Genome Wide Investigations Of Mycobacterium Tuberculosis To Reveal Processes Of Pathogenesis
Funder
National Health and Medical Research Council
Funding Amount
$396,341.00
Summary
Tuberculosis remains a global health burden of staggering proportions. Around 1 in 3 people are infected with Mycobacteria tuberculosis, the organism responsible for the disease, which kills 2 million people annually. The emergence of strains now resistant to almost all of our front line drugs has placed extra pressure on researchers who are attempting to develop new protective vaccines and the critical antibiotics required to eradicate the disease. Furthermore the current global HIV pandemic is ....Tuberculosis remains a global health burden of staggering proportions. Around 1 in 3 people are infected with Mycobacteria tuberculosis, the organism responsible for the disease, which kills 2 million people annually. The emergence of strains now resistant to almost all of our front line drugs has placed extra pressure on researchers who are attempting to develop new protective vaccines and the critical antibiotics required to eradicate the disease. Furthermore the current global HIV pandemic is making the situation far worse as HIV kills the very cells of the body that protect us from tuberculosis. This research project will fill the significant gaps in our knowledge of M. tuberculosis infection, specifically identify the genes of the organism which allow it to invade and spread throughout the body. M. tuberculosis infection consists of 3 characteristic stages, i.e. colonisation, spread and long term survival in specialised structures called granulomas. It is from these granulomas that the bacterium can emerge after long periods of inactivity to cause clinical tuberculosis. Using a mouse model of infection I will define the genes needed by the bacterium to survive at these 3 key stages of disease thereby providing for a better knowledge base from which to design new vaccine strategies and to create effective drugs.Read moreRead less
Once treatable infections are becoming deadly because bacteria are developing broad antibiotic resistance. New medicines are urgently needed. Microbes themselves are the richest known source of new antibiotics but finding the 'good bugs' is like finding a needle in a microbial haystack. This project will use state-of-the art science to screen a previously overlooked source of rich microbial biodiversity and find new antibiotics.
Potent Lipoglycopeptide Antibiotics Against C. Difficile
Funder
National Health and Medical Research Council
Funding Amount
$750,411.00
Summary
In some people C. difficile bacteria naturally reside in the gut. Other people accidentally ingest spores of the bacteria while they are patients in a hospital or nursing home. Sometimes, broad-spectrum antibiotics used to treat an infection also kill healthy gut bacteria. The gut then becomes overrun with C. difficile, causing diarrhoea and pain, and sometimes death. We will investigate the use of a new potent antibiotic, vancapticin, to kill C. difficle and prevent relapse of infection.
Role Of IS26 In Antibiotic Resistance Gene Recruitment, Dissemination And Expression
Funder
National Health and Medical Research Council
Funding Amount
$457,879.00
Summary
Antibiotic resistance is increasing, compromising the efficacy of front-line antibiotics. Untreatable infections due to bacteria that are resistant to all available antibiotics are being seen more often. To control the spread of resistance, an understanding of how resistance arises and is spread among bacteria is needed. This requires information about how the genetic elements that mobilize them work. This project will study one of the most important of these elements.
Determining The Bacterial Contributions To Tuberculosis And Identification Of Drug Targets
Funder
National Health and Medical Research Council
Funding Amount
$443,946.00
Summary
Serious issues of drug resistance have emerged in tuberculosis prevention and are placing enormous pressure on global health systems. We have identified an enzyme of M. tuberculosis that is essential for its survival. This project will develop potent inhibitory compounds for this enzyme. Further, we will identify new drug targets through a screen to specifically identify the genes of the organism essential for its survival in the body. This information will be used to develop new TB drugs.
Protein Glycan Interactions In Infectious Diseases.
