Self Adjuvanting CTL-Based Influenza Vaccines For Human Use
Funder
National Health and Medical Research Council
Funding Amount
$214,842.00
Summary
This project will generate novel vaccines that elicit cell-mediated immunity against influenza infection. The vaccines are totally synthetic and therefore not constrained by the limitations in manufacturing which currently confront egg-grown vaccines. These vaccines induce very strong immune responses because they target dendritic cells which are pivotal for induction of all immune responses. This targeting capability is due to a simple lipid molecule incorporated into the vaccine which is recog ....This project will generate novel vaccines that elicit cell-mediated immunity against influenza infection. The vaccines are totally synthetic and therefore not constrained by the limitations in manufacturing which currently confront egg-grown vaccines. These vaccines induce very strong immune responses because they target dendritic cells which are pivotal for induction of all immune responses. This targeting capability is due to a simple lipid molecule incorporated into the vaccine which is recognised by specific receptors on the surface of dendritic cells and also causes their maturation, a step which is essential for recognition by the immune system of potential pathogens. The technology to design and assemble these new vaccines is already.Read moreRead less
Mucosal Vaccine For Influenza On Inactivated Virus And Mannan
Funder
National Health and Medical Research Council
Funding Amount
$131,993.00
Summary
Influenza is a respiratory disease that causes significant morbidity and mortality worldwide. Current influenza vaccines are a preparation of three currently circulating inactivated influenza strains that induces an antibody response that can combat the virus and therefore infection. Despite the availability of a vaccine new approaches are needed to increase the activity, usage and distribution. To this end several approaches based on using additional agents to increase the immunogenicity and ne ....Influenza is a respiratory disease that causes significant morbidity and mortality worldwide. Current influenza vaccines are a preparation of three currently circulating inactivated influenza strains that induces an antibody response that can combat the virus and therefore infection. Despite the availability of a vaccine new approaches are needed to increase the activity, usage and distribution. To this end several approaches based on using additional agents to increase the immunogenicity and needle free delivery are being explored. We have a natural sugar based compound that can be used to increase the body's immunity to cancers and infectious agents such as bacteria and viruses. When these preparations are applied into the nostril of mice they generate antibody responses to the infectious agent in the lungs, gut, tears, saliva that can act as a barrier to infectious agents. We are incorporating an inactive flu virus with this natural sugar to investigate if it produces antibody that can protect mice and ferrets from the flu virus. This method will be first tried with the human flu virus and if successful will be tried with the bird flu virus. If the preparation can protect mice and ferrets from human or bird flu infection it could develop into a human vaccine against bird flu. Since it can be administered by the nose it will be widely used and can be used readily without qualified personnel in the case of a pandemic.Read moreRead less
Australia-Europe Malaria Research Cooperation - OzEMalaR
Funder
National Health and Medical Research Council
Funding Amount
$859,731.00
Summary
EVIMalaR is a European Virtual Institute for Malaria Research that combines 42 of the European Union’s leading malaria research groups plus 4 Africans, 1 Indian institution, and 1 Australian. EVIMalaR faculty will combine expertise to produce a Network of Excellence that enhances and harmonises experimental approaches through shared technological platforms, exchange visits, shared PhD students, shared resources such as databases, reagent banks and protocols across pathology, infection, immunolog ....EVIMalaR is a European Virtual Institute for Malaria Research that combines 42 of the European Union’s leading malaria research groups plus 4 Africans, 1 Indian institution, and 1 Australian. EVIMalaR faculty will combine expertise to produce a Network of Excellence that enhances and harmonises experimental approaches through shared technological platforms, exchange visits, shared PhD students, shared resources such as databases, reagent banks and protocols across pathology, infection, immunology and biochemistry. Malaria is a global problem with no single solution. A large, but sometimes disjointed, research community is addressing the problem, but more collaboration is vital. OzEMalaR will link 34 Australian labs with 47 European, African and Indian malaria researchers. Funding will enable exchange of modern technologies by supporting early career researchers (PhD and postdocs) from Australia to work and be trained in top European labs. European trainees will work and be trained by Australian malariologists using reciprocal EU supportRead moreRead less
