Intrinsic Host Antiviral Activity Against Pathogenic Filoviruses
Funder
National Health and Medical Research Council
Funding Amount
$488,754.00
Summary
Bats are a major reservoir for deadly human viruses including Ebola and Marburg virus. In contrast to humans, bats can be infected with these viruses without showing clinical signs of disease. The reason why bats can co-exist with these viruses is unknown. This study will determine if a bat antiviral molecule contributes to limiting virus release compared to the human version that could reveal strategies to prevent and control these deadly viruses in humans.
Simplified Process Methods For Mass Vaccine Manufacture
Funder
National Health and Medical Research Council
Funding Amount
$158,393.00
Summary
The ideal way to protect against pandemic bird flu is to vaccinate all Australians as soon as possible after a dangerous strain starts to spread. Current manufacturing technology, which begins by making an infectious virus in chicken eggs, is unable to quickly deliver a mass vaccine to the entire Australian population. The existing process is slow, meaning that it will take several months before enough vaccine is available even to protect personnel working in essential services. The product from ....The ideal way to protect against pandemic bird flu is to vaccinate all Australians as soon as possible after a dangerous strain starts to spread. Current manufacturing technology, which begins by making an infectious virus in chicken eggs, is unable to quickly deliver a mass vaccine to the entire Australian population. The existing process is slow, meaning that it will take several months before enough vaccine is available even to protect personnel working in essential services. The product from chicken eggs is rendered safe after manufacture by breaking the virus structure. This make then break strategy reduces vaccine effectiveness meaning that even fewer individuals can be effectively protected per vaccine batch. Recent scientific progress has demonstrated that it is possible to make a non-infectious empty virus shell (a so-called virus-like particle) inside cells. This new product is able to provide full protection against a lethal influenza challenge, when administered nasally. However, these particles are very difficult to purify from contaminants that are packaged into the particles during manufacture in cells. These contaminants can cause an adverse reaction when the product is given to humans, meaning that although the product is effective it remains difficult to mass produce. A manufacturing problem remains. To overcome this manufacturing problem we will seek to assemble vaccine particles in vitro, building the particle from purified protein. Existing technology for manufacturing pure pharmaceutical protein is well-established and safe, and allows mass manufacture of contaminant-free product. This new make don't break manufacturing strategy is similar to that chosen by Merck to deliver a safe and effective vaccine, for cervical cancer, to mass market. Our key aim is to adapt this efficient manufacturing strategy to the manufacture of influenza vaccine. If successful, we will be able to immunize the Australian population using existing national biomanufacturing capability, within weeks of new strain identification, and without the requirement for high-level containment during manufacture.Read moreRead less
Construction And Immunogenic Evaluation Of Recombinant HBsAg-S Virus-like Particles Containing B And T Cell Epitopes Of
Funder
National Health and Medical Research Council
Funding Amount
$170,000.00
Summary
Helicobacter pylori is a significant human pathogen impacting on the health and well being of not only thousands of Australians, but also millions of people world-wide. However, the task of developing a vaccine against H. pylori remains important. Vaccination is the most effective mechanism to prevent disease associated with this infection, particularly gastric cancer, one of the most common causes of cancer death world-wide. However, current attempts to develop an effective vaccine for humans h ....Helicobacter pylori is a significant human pathogen impacting on the health and well being of not only thousands of Australians, but also millions of people world-wide. However, the task of developing a vaccine against H. pylori remains important. Vaccination is the most effective mechanism to prevent disease associated with this infection, particularly gastric cancer, one of the most common causes of cancer death world-wide. However, current attempts to develop an effective vaccine for humans has been limited by the non-availability of an effective and safe adjuvant. The aim is to construct a recombinant Virus-Like Particle which can be used as a safe and effective vaccine against Helicobacter pylori infections. We specifically aim to: · determine the most efficacious singular or combinatorial route-s of delivery of Virus-Like Particles (VLPs) which will induce the desired Th2 and B cell responses in mice · define the Th2 and B cell epitopes of H.pylori Kat A carboxyl terminus that can be used to construct chimeric HBsAg-S-Kat A VLPs · determine if the induction of desired immunological responses in mice are protective against wild type challengeRead moreRead less
Humoral And Neutralising Antibody Responses To Self-adjuvanting Recombinant HCV Virus Like Particles
Funder
National Health and Medical Research Council
Funding Amount
$118,796.00
Summary
Hepatitis C virus (HCV) infects 3% of the world's population and causes an estimated 476,000 deaths per year as a result of HCV associated end-stage liver disease. HCV is one of the most common notifiable infectious diseases in Australia with 16,000 new cases reported annually and a vaccine will reduce the number of new infections. The aim of this project is to develop HCV virus like particles (VLP's) that have the potential for future development of preventative vaccine against HCV.
