Assessment Of Alpha-galactosylceramide As A Novel Adjuvant For Pandemic Influenza: A Virua Vaccine
Funder
National Health and Medical Research Council
Funding Amount
$220,042.00
Summary
The occurrence of human infections with pathogenic avian H5N1 Influenza A viruses was the first documentation of these viruses demonstrating an ability to directly transmit from birds to humans. The virulent nature of these infections, and the fact that there is no pre-existing immunity to these viruses in the human population has raised the concern that these viruses may emerge to cause the next influenza pandemic. Vaccination is our most effective way of protecting against influenza infection, ....The occurrence of human infections with pathogenic avian H5N1 Influenza A viruses was the first documentation of these viruses demonstrating an ability to directly transmit from birds to humans. The virulent nature of these infections, and the fact that there is no pre-existing immunity to these viruses in the human population has raised the concern that these viruses may emerge to cause the next influenza pandemic. Vaccination is our most effective way of protecting against influenza infection, however there are no commercially available avian influenza vaccines available. Moreover, recent evidence suggests current vaccines strategies may be less than effective. This proposal aims to evaluate the efficacy of a novel vaccine strategy that promotes immune protection against a potential pandemic influenza strain.Read moreRead less
I am a viral immunologist studying the requirements for an effective host response to viral infection. I am also investigating the potential for the development of efficacious vaccines to protect against infection and ways of intervening in the disease pr
Role Of Plasmacytoid Dendritic Cells And Neutrophils In The Generation Of Antiviral Immunity
Funder
National Health and Medical Research Council
Funding Amount
$469,500.00
Summary
Work described in this application is important in understanding how two very different types of white blood cells, namely neutrophils and plasmacytoid dendritic cells (PDC), contribute to the generation of an effective immune response and control of virus growth. Both these cell types are activated in the earliest phase of the host response and are likely to play crucial roles in determining the nature of the later components of the response. We have recently shown that animals depleted of Gr-1 ....Work described in this application is important in understanding how two very different types of white blood cells, namely neutrophils and plasmacytoid dendritic cells (PDC), contribute to the generation of an effective immune response and control of virus growth. Both these cell types are activated in the earliest phase of the host response and are likely to play crucial roles in determining the nature of the later components of the response. We have recently shown that animals depleted of Gr-1+ cells, with monoclonal antibody (mAb) RB6-8C5, rapidly succumb to a poxvirus infection (mousepox) with 100% mortality. In contrast, mice treated with a control mAb clear the infection very effectively. Host responses essential for recovery from mousepox, including antiviral cytotoxic T lymphocyte (CTL) response and gamma interferon production, are severely diminished in mice treated with the Gr-1+ cell depleting mAb. Since the mAb can potentially deplete both neutrophils and PDC, this raises the important question of whether one or both of these cell types may be involved in the generation of cytokine and cell-mediated immune responses to viral infection. Although PDC and neutrophils themselves are not thought to present antigen to T cells, the elucidation of how they may control the generation of this major arm of the immune response will be novel and has important implications for vaccine design. Virtually nothing is known about how neutrophils or PDC influence viral antigen presentation by antigen presenting cells. Several murine models of viral infection, that in many ways mimic the diseases in humans, will be used to map the sequence of events initiated by PDC and neutrophils and which end in the clearance of virus from the host. Understanding these pathways and identifying the essential mediators and their interactions is critical in elucidating the role of the two cell types in the host response to virus infection.Read moreRead less
IgA Mediated Activation Of FcalphaRI, An Fc Receptor And A Leukocyte Ig-like Receptor.
Funder
National Health and Medical Research Council
Funding Amount
$535,500.00
Summary
Our immune system exists to seek and destroy infections caused by bacteria and viruses (pathogens) that would grow in us. B cells in the immune system make antibody tags which attach to pathogens marking them for elimination. A special type of antibody is IgA. IgA occurs in two forms, the first is found at mucosal sites, these are membranous passages in the body, such as the lung, the gut and the genital tract. These communicate with the outside and are the major route of pathogen entry into the ....Our immune system exists to seek and destroy infections caused by bacteria and viruses (pathogens) that would grow in us. B cells in the immune system make antibody tags which attach to pathogens marking them for elimination. A special type of antibody is IgA. IgA occurs in two forms, the first is found at mucosal sites, these are membranous passages in the body, such as the lung, the gut and the genital tract. These communicate with the outside and are the major route of pathogen entry into the body. Here IgA forms a rather passive, but pathogen specific, sticky barrier to prevent microbial pathogens attaching to these large surfaces. In an everyday analogy this IgA behaves somewhat like fly-paper. This subdued response is appropriate as we are constantly exposed to micro-organisms living in our gut, or breathed into our lungs, and our immune system would make us ill if it aggressively attacked our innocuous microbial neighbours. The second type of IgA is found in the blood where it attaches to pathogens that have breached the body's barriers. These IgA tags are actively sought by white blood cells whose function is to protect the body from infection by recognising and engulfing the tagged pathogens and destroying them with killer molecules, including bleach. The IgA-Fc receptor is the sensor on the surface of white blood cells which seeks the IgA tags as they attach to pathogens. In order to survive in this hostile environment some of our pathogens, such as Staphylococcus, have their own strategies to make themselves invisible to the immune system. These strategies include cutting up the IgA tags or blocking the sensors for IgA. In this project we will study how IgA tags turn on white blood cells to destroy pathogens. We will also be looking at two Staphylococcal proteins which block up the sensor for IgA tags. Finally we are endeavouring to understand how it is the mucosal type IgA does not activate the white cells nearly as much as the IgA from the blood.Read moreRead less
I work on the molecular mechanisms of innate immunity. Priorities of my work are the immune response to pathogens such as viruses and bacteria and to cancer.