This study will examine cellular immunity to the avian H5 influenza in people who have been previously infected with the currently circulating strains of H1 and H3 influenza, or in those who have been recently vaccinated with current influenza vaccines. This will give us an idea if there is any cross reactive immunity that may assist in developing immunity to pandemic strains of avian influenza, or may provide help in making antibody responses sooner to avian influenza vaccines once they are dev ....This study will examine cellular immunity to the avian H5 influenza in people who have been previously infected with the currently circulating strains of H1 and H3 influenza, or in those who have been recently vaccinated with current influenza vaccines. This will give us an idea if there is any cross reactive immunity that may assist in developing immunity to pandemic strains of avian influenza, or may provide help in making antibody responses sooner to avian influenza vaccines once they are developed. We will also establish assays to determine how immunogenic some new avian influenza vaccines are in mice.Read moreRead less
Gamma-ray Inactivated Influenza A Virus Vaccine For Cross-protective T Cell Immunity
Funder
National Health and Medical Research Council
Funding Amount
$239,963.00
Summary
Although there are new antiviral drugs that appear to be effective against influenza virus, the far more costeffective and efficient means to combat an influenza pandemic would be by vaccination. Current influenza vaccines employ virus preparations that are inactivated by chemical treatment. The inactivated vaccines, which function mostly by inducing antibody against the virus, have to be reformulated almost every year to take account of the changing virus because the antibodies recognize the vi ....Although there are new antiviral drugs that appear to be effective against influenza virus, the far more costeffective and efficient means to combat an influenza pandemic would be by vaccination. Current influenza vaccines employ virus preparations that are inactivated by chemical treatment. The inactivated vaccines, which function mostly by inducing antibody against the virus, have to be reformulated almost every year to take account of the changing virus because the antibodies recognize the viral surface which is prone to mutation. Accordingly, in terms of the threatening H5N1 avian influenza pandemic, it is not known if an inactivated vaccine based on the circulating H5N1 strain will be effective if the virus mutates to adapt to efficient growth and spread in the human population. In contrast to the antibody response against influenza virus, the cytotoxic T cell response is broadly crossreactive between heterologous influenza virus strains. Live virus infection efficiently induces cytotoxic T cell immunity which plays an important role in reducing disease severity and mortality following infection with a second, heterologous influenza virus, although infection per se is not prevented. Accordingly, vaccination strategies that elicit cytotoxic T cell memory should be given urgent consideration in the preparation against an influenza pandemic. We have found that the use of gamma-irradiation (in contrast to chemical treatment) for the preparation of inactivated experimental vaccines against influenza and other viruses does not destroy the ability of the vaccines to elicit cytotoxic T cell immunity. The gamma-ray inactivated vaccines conferred protection against lethal challenge with heterologous influenza virus strains in mice. This proposal is aimed at extending this novel finding to avian influenza viruses and to uncover the mechanisms involved in the cytotoxic T cell immunogenicity of gamma-ray inactivated vaccines.Read moreRead less
HIV infection of CD4+ lymphocytes leads to a high rate of reproduction of new virus. However, in the brain, HIV infection of the astrocytes does not yield high levels of new virus. HIV is genetically active in these astrocytes, producing high levels of the messenger molecules, the so-called mRNA, that code for the proteins required for a new virus particle. We have determined that these HIV mRNAs are specifically prevented from translating into protein. The mechanisms controlling protein transla ....HIV infection of CD4+ lymphocytes leads to a high rate of reproduction of new virus. However, in the brain, HIV infection of the astrocytes does not yield high levels of new virus. HIV is genetically active in these astrocytes, producing high levels of the messenger molecules, the so-called mRNA, that code for the proteins required for a new virus particle. We have determined that these HIV mRNAs are specifically prevented from translating into protein. The mechanisms controlling protein translation from RNA are relatively poorly understood compared with the other control points of cellular gene expression, such as the synthesis of mRNA. This project examines how astrocytes rapidly detect the presence of HIV mRNA and alter their translation machinery to halt the expression of HIV protein. This host defence mechanism involves two key components; the cellular component that identifies and responds to the viral mRNA, and the structural features of the HIV mRNA that enable the cell to detect its viral origin. We will study how translation of HIV proteins requires both HIV and cellular factors. We will determine the impact of both viral RNA elements and viral RNA binding proteins on the translation of viral and cellular proteins. The contribution of the type-1 interferons that are produced in response to viral infection will be studied for their role in augmenting the inhibition of HIV protein translation. Since HIV infected astrocytes significantly contribute to the onset of AIDS dementia, we will sees a strategy to lock HIV into a dormant state in the brain and thereby prevent the neurodegenerative disease associated with HIV. We will use the anti-viral mechanism blocking HIV protein translation in astrocytes to protect other cell populations, such as the CD4+ lymphocytes, from HIV infection. These studies will also give insights into the general mechanisms for translational control of gene expression in human cells.Read moreRead less