Outer Membrane Proteins Of Leptospira; Role In Immunity And Pathogenesis
Funder
National Health and Medical Research Council
Funding Amount
$88,500.00
Summary
Leptospirosis is a significant cause of death in tropical regions of the world. Recent outbreaks in Nicaragua and Brazil are timely reminders of the seriousness of disease caused by the Leptospira bacteria. In these outbreaks >10% of people developing the disease did not recover. Spread of the disease does not occur from person to person, but rather from animal to human. Leptospira are shed from infected animals via the urine; human infection may occur through contact with infected urine or u ....Leptospirosis is a significant cause of death in tropical regions of the world. Recent outbreaks in Nicaragua and Brazil are timely reminders of the seriousness of disease caused by the Leptospira bacteria. In these outbreaks >10% of people developing the disease did not recover. Spread of the disease does not occur from person to person, but rather from animal to human. Leptospira are shed from infected animals via the urine; human infection may occur through contact with infected urine or urine contaminated materials. In Australia, leptospirosis is an occupational hazard with dairy farmers, pig handlers, banana pickers and abattoir workers being those most at risk. A recent and alarming development is the emergence of new risk groups associated with certain leisure activities. For example, in the USA three triathletes died from leptospirosis and it was subsequently determined that the source of infection was contaminated swimming water. This project will investigate aspects of the development of disease and immunity during infection by Leptospira. This will be achieved by analysing the set of proteins located on the surface of the bacterium. These proteins play a key role in the development of disease. Using state of the art technology, each of the proteins will be purified and identified. This will enable experiments that will enhance our understanding of the development of disease at a molecular level.Read moreRead less
Influenza A Virus PB1-F2 Protein: A Putative Virulence Factor And Initiator Of Inflammation
Funder
National Health and Medical Research Council
Funding Amount
$474,718.00
Summary
Influenza virus produces a protein of undefined function called PB1-F2. Infection of mice with virus expressing PB1-F2 from virulent strains causes severe lung inflammation, while PB1-F2 from milder seasonal viruses does not. We will examine how PB1-F2 influences virulence of human influenza in the ferret, which exhibits the same illness as humans. This work will help understand the disease severity of newly evolved influenza viruses of humans and the role of PB1-F2 in mediating this.
Plasmids are extra mini-chromosomes that are present in many bacteria. They carry information that enables their hosts to survive and prosper in hostile environments. Plasmids are able to spread rapidly between bacteria, ensuring that the information they carry is rapidly disseminated throughout bacterial populations. Many plasmids carry information that increases the virulence of their host bacteria, because it adds to their repertoire of toxins and other adjuncts to invasiveness and colonisati ....Plasmids are extra mini-chromosomes that are present in many bacteria. They carry information that enables their hosts to survive and prosper in hostile environments. Plasmids are able to spread rapidly between bacteria, ensuring that the information they carry is rapidly disseminated throughout bacterial populations. Many plasmids carry information that increases the virulence of their host bacteria, because it adds to their repertoire of toxins and other adjuncts to invasiveness and colonisation, or enables them to survive in the presence of antibiotics. The emergence of multi-drug resistant bacteria and the rapid spread of the ability of bacteria to withstand most antibiotics available to date were mediated by plasmids. Plasmids also carry information that ensures their own survival. The consequence of this is that their bacterial hosts retain the plasmids, even when it is no longer beneficial to do so. For example, plasmids carrying information for resistance to antibiotics are not lost when their bacterial hosts grow in the absence of antibiotics. This is because plasmids have control systems, which ensure that on the one hand, replication of the plasmid keeps pace with the replication of its host, and on the other hand that the plasmid does not produce so many copies of itself that it overwhelms its host. This project examines the intricate regulatory system that a group of antibiotic-resistance plasmids uses to ensure that on average each plasmid molecule is replicated once per bacterial cell cycle. This system uses an antisense RNA, a tertiary RNA structure (pseudoknot) that acts as a translational switch, and a protein that interacts with different sequences on the plasmid to initiate replication. Detailed knowledge of the processes underlying this complex system is required if we are to develop new treatments that will lead to elimination of antibiotic-resistance and virulence-contributing plasmids from populations of pathogenic bacteria.Read moreRead less
Shigella Flexneri O Antigen Polysaccharides: Biosynthesis, Function In Virulence, And Interaction With IcsA/VirG
Funder
National Health and Medical Research Council
Funding Amount
$468,055.00
Summary
Shigella flexneri bacteria cause dysentery in millions of humans each year. The bacterium invades and replicates within the cells of the large intestine. Inside cells, S. flexneri is able to use the host cell's actin-based motility machinery to become motile within the cells, and this can be seen as F-actin comet tails extending from one end of the cell. Bacterial cell surface components residing in the outer membrane are important for the bacterium's ability to cause disease. Two of these compo ....Shigella flexneri bacteria cause dysentery in millions of humans each year. The bacterium invades and replicates within the cells of the large intestine. Inside cells, S. flexneri is able to use the host cell's actin-based motility machinery to become motile within the cells, and this can be seen as F-actin comet tails extending from one end of the cell. Bacterial cell surface components residing in the outer membrane are important for the bacterium's ability to cause disease. Two of these components (lipopolysaccharides (LPS) and their polysaccharide chains (O antigens), and IcsA-VirG protein)) are required for initiating actin polymerisation, and mutations affecting synthesis of these components reduce ability to cause disease. In previous studies we have found that O antigen and the synthesis and function of IcsA are interrelated. This project will study how the O antigens are synthesised and their chain length determined by the Wzz protein, and the Wzz structure in relation to its function will also be characterised. The role played by O antigen in intracellular motility will be studied to determine the mechanisms involved. Infection of cells and cell free extracts, antibodies, and an enzyme which specifically degrades the O antigen, will be used to study how O antigen affect the interaction between bacteria with human cell proteins. The relationship between O antigen and IcsA function will be studied using monoclonal antibodies raised to IcsA. The effect of LPS on the outer membrane protease IcsP will be investigated, as will the effect of LPS lipid A mutations on O antigen and virulence. These studies will contribute to a better understanding of the biosynthesis of an ubiquitous bacterial cell surface component (O antigen), its function as a virulence factor in bacterial interactions with host cells. This may lead to novel therapeutic strategies to prevent and control Shigellosis and other bacterial infections.Read moreRead less
Non-coding RNA Regulation Of Virulence In Enterohaemorrhagic E. Coli
Funder
National Health and Medical Research Council
Funding Amount
$389,313.00
Summary
Shiga toxins cause potentially fatal haemolytic uremic syndrome (HUS) and are transferred between bacterial pathogens by bacteriophage (bacterial viruses). We have recently found that the Shiga toxin encoding bacteriophage encodes an unusually large number of non-coding RNAs (RNA regulators of gene expression). This Project aims to understand how these RNA regulators benefit the Shiga toxin bacteriophage and use this knowledge to develop interventions that will prevent expression of the toxin.