Immune Regulation, Effector Function And Human Therapy
Funder
National Health and Medical Research Council
Funding Amount
$11,474,346.00
Summary
The immune system plays an important role in protecting the host from viral and bacterial infections, and inhibits cancer onset and progression. Immune processes proceed through specialised cells in conjunction with soluble factors such as inteferons and interleukins. These soluble factors can regulate the activities of immune cells, and inhibit the growth and survival of aberrant (virus infected, cancer) cells. Unfortunately, the immune system can sometimes lose specificity and attack the host, ....The immune system plays an important role in protecting the host from viral and bacterial infections, and inhibits cancer onset and progression. Immune processes proceed through specialised cells in conjunction with soluble factors such as inteferons and interleukins. These soluble factors can regulate the activities of immune cells, and inhibit the growth and survival of aberrant (virus infected, cancer) cells. Unfortunately, the immune system can sometimes lose specificity and attack the host, resulting in autoimmune diseases such as diabetes. This research team has played a vital role in characterising the specific activities of immune cells and the associated factors. Importantly, they are deciphering the intricate communication networks of these immune components and dissecting their modes of action. By understanding these complex processes, the team aims to harness the unique therapeutic properties of our own immune system and translate their findings into the clinic. The team is developing new immune-based therapies for use, either alone or in combination with existing chemotherapies to fight debilitating human diseases such as cancer and autoimmune disease.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100070
Funder
Australian Research Council
Funding Amount
$650,000.00
Summary
An advanced in vivo imaging facility. An advanced in vivo imaging facility: This project will establish an advanced In Vivo Imaging Facility (IVIF) for examining host-microbe interactions and associated immunological processes within the context of the numerous infectious disease models within the University of Melbourne and associated collaborators. The Zeiss LSM 7MP 2-photon imaging system will provide enhanced capacity to directly visualise cellular and molecular events in real time, with gre ....An advanced in vivo imaging facility. An advanced in vivo imaging facility: This project will establish an advanced In Vivo Imaging Facility (IVIF) for examining host-microbe interactions and associated immunological processes within the context of the numerous infectious disease models within the University of Melbourne and associated collaborators. The Zeiss LSM 7MP 2-photon imaging system will provide enhanced capacity to directly visualise cellular and molecular events in real time, with greater sensitivity and in a broader range of tissues and organs. This will provide the opportunity for novel insights into numerous immunological and host-microbe interactions.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100691
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Argonaute proteins and the mammalian antiviral response. Awarded the Nobel Prize for Medicine in 2006, RNA interference (RNAi) is a natural process that plants use to attack viruses. Humans possess all of the tools for RNAi, but whether it is used for antiviral defense is unknown. This project aims to uncover this immune process which will open new avenues to treat virus infections, from influenza to HIV.
Defining The Molecular Effectors And Regulators Of Anti-viral Immune Responses
Funder
National Health and Medical Research Council
Funding Amount
$447,750.00
Summary
In humans, cytomegalovirus infection can cause severe disease and may even be fatal in individuals with immature or compromised immune systems, such as newborns, AIDS patients, transplant recipients and people treated with chemotherapeutic drugs. The majority of healthy individuals however can clear the infection with minimal disease. The ability of cytomegalovirus to cause disease is increased in the absence of effective immune responses which would normally clear the virus before illness occur ....In humans, cytomegalovirus infection can cause severe disease and may even be fatal in individuals with immature or compromised immune systems, such as newborns, AIDS patients, transplant recipients and people treated with chemotherapeutic drugs. The majority of healthy individuals however can clear the infection with minimal disease. The ability of cytomegalovirus to cause disease is increased in the absence of effective immune responses which would normally clear the virus before illness occurs. Understanding the role of specific mediators of anti-viral immune responses is therefore of paramount importance in establishing the guidelines for the design of more effective anti-viral therapies. The mouse model of cytomegalovirus infection provides a unique system to dissect the roles of specific components of the immune response during the course of viral infection. Our previous studies have shown that anti-viral immune responses are complex and involve a multitude of players. The central aim of the work in the current proposal is to establish the precise contribution of specific molecular effectors and regulators of anti-viral immune responses and define their relevance during the different stages of viral infection. Hence, the results of these studies will be relevant to understanding the pathogenesis of cytomegalovirus infection in humans and more importantly will provide critical insights into the rational design of improved antiviral drugs and vaccines. Since the molecules and cells under investigation are also known to play a crucial role in immune responses that control tumour growth and transplant survival, the proposed studies will provide valuable insight towards the development of new therapies for pathologies associated not only with cytomegalovirus infection, but also with the conditions named above.Read moreRead less