Funder
National Health and Medical Research Council
Funding Amount
$9,182,220.00
Summary
Infectious diseases remain a serious threat to human health, accounting for over 10 million deaths each year. This is a broad-based collaborative proposal, building on our previous achievements. Its aim is to better understand the dynamic interactions between major disease-causing microbes and their human hosts, and to directly apply this new knowledge to the development of improved vaccines and novel treatment strategies. These are urgently needed to combat infectious diseases in the 21st centu ....Infectious diseases remain a serious threat to human health, accounting for over 10 million deaths each year. This is a broad-based collaborative proposal, building on our previous achievements. Its aim is to better understand the dynamic interactions between major disease-causing microbes and their human hosts, and to directly apply this new knowledge to the development of improved vaccines and novel treatment strategies. These are urgently needed to combat infectious diseases in the 21st century.Read moreRead less
Optimisation Of Salmonella Genotyping And Epidemiological Data Analysis For Detection And Investigation Of Outbreaks
Funder
National Health and Medical Research Council
Funding Amount
$508,051.00
Summary
Bacteria known as salmonella are the most important causes of food-borne diarrhoeal disease. They occasionally cause potentially fatal septicaemia, especially in young children and people with underlying disease. We estimate that more than 80,000 cases of salmonella infection occur in Australia, each year, at a cost to the community of $37 million. Salmonella are divided into more than 2000 different types, but one - called Typhimurium - causes about 40% of infections and a few others cause most ....Bacteria known as salmonella are the most important causes of food-borne diarrhoeal disease. They occasionally cause potentially fatal septicaemia, especially in young children and people with underlying disease. We estimate that more than 80,000 cases of salmonella infection occur in Australia, each year, at a cost to the community of $37 million. Salmonella are divided into more than 2000 different types, but one - called Typhimurium - causes about 40% of infections and a few others cause most of the rest. This means that is difficult to distinguish cases of salmonella infection that have originated from one source (an outbreak) from cases that have originated from another. Without this information, is it hard to track the source, which is usually inadequately cooked meat or chicken another food that has been contaminated with salmonella after preparation. There are several existing methods for fingerprinting salmonella, but they are quite slow or do not distinguish different strains well enough to identify outbreaks quickly. This means that sources of contaminated food are often not identified in time to prevent more cases occurring. We aim to develop a faster and more discriminatory system for fingerprinting salmonella, based on novel technology that can identify many small genetic sequences that occur in different combinations in different strains. As well, we will develop electronic scanning tools that will link the fingerprints of the salmonella strains with information about the people infected with them, such as the types of food and places where they have eaten, to identify patterns or clusters that indicate a common source. The more rapidly this can be done the sooner the source of contaminated food can be found and eliminated and additional cases can be prevented. This has important implications for public health - it will increase food safety and reduce illness and economic loss.Read moreRead less
The Team brings together a unique grouping of people with backgrounds in molecular biology, medical microbiology, microbiology, marine ecology and immunology to tackle a significant health problem infections caused by bacteria. Using a novel approach, based on understanding how marine organisms specifically interfere with bacterial colonisation, the Team over the past seven years has identified a group of compounds that represent a novel group of antibiotics. Publications and patenting by the Te ....The Team brings together a unique grouping of people with backgrounds in molecular biology, medical microbiology, microbiology, marine ecology and immunology to tackle a significant health problem infections caused by bacteria. Using a novel approach, based on understanding how marine organisms specifically interfere with bacterial colonisation, the Team over the past seven years has identified a group of compounds that represent a novel group of antibiotics. Publications and patenting by the Team has demonstrated that the Team is at the forefront of research in this area. The novel antibiotics work by preventing bacteria sticking to surfaces and by preventing the bacteria from releasing toxins. The studies will concentrate on those bacteria that produce infections in the lungs (acute pneumonia), eyes (corneal infection), ear (middle ear disease), and abscesses.Read moreRead less
Developing New Therapies To Combat Tuberculosis Through Inhibition Of Vitamin B5 Metabolism In The Organism That Causes The Disease
Funder
National Health and Medical Research Council
Funding Amount
$311,760.00
Summary
The metabolism of vitamin B5 by pathogenic microorganisms has been recognised as an attractive target for developing drugs to combat various infectious diseases. The aim of the proposed work is to develop inhibitors of vitamin B5 metabolism in the bacterium that causes tuberculosis, using a powerful, multidisciplinary approach known as “fragment-based drug discovery”. This work is likely to yield potent inhibitors of the target bacterium, which could ultimately be used to treat tuberculosis.
A remarkable feature of bacterial cells though is that they can share genes. In so doing bacteria have the ability to acquire completely new characteristics. One example of this spreading of genes is the rapid dissemination of antibiotic resistance in pathogenic bacteria and the creation of multi-resistant superbugs. This process contributes greatly to the problem of hospiatal acquired infeections and results in many patient deaths annually. The other aspect of this sharing of genes is that in a ....A remarkable feature of bacterial cells though is that they can share genes. In so doing bacteria have the ability to acquire completely new characteristics. One example of this spreading of genes is the rapid dissemination of antibiotic resistance in pathogenic bacteria and the creation of multi-resistant superbugs. This process contributes greatly to the problem of hospiatal acquired infeections and results in many patient deaths annually. The other aspect of this sharing of genes is that in a population some cells will lack genes that others have. Some of these shared genes apart from antibiotic resistance can be a concern and include traits that make some bacteria pathogenic. Thus, two cells of the same species may have very different abilities to cause disease based on what additional genes they carry. Genomics is becoming one of the great scientific revolutions of the 21st century. Over 160 microbial genomes have been sequenced to date and from these studies we have also learned many important things including how some bacteria cause disease. Mobile DNA presents unique challenges to microbial genomics however since different individuals in a species can have many different genes. Thus genomics on even many individuals of a species may miss bacterial genes important to us. Here we will be applying genomics in a way that specifically targets those genes that are shared. This will have many benefits. We will be able to greatly increase our rate of discovery of medically important and other genes in way that is targeted. This approach will allow us to discover these shared genes in a way that is much more cost effective and faster than conventional whole cell genomics. It will also allow us to gain an understanding of how benign bacteria associated with humans may act as reservoirs for passing on harmful genes to bacteria that cause hospital infections.Read moreRead less