Plasmids are additional mini-chromosomes carried by many bacteria. They carry information that enables their hosts to prosper in otherwise hostile environments. Plasmids spread rapidly between bacteria, efficiently disseminating plasmid-borne information throughout bacterial populations. Many plasmids carry information that increases the virulence of their host. The emergence of multi-drug resistant bacteria and the rapid spread of the information enabling bacteria to withstand most antibiotics ....Plasmids are additional mini-chromosomes carried by many bacteria. They carry information that enables their hosts to prosper in otherwise hostile environments. Plasmids spread rapidly between bacteria, efficiently disseminating plasmid-borne information throughout bacterial populations. Many plasmids carry information that increases the virulence of their host. The emergence of multi-drug resistant bacteria and the rapid spread of the information enabling bacteria to withstand most antibiotics available today, were mediated by plasmids. Plasmids also carry information that ensures their own survival. Consequently, their hosts retain the plasmids even when it is no longer beneficial for them to do so. For example, plasmids mediating resistance to antibiotics are not lost when bacterial hosts are grown in the absence of those antibiotics. That is because plasmids have control systems, which ensure both that replication of the plasmid keeps pace with that of its host, and that the plasmid does not produce so many copies of itself that it overwhelms its host or places it at a competitive disadvantage amongst other bacteria. This project examines the intricate regulatory system that enables two groups of antibiotic-resistance plasmids to ensure that, on average, each plasmid molecule is replicated once per bacterial cell cycle. This system uses a tertiary RNA structure as a molecular switch, an antisense RNA as the regulator of this switch, and a protein that interacts with DNA sequences on the plasmid and with a bacterial protein, to initiate replication. Information gained from studies of plasmid systems is essential to the development of treatments for the elimination of antibiotic-resistance and virulence-contributing plasmids from populations of pathogenic bacteria. Antisense RNAs are not only a powerful research tool, but are also being developed for therapeutic use. Understanding how these RNAs interact with their targets will increase their effectiveness.Read moreRead less
Regulatory Networks Controlling Virulence In Neisseria Gonorrhoeae And Neisseria Meningitidis.
Funder
National Health and Medical Research Council
Funding Amount
$147,500.00
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 under particular conditions, that is, their expression is regulated. To target efforts in the development of new vaccines and treatments, it is importan ....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 under particular conditions, that is, 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. 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 now known. From computer analysis of these data, it appears that these bacteria have few of the specific regulatory systems that are present in other bacteria. Because of the limited repertoire of regulatory systems still present in N. gonorrhoeae and N. meningitidis, it is feasible to mutate each one and determine which are involved in regulation of virulence determinants. We have made copies of every individual gene found in the DNA sequence of these bacteria and have attached each one individually to a glass slide to form a microarray measuring 18mm x 18mm. This microarray will allow us to monitor the expression of every gene in these bacteria in response to environmental signals. This information will be used to identify all the virulence genes controlled by each regulatory 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
Pathogenesis Of Infections With Yersinia Enterocolitica
Funder
National Health and Medical Research Council
Funding Amount
$339,634.00
Summary
Yersinia enterocolitica is a significant cause of food-poisoning, gastroenteritis and abdominal pain which may be mistaken for acute appendicitis. Y. enterocolitica is a heterogenous bacterial species only some strains of which are able to cause disease. Many of the disease-causing strains have readily identifiable virulence determinants which facilitate their detection in clinical microbiological laboratories. By contrast, other types, in particular the biotype 1A strains, lack these determinan ....Yersinia enterocolitica is a significant cause of food-poisoning, gastroenteritis and abdominal pain which may be mistaken for acute appendicitis. Y. enterocolitica is a heterogenous bacterial species only some strains of which are able to cause disease. Many of the disease-causing strains have readily identifiable virulence determinants which facilitate their detection in clinical microbiological laboratories. By contrast, other types, in particular the biotype 1A strains, lack these determinants, although many of them are significantly associated with disease. During the past few years, we have compared biotype 1A strains of Y. enterocolitica obtained from patients with those from non-clinical sources in a number of assays for virulence-associated properties. These studies have shown that clinical isolates differ from non-clinical ones in terms of their ability to (1) invade epithelial cells in vitro and intestinal absorptive cells in vivo, (2) escape from epithelial cells and macrophages they have invaded, (3) resist killing by macrophages, and (4) colonise the intestinal tracts of mice. The aim of the study is to identify the bacterial determinants responsible for these differences between clinical and non-clinical strains of Y. enterocolitica biotype 1A. This will be achieved by using genetic techniques to modify virulent strains of biotype 1A at random and then identify derivatives of these bacteria with altered virulence properties. We shall also use genetic techniques to identify genes that are specifically activated when the bacteria come into contact with animal cells and tissues. The results of this research will provide new insights into the virulence mechanisms of Y. enterocolitica and related bacteria, and will be used to develop diagnostic tests which will allow pathogenic strains to be distinguished from harmless ones.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
Novel Compounds For Use As Inhibitors Of Virulence Of Human Pathogens
Funder
National Health and Medical Research Council
Funding Amount
$220,500.00
Summary
There is growing concern over the emergence of multi-drug resistant strains of bacteria which are no longer treatable with the current generation of antibiotics. This highlights the urgent need for development of the next generation of therapeutic agents to supplement or replace the current antibiotics. Our research team has identified a class of compounds which are naturally produced by a marine alga that may be effective in the control of bacterial pathogens. These compounds work by interferin ....There is growing concern over the emergence of multi-drug resistant strains of bacteria which are no longer treatable with the current generation of antibiotics. This highlights the urgent need for development of the next generation of therapeutic agents to supplement or replace the current antibiotics. Our research team has identified a class of compounds which are naturally produced by a marine alga that may be effective in the control of bacterial pathogens. These compounds work by interfering with the way many pathogens regulate the production of virulence traits. Some bacteria are able to signal members of their population by the specific uptake and recognition, through a receptor protein, of chemical cues they secrete into the environment. Accumulation of these cues or signals triggers expression of the genes that code for the virulence traits. Moreover, one particular class of these signal response proteins has been identified in many pathogens and has been shown to regulate protease production and production of a protective extracellular slime layer called a capsule. If one or more of these traits can be blocked, then the virulence of the bacterium can be reduced. We have preliminary data which demonstrates that the algal compounds do in fact prevent the expression of virulence traits and thus should be useful as new agents for the treatment of disease. The causative agents of cholera and severe gatroenteritis, Vibrio cholerae and V. parahaemolyticus respectively, have one or the other of these virulence traits, but the pathogen Vibrio vulnificus has all three and therefore is an excellent model pathogen. We propose to explore the ability of the algal compounds to specifically shut down expression of virulence factors with a long term aim for the development of these compounds as novel antimicrobial therapies for the post-antibiotic era.Read moreRead less