by both Shigella flexneri and other species of the genus Shigella. The two pathogenicity islands belong to a unique class of genetic elements found in Shigella species and virulent strains of the intestinal bacterium E. coli. Our current study is aimed at (1) understanding the mechanisms by which one of these islands, the she pathogenicity island, spreads from one bacterial strain to another to introduce disease-producing or virulence genes to new bacteria and (2) to study how the sigA virulence gene, carried on the she pathogenicity island, contributes to disease development in humans. We know that sigA encodes a protein toxin which contributes to the loss of fluid from the intestines of rabbits that have been experimentally infected with Shigella flexneri. We propose to study the structure and function of the SigA protein to determine how it interacts with tissues to produce a pathological state. Such studies will enhance our understanding of the process of disease development and contribute to the investigation and assessment of new strategies for therapeutic intervention.Read moreRead less
Construction And Immunogenic Evaluation Of Recombinant HBsAg-S Virus-like Particles Containing B And T Cell Epitopes Of
Funder
National Health and Medical Research Council
Funding Amount
$170,000.00
Summary
Helicobacter pylori is a significant human pathogen impacting on the health and well being of not only thousands of Australians, but also millions of people world-wide. However, the task of developing a vaccine against H. pylori remains important. Vaccination is the most effective mechanism to prevent disease associated with this infection, particularly gastric cancer, one of the most common causes of cancer death world-wide. However, current attempts to develop an effective vaccine for humans h ....Helicobacter pylori is a significant human pathogen impacting on the health and well being of not only thousands of Australians, but also millions of people world-wide. However, the task of developing a vaccine against H. pylori remains important. Vaccination is the most effective mechanism to prevent disease associated with this infection, particularly gastric cancer, one of the most common causes of cancer death world-wide. However, current attempts to develop an effective vaccine for humans has been limited by the non-availability of an effective and safe adjuvant. The aim is to construct a recombinant Virus-Like Particle which can be used as a safe and effective vaccine against Helicobacter pylori infections. We specifically aim to: · determine the most efficacious singular or combinatorial route-s of delivery of Virus-Like Particles (VLPs) which will induce the desired Th2 and B cell responses in mice · define the Th2 and B cell epitopes of H.pylori Kat A carboxyl terminus that can be used to construct chimeric HBsAg-S-Kat A VLPs · determine if the induction of desired immunological responses in mice are protective against wild type challengeRead moreRead less
The Roles Of Lipoprotein Multigene Families In Pathogenesis Of Mycoplasma Pneumoniae
Funder
National Health and Medical Research Council
Funding Amount
$257,036.00
Summary
Mycoplasma pneumoniae is one of the most common causes of community acquired pneumonia. Although it can usually be successfully treated with antibiotics, it can result in more severe diseases and can be difficult to diagnose accurately. It has been identified as a target for vaccine development, but this has been hampered by the limited understanding we have of how it causes disease. The attempts at vaccination that have been made have resulted in vaccines which induced more severe, rather than ....Mycoplasma pneumoniae is one of the most common causes of community acquired pneumonia. Although it can usually be successfully treated with antibiotics, it can result in more severe diseases and can be difficult to diagnose accurately. It has been identified as a target for vaccine development, but this has been hampered by the limited understanding we have of how it causes disease. The attempts at vaccination that have been made have resulted in vaccines which induced more severe, rather than less severe, disease. Investigations of several other related bacteria have shown that they are able to vary their surface proteins and thus may evade the immune system, permitting them to cause more prolonged disease. Better understanding how this occurs, and what this enables the bacteria to do, may assist in developing improved vaccine strategies. This project aims to investigate the six gene families in Mycoplasma pneumoniae which are known to encode surface proteins and establish how and why the bacteria switch from one gene to another during infection. In addition the capacity of bacteria expressing different versions of the six surface proteins to adhere to different tissues will be investigated. Once this is known, these mechanisms may be able to be specifically disrupted to prevent a strain of Mycoplasma pneumoniae from being able to establish prolonged infections. Such a strain might be a useful basis for an effective vaccine.Read moreRead less
Regulatory Networks Controlling Virulence In Neisseria Gonorrhoeae And Neisseria Meningitidis.
Funder
National Health and Medical Research Council
Funding Amount
$300,773.00
Summary
Bacteria that cause disease produce substances called virulence determinants, often on their cell surface. These virulence determinants are either directly involved in allowing infection to take place, or cause the damage that we recognize as an infectious disease. Some virulence determinants are produced all the time, while others are only made in particular conditions - their expression is regulated. To target efforts in the development of new vaccines and treatments, it is important to identi ....Bacteria that cause disease produce substances called virulence determinants, often on their cell surface. These virulence determinants are either directly involved in allowing infection to take place, or cause the damage that we recognize as an infectious disease. Some virulence determinants are produced all the time, while others are only made in particular conditions - their expression is regulated. To target efforts in the development of new vaccines and treatments, it is important to identify all the virulence determinants produced by a particular bacterial species, but also to know which are regulated, and the environmental signals that determine their expression. It can be just as important to know whether a virulence determinant is constantly expressed, and therefore represents an invariant target. Neisseria gonorrhoeae and Neisseria meningitidis are two important disease-causing bacteria that exclusively infect humans and cause gonorrhoea, and meningitis. The complete DNA sequence of both of these bacteria is currently being determined. From computer analysis of these data, it appears that these bacteria have few of the specific regulatory systems that are present in other bacteria. The availability of DNA sequencing data enables an alternative and much more systematic approach to the identification and study of the regulation of virulence determinants. Because of the limited repertoire of regulatory systems still present in N. gonorrhoeae and N. meningitidis, it is feasible to mutate each and determine which are involved in regulation of virulence determinants. We will also be able to identify genes regulated by each system, determine how regulation is achieved, and use this information to identify any presently unknown virulence genes controlled by the same system. Such an analysis has never been previously achieved for any bacterial species, because of the number and complexity of the regulatory systems usually present.Read moreRead less