Development Of Chimeric Hepatitis B Virus Like Particles As A Vaccine Delivery Platform For Multiple HIV-1 Epitopes
Funder
National Health and Medical Research Council
Funding Amount
$139,500.00
Summary
The small envelope protein of hepatitis B virus (HBsAg) can self-assemble into highly organised viruslike particles with about 150 HBsAg-proteins forming a virus-like particle (VLP). VLPs induce an effective immune response, mainly against the exposed major antigenic site, the hydrophilic ‘a’- determinant region. To create a novel HBsAg-specific vaccine vector, foreign epitopes were inserted into the major antigenic site allowing surface orientation of the inserted sequence. Pilot studies involv ....The small envelope protein of hepatitis B virus (HBsAg) can self-assemble into highly organised viruslike particles with about 150 HBsAg-proteins forming a virus-like particle (VLP). VLPs induce an effective immune response, mainly against the exposed major antigenic site, the hydrophilic ‘a’- determinant region. To create a novel HBsAg-specific vaccine vector, foreign epitopes were inserted into the major antigenic site allowing surface orientation of the inserted sequence. Pilot studies involving the vaccination of mice with VLPs containing an epitope derived from the AIDS-virus (human immunodeficiency virus 1, HIV-1) or various hepatitis C virus-specific epitopes resulted in high titre antibody responses. This project aims for the development of a multi-component vaccine targeting a non-structural HIV-1 protein and therefore, avoiding the selective pressure directed against the structural proteins. The non-structural HIV-1 tat-protein is a multi-functional protein with an extracellular mode to sensitise uninfected cells for HIV-1 infection and to reactivate HIV-1 from quiescently infected cells. The use of eight tat-sequences is sufficient to provide coverage against 99% of HIV-1 sequences. We will develop hybrid particles that are composed of different sets of chimeric HBsAg proteins each containing a distinct tat-epitope. With this application, we aim to develop hybrid particles for the delivery of the complete set of tat-epitopes. The hybrid particles will be used for vaccination studies in mice, and the antibodies assessed by an in-vitro assay. This will lead to the development of a therapeutic and-or prophylactic HIV-1 vaccine, which could be used either for mass immunisation or in support of combination drug therapy and would have all the cost and production advantages of the widely used hepatitis B vaccine.Read moreRead less
A Virus-like Particle Vaccine For Hepatitis C Virus.