Analysis And Regulation Of Leptospiral Virulence Factors.
Funder
National Health and Medical Research Council
Funding Amount
$630,465.00
Summary
Leptospirosis is a globally important infectious disease caused by Leptospira spp. This project aims to identify and characterise factors which play a role in disease development by knocking out genes, then investigating the impact on overall gene-protein expression in the mutant strain and its ability to cause disease. This will allow us to gain insights on mechanisms by which Leptospira spp. cause disease, leading to development of better methods of disease control and prevention.
Functional Genomic Analysis Of Exported DNA J Molecules In The Malaria Parasite Plasmodium Falciparum
Funder
National Health and Medical Research Council
Funding Amount
$529,698.00
Summary
Every day 3500 people die of malaria and more than 40% of the world s population is at risk. Malaria is one of the biggest scourges of mankind. This project aims to translate the available genomic data into functional insights using frontier technology to identify new intervention targets for P. falciparum infection. Developing novel targets against malaria is important from a humanitarian point of view, and also to safeguard Australia and its neighbouring regions against the social and economic ....Every day 3500 people die of malaria and more than 40% of the world s population is at risk. Malaria is one of the biggest scourges of mankind. This project aims to translate the available genomic data into functional insights using frontier technology to identify new intervention targets for P. falciparum infection. Developing novel targets against malaria is important from a humanitarian point of view, and also to safeguard Australia and its neighbouring regions against the social and economical implication of this disease. The malaria parasite seeks shelter from the host immune system by hiding in red blood cells, but at the same time it has to stay in contact with the blood environment. This is achieved by export of virulence factors onto the surface of malaria parasite-infected red blood cells, which are essential for the maintenance of malaria infection. Without these virulence factors the body's immune system can get rid of the malaria parasites by itself. For display on the surface the proteins have to pass several membranes and are transferred through the red blood cell. The whole transport and assembly process of the virulence factors into functional units is very complex and requires several helper and co-helper molecules. With the deciphering of the malarial genetic code it became obvious that the parasite displays an unusual large number of co-helper molecules, which are putatively exported into the red blood cell. We will generate transgenic parasites deficient in the expression of these exported co-helper proteins and assess their role on the pathogenesis of this debilitating infectious disease.Read moreRead less
Molecular Characterization Of E. Coli That Cause Urinary Tract Infection
Funder
National Health and Medical Research Council
Funding Amount
$387,114.00
Summary
The long term goals of the proposed research are to understand the processes by which uropathogenic Escherichia coli (UPEC) cause acute, recurrent and chronic infections and to identify new UPEC targets for therapeutic intervention. Urinary tract infections (UTI) are among the most common infectious diseases of humans and a major cause of morbidity and mortality. In the USA, UTI accounts for more than 1 million hospitalizations and $1.6 billion in medical expenditures each year. It is estimated ....The long term goals of the proposed research are to understand the processes by which uropathogenic Escherichia coli (UPEC) cause acute, recurrent and chronic infections and to identify new UPEC targets for therapeutic intervention. Urinary tract infections (UTI) are among the most common infectious diseases of humans and a major cause of morbidity and mortality. In the USA, UTI accounts for more than 1 million hospitalizations and $1.6 billion in medical expenditures each year. It is estimated that one in four women and one in twenty men will develop a UTI in their lifetime. The recurrence rate is high and no treatment other than antibiotics (often inefficient) is currently available. UPEC are the primary cause of UTI. In the last grant period, we focused on the molecular interplay that exists between different surface adhesins of UPEC. We succeeded in demonstrating functional interference between adhesins, motility organelles, aggregation factors and the capsule. We also discovered and partially characterized several novel UPEC adhesins that may play a role in pathogenesis. We established two novel technology sets: a mouse model of ascending UTI and the flow chamber biofilm model. In the next grant period, we will build on these concepts and experimental systems to gain a deeper understanding of the molecular mechanisms underlying UPEC virulence. We will characterize the role of several novel UPEC surface proteins in cell adhesin, aggregation, biofilm formation and colonization of the mouse urinary tract. We will employ an integrated approach that combines a powerful bacterial genetic system, a biofilm model, a mouse UTI model, microscopy and tissue culture systems to reveal the cellular, molecular, and structural basis for the pathogenesis of UTI. The work will facilitate the development of new vaccine approaches to prevent UTI, such as novel mechanisms for strain attenuation and vaccine design. The burden of UTI disease demands such research endeavours.Read moreRead less