Virulence Mechanisms In Hypervirulent Epidemic Strains Of Clostridium Difficile.
Funder
National Health and Medical Research Council
Funding Amount
$499,135.00
Summary
The bacterium Clostridium difficile is the major cause of nosocomial diarrhoea in many countries, including Australia. More virulent isolates have emerged since 2000, leading to increased incidence and severity of disease in many countries and resulting in epidemics. This project will make a major contribution to our understanding of how these bacteria cause disease and may help to prevent outbreaks of the hypervirulent strains in Australia by identifying potential new vaccine candidates.
The aim of this project is to provide a better understanding of the mechanisms underlying the development of gas gangrene, an often fatal disease of particular significance to elderly and diabetic patients, who are particularly susceptible following injury, or surgery, or in some cases when suffering from colon cancer. Although research has been carried out on this disease for many years prompt surgical removal of the infected tissue, often including amputation of a limb, is still commonly used ....The aim of this project is to provide a better understanding of the mechanisms underlying the development of gas gangrene, an often fatal disease of particular significance to elderly and diabetic patients, who are particularly susceptible following injury, or surgery, or in some cases when suffering from colon cancer. Although research has been carried out on this disease for many years prompt surgical removal of the infected tissue, often including amputation of a limb, is still commonly used to ensure the patient's survival. This project involves the study of the two bacteria that are the major causes of the disease. We aim to find out how the bacteria mediate the disease, in particular to determine which toxic factors produced by the bacteria are involved. The normal host response to a bacterial infection is a rapid influx of white blood cells to the infected tissue, which is part of the normal inflammatory response. These cells engulf and degrade the bacteria, clearing the infection. However, a major characteristic of gas gangrene pathology is that very few white blood cells infiltrate the infected tissue. We aim to determine why the host fails to mount an inflammatory response to this bacterial infection. We will achieve this objective by developing a better understanding of the role of the bacterial toxins in the development of this morbid disease. It is hoped the results from this study will enable the development of more effective therapeutic and prophylactic treatments for this disease and also provide a foundation for studies into the modulation of the host response by other bacterial species.Read moreRead less
Global Regulation Of Toxin Production In Clostridium Perfringens
Funder
National Health and Medical Research Council
Funding Amount
$389,860.00
Summary
This project involves an investigation of how the bacteria that cause an often fatal wound infection control the production of the toxic proteins that are essential elements of the disease process. In all pathogenic bacteria there are specific genes that encode the virulence factors that are involved in the disease. The expression of these genes is generally controlled by the products of other genes known as regulatory genes. The function of these regulatory networks is generally responsive to e ....This project involves an investigation of how the bacteria that cause an often fatal wound infection control the production of the toxic proteins that are essential elements of the disease process. In all pathogenic bacteria there are specific genes that encode the virulence factors that are involved in the disease. The expression of these genes is generally controlled by the products of other genes known as regulatory genes. The function of these regulatory networks is generally responsive to environmental stimuli. This project involves the detailed functional analysis of a regulatory network that was first identified in this laboratory and which controls the expression of extracellular toxins that have been implicated in gas gangrene. The overall objectives of the project are to develop a detailed understanding of the mechanisms involved in this regulatory process. Specifically, the project aims to determine the functional components of the regulatory proteins that interact with the environmental signal or which bind to the genes encoding the bacterial toxins, to determine the nature of the target sites to which the regulatory proteins bind, and to examine the hypothesis that there is another regulatory gene that is involved in this process. The project will make a major contribution to our knowledge of the complex interactions that occur between an invading bacterium and the host tissues. If we are to fully comprehend how bacteria cause disease then it is critical that we understand how bacteria control the production of the toxic products that are an integral part of the disease process.Read moreRead less
Two-component Regulatory Systems Involved In Toxin Production In Clostridium Perfringens
Funder
National Health and Medical Research Council
Funding Amount
$78,500.00
Summary
The bacterium studied in this project causes gas gangrene, a severe and often fatal infection of traumatic or surgical wounds. The project involves the detailed analysis of the process by which this bacterium controls the production of the toxic proteins that are required for disease to occur. The emphasis is to determine the mechanism by which this regulatory process is mediated. Research in this laboratory has identified two genes whose protein products are the key links in this regulatory net ....The bacterium studied in this project causes gas gangrene, a severe and often fatal infection of traumatic or surgical wounds. The project involves the detailed analysis of the process by which this bacterium controls the production of the toxic proteins that are required for disease to occur. The emphasis is to determine the mechanism by which this regulatory process is mediated. Research in this laboratory has identified two genes whose protein products are the key links in this regulatory network. The objectives of the project will be to determine which part of the regulatory protein interacts with the target toxin gene, to start to determine the structure of the regulatory protein so that the precise biochemical mechanism of action can be ascertained, to determine the components of the DNA target that are essential for binding activity, and to identify other genes that are involved in the regulation of both the toxin genes and other genes that may be implicated in the disease process. These studies will be facilitated by the availability of the complete genome sequence of this pathogenic bacterium. The project will make a major contribution to our knowledge of how bacteria that cause disease are able to control the production of the toxins that are critical to the disease process. If we are to learn how to more effectively control and treat bacterial infections then it is very important that we understand the complex regulatory networks that tell bacteria when to produce its disease-causing products.Read moreRead less