We will construct different genetically engineered viruses, which infect cells in the respiratory tract, to deliver genes encoding proteins from human immunodeficiency virus (the AIDS virus). These engineered viruses can be expected to generate an active immune response in mucosal tissues, including the vaginal and rectal tracts. As these are the major routes for transmission of the AIDS virus, these new vaccines are expected to reduce transmission of the AIDS virus.
HIV is one of the highest public health priorities of our time. Traditional vaccines have been unsuccessful highlighting the need for alternative approaches to HIV vaccine design. We propose to modify a novel technology developed initially for targeted drug delivery, termed “capsules”, for the purpose of inducing an immune response. This is a generic technology with applications for other infectious diseases and cancer and brings together disparate disciplines of nanochemistry and immunology.
Escape And Reversion Of Critical Immune Responses: Insights Into Effective Immunity To HIV
Funder
National Health and Medical Research Council
Funding Amount
$372,446.00
Summary
The HIV pandemic is a global emergency. The overall goal of this grant proposal is to elucidate the requirements for protective immunity to HIV. Although immune responses have some effect on HIV replication, the virus mutates and evolves to escape immune pressure. However, each mutation away from wild-type virus likely results in at least some impairment in the ability of the virus to replicate. Where efficient immune responses target regions of the virus that are critical to virus replication, ....The HIV pandemic is a global emergency. The overall goal of this grant proposal is to elucidate the requirements for protective immunity to HIV. Although immune responses have some effect on HIV replication, the virus mutates and evolves to escape immune pressure. However, each mutation away from wild-type virus likely results in at least some impairment in the ability of the virus to replicate. Where efficient immune responses target regions of the virus that are critical to virus replication, escape mutations may result in viral variants incapable of causing disease. Resulting from an exciting collaboration between HIV and theoretical biologists, we have recently identified techniques to calculate the effectiveness of immunity and the cost of subsequent immune escape variants. We will use and expand these techniques to identify immune responses that result in the most effective control of viral replication. These studies will lead to ways to improve HIV vaccines and thereby prevent HIV.Read moreRead less
Studies On The Activation And Immunogenicity Of The HIV-1 Glycoproteins, Gp120-gp41
Funder
National Health and Medical Research Council
Funding Amount
$606,438.00
Summary
More than 34 million people were living with HIV-1 in 2011 with ~7,000 new infections still occurring daily. A prophylactic vaccine for HIV-1 is needed to stop its transmission, however, this goal is yet to be achieved. Our proposed studies will inform the design of prophylactic HIV-1 vaccines that act by making antibodies that neutralize the virus.
Develop New Approaches To Cancer Diagnosis And Treatment
Funder
National Health and Medical Research Council
Funding Amount
$4,000,000.00
Summary
Apoptosis is the dominant focus of our planned studies, because its impairment is both a critical step towards malignancy and a barrier to effective treatment. Arguably, the laboratory heads within our division and our collaborators from the Structure Biology Division at WEHI constitute the world’s strongest group with this focus. Our accumulated experience in this field from its renaissance in 1988 and the many unique materials they have created superbly position us to answer the fundamental qu ....Apoptosis is the dominant focus of our planned studies, because its impairment is both a critical step towards malignancy and a barrier to effective treatment. Arguably, the laboratory heads within our division and our collaborators from the Structure Biology Division at WEHI constitute the world’s strongest group with this focus. Our accumulated experience in this field from its renaissance in 1988 and the many unique materials they have created superbly position us to answer the fundamental questions and translate them into new therapeutic approaches. Our team’s second focus, the links of stem cells to cancer, is also of great importance, because the rare stem cells in the tumour may dictate therapeutic outcome. This Fellowship aims to addresses fundamental issues with enormous potential for medicine. It builds on productive ongoing research by a team with diverse complementary expertise, a record of effective interaction, high momentum and a history of path-breaking discoveries. I plan to maintain and further develop our Division (the Molecular Genetics of Cancer Division at WEHI) as one of the strongest teams for cancer research and development of cancer therapies in the world. Our division contains several laboratories that are highly interactive and complimentary in their approaches and research interests. I plan to strengthen the already highly productive laboratories in our division and to develop some new ones (see below under ‘proposed team’). I plan to increase work of our division to also include studies on other solid tumours (e.g. colon cancer, lung cancer, prostate cancer). This Fellowships aims to greatly enhance cancer research and hopefully also clinical practice in Australia. This should enhance the reputation of Australia as a country with recognized excellence in medical research and clinical practice. I am also confident that our division will continue to educate outstanding PhD graduates and postdoctoral fellows who will in due course become independent researchers and develop into future leaders in medical research in Australia and-or overseas.Read moreRead less
Tuberculosis kills more people than any other infectious disease, and approximately one-third of the world's population is latently infected with Mycobacterium tuberculosis. This situation is largely due to the low efficacy of the only licensed TB vaccine, BCG, and the 'black box' of what constitutes protection against TB. This project aims to unravel the mechanisms of protective immunity against TB to develop a highly protective vaccine.
HIV is a rapidly evolving virus, and within an infected individual it continually acquires new mutations and joins together mutations by recombination. We have developed a novel system for studying recombination, and find that different individuals have different recombination rates, which may contribute to why some individuals survive longer. This project aims to identify the mechanisms responsible for differing recombination rates and how we can alter these to improve patient outcome.