Funder
National Health and Medical Research Council
Funding Amount
$199,013.00
Summary
The aim is to evaluate the efficiency of a virus-like particle (VLP) vaccine for hepatitis C virus (HCV). HCV infects about 10,000 people every year in Australia and approximately 8, 000 of these will develop persistent infection. As a result, there are currently 150,000-200,000 HCV carriers in Australia and 500 million worldwide. These individuals represent a source of infection. Although the major route for transmission is blood and blood products, the advent of HCV screening in the blood bank ....The aim is to evaluate the efficiency of a virus-like particle (VLP) vaccine for hepatitis C virus (HCV). HCV infects about 10,000 people every year in Australia and approximately 8, 000 of these will develop persistent infection. As a result, there are currently 150,000-200,000 HCV carriers in Australia and 500 million worldwide. These individuals represent a source of infection. Although the major route for transmission is blood and blood products, the advent of HCV screening in the blood banks has reduced the risk of infection from this source. However, many intravenous drug users (IVD) share needles and although it is not common, transmission to spouses of carriers is well recognised. In addition, approximately 20% of HCV carriers have no recognised risk factor and it is unclear how these individuals became infected. Transmission of the virus to hospital inpatients and outpatients is also well recognised and as a result, it is clear that a vaccine is urgently required. However, as HCV cannot be cultured in the laboratory, it is impossible to develop a traditional vaccine; furthermore, because a proportion of patients who recover from HCV infection have no specific immunity and thus can be re-infected, the design of a vaccine presents a number of problems. Thus a vaccine which is based on the development of neutralising antibody is unlikely to be effective, in contrast to a vaccine which is designed to generate a cellular immune response. VLPs induce an effective cellular immune response and we plan to make VLPs composed of the L1 protein of bovine papillomavirus (BPV) which is fused to the highly immunogenic HCV core protein or to a string of protein segments (polytope). Laboratory mice will be vaccinated with these VLP and the cellular immune response measured. The vaccine will then be administered to HCV carriers to ensure the safety and the immunological efficacy of the product. This will be assessed serologically and clinically.Read moreRead less
Antibody Targeted Virus Particles For A Gene Therapy Approach To Inhibiting Atheroschlerosis Development
Funder
National Health and Medical Research Council
Funding Amount
$95,313.00
Summary
I am a Biotechnologist and my research looks into ways of preventing Atherosclerosis. Atherosclerosis is the build up of plaques in artery walls, and is the major precursor condition to stroke and myocardial infarction (heart attack). My project focuses on a preventative gene therapy which will be delivered specifically to early stage plaques. The gene will inhibit one of the earliest developmental stages of atherosclerosis: recruitment of immune cells to these sites, and so prevent their growth ....I am a Biotechnologist and my research looks into ways of preventing Atherosclerosis. Atherosclerosis is the build up of plaques in artery walls, and is the major precursor condition to stroke and myocardial infarction (heart attack). My project focuses on a preventative gene therapy which will be delivered specifically to early stage plaques. The gene will inhibit one of the earliest developmental stages of atherosclerosis: recruitment of immune cells to these sites, and so prevent their growth.Read moreRead less
Chimeric Virus-like Particles (VLPs) Displaying H1, H3 And H5 Haemagglutinins - Construction And Immunogenicity
Funder
National Health and Medical Research Council
Funding Amount
$207,543.00
Summary
Virus-like particles (VLPs) provoke strong immune responses in the body. We have developed a novel VLP system that allows the production of VLPs containing foreign vaccine antigens of much larger size than previously possible, and have shown that these VLPs provoke strong immune responses in mice without the use of adjuvants. The capacity of these VLPs is large enough to accommodate the most important vaccine antigen of influenza, the haemagglutinin (HA) molecule. We will test whether VLPs can b ....Virus-like particles (VLPs) provoke strong immune responses in the body. We have developed a novel VLP system that allows the production of VLPs containing foreign vaccine antigens of much larger size than previously possible, and have shown that these VLPs provoke strong immune responses in mice without the use of adjuvants. The capacity of these VLPs is large enough to accommodate the most important vaccine antigen of influenza, the haemagglutinin (HA) molecule. We will test whether VLPs can be produced containing each of the three most important HA types _ H1 and H3 that are currently circulating in man, and H5 (avian) that is considered a pandemic threat. VLPs will be tested for their ability to induce neutralizing antibody and cellular immune responses in mice, and for their ability to protect ferrets from influenza infection. If successful, the HA-VLP system would provide a method for the rapid production of new influenza vaccines using large-scale fermentation technology as for hepatitis B and many other vaccines, rather than eggs or cell culture as used for current influenza vaccines.Read moreRead less
A Novel Vaccine Platform For Trimeric Envelope Proteins: HIV-1 Envelope
Funder
National Health and Medical Research Council
Funding Amount
$139,250.00
Summary
Vaccines are urgently needed for the prevention of HIV/AIDS. The design of this vaccine candidate is based on the display of HIV-1 envelope spikes using a related primate retrovirus envelope with a more stable assembly to anchor the the spikes in a particle.