The Role Of Vif In Enhancing HIV Replication And Effecting The Integrity Of The Replication Complexes Of HIV
Funder
National Health and Medical Research Council
Funding Amount
$260,200.00
Summary
HIV-AIDS is still one of the leading causes of infectious human fatality worldwide. The genome of HIV encodes six viral accessory proteins that are necessary for viral replication and infection. One of these genes, viral infectivity factor (vif), is essential for production of infectious virus. Exactly how this viral protein works within the cell is not clear at present. Current literature suggests that Vif acts in some way to enhance reverse transcription, one of the early stages of the viral l ....HIV-AIDS is still one of the leading causes of infectious human fatality worldwide. The genome of HIV encodes six viral accessory proteins that are necessary for viral replication and infection. One of these genes, viral infectivity factor (vif), is essential for production of infectious virus. Exactly how this viral protein works within the cell is not clear at present. Current literature suggests that Vif acts in some way to enhance reverse transcription, one of the early stages of the viral life cycle. We aim to investigate the action of Vif in stabilizing early HIV reverse transcription complexes to understand how it acts to enhance HIV replication and viral infection. The early stages of HIV replication are critical for establishing infection and hence ideal targets for therapeutic intervention. This research will help understand how Vif works in a cell and affects the infectivity of HIV viral particles and may be suggestive of potential targets for development of anti-viral drugs.Read moreRead less
Transcriptional Control Of Peripheral T Cell Differentiation During Pathogen Infection And Autoimmunity
Funder
National Health and Medical Research Council
Funding Amount
$92,314.00
Summary
White blood cells, specifically helper and killer T cells, play an important role in fighting infection. They are tightly regulated and if not properly controlled can lead to aggressive autoimmune diseases such as diabetes and multiple sclerosis. My studies will elucidate the mechanisms behind the regulation of T cells at steady-state and during disease. Insights gained from this project will have implications for the design of new approaches to combat infectious and autoimmune diseases.
Critical Role Of TNF In Host-virus Interactions And Outcome Of Infection: Involvement Of Reverse Signalling Through MTNF
Funder
National Health and Medical Research Council
Funding Amount
$496,500.00
Summary
Cytokines are molecules produced by cells that take part in the immune response. They coordinate the activities of leukocytes and are important in the host response to virus infections. For their part, viruses have evolved strategies to try and evade the host response. The analysis of these strategies in the context of a viral infection will lead to a better understanding of the immune system and host-virus interactions. Tumour necrosis factor is a cytokine made by specific leukocytes, in two st ....Cytokines are molecules produced by cells that take part in the immune response. They coordinate the activities of leukocytes and are important in the host response to virus infections. For their part, viruses have evolved strategies to try and evade the host response. The analysis of these strategies in the context of a viral infection will lead to a better understanding of the immune system and host-virus interactions. Tumour necrosis factor is a cytokine made by specific leukocytes, in two stages: First, the cytokine is exposed on the surface of the cell and then it is clipped off and released as a soluble form. In either form it can interact with specific receptors on other cells and, in this way, change the cells' activities. We have found that binding of tumour necrosis factor receptors to the cytokine, while it is in its membrane form, can also send a message backwards into the cell bearing the tumour necrosis factor. This process, known as reverse signalling, then changes the activity of this cell and constitutes a major new route through which information transfer can occur. In this project we will characterize the biological changes that result from reverse signalling in specific types of leukocytes. We will be looking at the role of membrane tumour necrosis factor in two separate models of viral disease. The first is influenza pneumonia that is responsible for a great deal of morbidity and mortality worldwide. The second is a model of poxvirus infection (mousepox) that mimics the disease smallpox in humans. Human poxvirus infections are on the rise (e.g. monkeypox) and there is an increased threat of smallpox as a weapon of bioterrorism. Mousepox is a good model for the study of generalized viral infections and is also an excellent example of a virus that encodes proteins specifically designed to interfere with host tumour necrosis factor. Our studies will focus on the role of this cytokine in host-virus interactions and the outcome of infection.Read moreRead less
Determining The Role Of Rel/NF-kB Transcription Factors In CD8 T Cell Homeostasis.
Funder
National Health and Medical Research Council
Funding Amount
$426,500.00
Summary
NF-kB proteins comprise a family of transcription factors that regulate key genes involved in immune responses, inflammation, cell death and proliferation. This family of proteins are potential drug targets for treatment of various diseases. How and when such inhibitors are used in clinical situations depends on understanding how and which cells of the immune system are specifically affected by the absence of NF-kB proteins. In a number of treatment settings intercurrent viral infections occur f ....NF-kB proteins comprise a family of transcription factors that regulate key genes involved in immune responses, inflammation, cell death and proliferation. This family of proteins are potential drug targets for treatment of various diseases. How and when such inhibitors are used in clinical situations depends on understanding how and which cells of the immune system are specifically affected by the absence of NF-kB proteins. In a number of treatment settings intercurrent viral infections occur frequently and therefore there is an even greater need to understand how the immune system may be affected or compromised in response to the primary treatment. This work will provide insights into the cellular and molecular mechanisms affected by the absnece of a particular NF-kB family member (NF-kB1) in CD8 T cells during normal T cell homeostasis and when challenged with viruses. What we learn from our experiments could have important implications for the development of vaccines.Read moreRead less
Mechanisms Underlying APOBEC3G Restriction Of HIV-1
Funder
National Health and Medical Research Council
Funding Amount
$540,075.00
Summary
In the fight against worldwide HIV-AIDS, understanding natural cell defenses to the HIV virus may identify new virus targets and strategies to block HIV in humans. Here, we will use state-of-the-art, high resolution, fluorescent microscopy to understand how the recently identified cell protein, APOBEC3G, blocks the HIV life cycle in human cells. We anticipate that APOBEC3G will stop HIV from invading the nucleus of human cells to defend against HIV, a strategy we can apply to new therapies.
Regulation Of Antiviral And Antiinflammatory Responses By MTNF: Key Role Of Reverse Signaling By Host And Viral TNFR
Funder
National Health and Medical Research Council
Funding Amount
$568,501.00
Summary
New and re-emerging viral infections continue to pose a major problem. We have recently discovered a hitherto unrecognized process that the body uses to regulate its response to infection. Some viruses have evolved to target this process, underscoring its importance. We will study 2 virus models, poxvirus and influenza A, to understand how this process works during infection. We will also examine the potential to exploit this process to block pathology and influence recovery from infection.
Herpesviruses infect most Australians and cause recurrent ulcers, birth defects and cancer. Infection lasts lifelong, and spreads to close contacts without obvious clinical signs. Thus disease is hard to prevent. However we can learn much from related animal infections. We have shown that both mouse and human herpesviruses enter mice via cells in the nose. Thus human infections might follow the same route. We will define what body defences work here and whether vaccines can prevent infection.
Human ?-herpesviruses persist for life, cause cancers and emerge with particular virulence when the immune system is weak. Vaccination against them is therefore an important health priority. We have shown for a related ?-herpesvirus of mice that live vaccines protect. Antibody seems to play a major role. We will test whether safer, recombinant vaccines are also sufficient to elicit protective antibody. Thus we can establish a viable strategy for preventing virus-induced human cancers.