Determination Of The Mechanisms Of Action Of A Cytomegalovirus Chemokine Receptor Homologue In Pathogenesis
Funder
National Health and Medical Research Council
Funding Amount
$251,341.00
Summary
A number of herpesviruses encode proteins that are similar to proteins of our immune system. These pirated proteins are exploited by the virus to enable it to replicate and persist in the infected individual, usually by evading or gaining advantage from the normal immune response. This project will investigate the role of one such protein found in both human and animal herpesviruses (specifically cytomegaloviruses (CMV)) that is conserved with cellular cell surface proteins (receptors) that bind ....A number of herpesviruses encode proteins that are similar to proteins of our immune system. These pirated proteins are exploited by the virus to enable it to replicate and persist in the infected individual, usually by evading or gaining advantage from the normal immune response. This project will investigate the role of one such protein found in both human and animal herpesviruses (specifically cytomegaloviruses (CMV)) that is conserved with cellular cell surface proteins (receptors) that bind immune signaling molecules (chemokines). Chemokines are important proteins in the early response to infection. Binding of chemokines to their receptors initiates a cascade of signals within the cell that has profound effects on cellular responses to environmental stimuli. Thus, it is believed that herpesviruses have acquired chemokine receptors to modify or react to the immune response, causing infected cells to behave abnormally either despite or in response to chemokine signals. This project will determine how this CMV specific protein affects the function of cells that CMV infects and how this may promote virus replication, dissemination and persistence in infected hosts. We will also engineer CMVs where the activity of the target protein can be inhibited by administration of prototype antiviral drugs. If inhibition of the activity of the protein is found to reduce virus replication, dissemination or persistence, then this will demonstrate that this type of protein would be a suitable target for the development of novel drugs active against CMV infections. CMV can cause serious (potentially life threatening) disease in newborn children (following infection in the uterus) and immunosuppressed people (eg. organ transplant recipients and people with HIV-AIDS). Our studies will improve our understanding of the contribution of a specific CMV protein to disease, thereby assisting efforts to reduce the impact of CMV infections.Read moreRead less
Hepatitis C virus (HCV) and Human immunodeficiency virus (HIV) infect 200 million and 50 million people world-wide, respectively, and there are no preventative vaccines. The work outlined in this fellowship seeks to understand the structure and function of the major surface proteins of these viruses, their ability to be recognised by the immune system and to develop a novel vaccine for the prevention of HCV.
Structure And Function Of The Hepatitis C Virus Glycoproteins E1 And E2.
Funder
National Health and Medical Research Council
Funding Amount
$533,828.00
Summary
Hepatitis C virus (HCV) infects approximately 3 % of the global human population with 150,000-200,000 HCV-infected individuals currently living in Australia. Chronic HCV infection is associated with recurrent, progressively worsening liver disease, liver cirrhosis and hepatocellular carcinoma. The current therapy (interferon-ribavirin) is effective in only 40 % of patients and is often associated with severe side-effects. The mechanisms that HCV uses to replicate in liver cells is poorly underst ....Hepatitis C virus (HCV) infects approximately 3 % of the global human population with 150,000-200,000 HCV-infected individuals currently living in Australia. Chronic HCV infection is associated with recurrent, progressively worsening liver disease, liver cirrhosis and hepatocellular carcinoma. The current therapy (interferon-ribavirin) is effective in only 40 % of patients and is often associated with severe side-effects. The mechanisms that HCV uses to replicate in liver cells is poorly understood. In this project we aim to better understand how the viral glycoproteins, E1 and E2, function in the initiation of infection. In particular, we will examine how these glycoproteins bind to liver cell receptors and then mediate virus-cell membrane fusion. These processes lead to the penetration of the HCV genetic material into the cell where it is replicated. These studies are essential for the discovery of new targets for antiviral agents and vaccines.Read moreRead less
The HIV-1 Tat Protein Is An Reverse Transcription Co-factor.
Funder
National Health and Medical Research Council
Funding Amount
$404,592.00
Summary
HIV-1 is the virus that causes AIDS. In order for HIV-1 to grow, the viral genetic material must be converted into a form that is compatible with a human host. Specifically, the HIV-1 genetic material is made of RNA while the human genome is composed of DNA. An HIV-1 enzyme called reverse transcriptase (RT) is used for this purpose. We have discovered that another HIV-1 protein called Tat is also required for the efficient conversion of HIV-1 RNA into HIV-1 DNA. If HIV-1 lacks Tat, then this tra ....HIV-1 is the virus that causes AIDS. In order for HIV-1 to grow, the viral genetic material must be converted into a form that is compatible with a human host. Specifically, the HIV-1 genetic material is made of RNA while the human genome is composed of DNA. An HIV-1 enzyme called reverse transcriptase (RT) is used for this purpose. We have discovered that another HIV-1 protein called Tat is also required for the efficient conversion of HIV-1 RNA into HIV-1 DNA. If HIV-1 lacks Tat, then this transformation process is inefficient and HIV-1 is not able to grow. Recently our group made a breakthrough discovery on how Tat works. Tat can directly bind to RT and stimulate the conversion process. This research is aimed at a detailed analysis of Tat and RT interaction. This information is required in order to understand how this interaction can be blocked in order to stop HIV-1 growth. In the long-term, results produced by this research will be required to discover novel drugs to combat HIV-AIDS.Read moreRead less
Cell Surface Lectin Receptors For Attachment And Entry Of Influenza Viruses Into Cells Of The Innate Immune System
Funder
National Health and Medical Research Council
Funding Amount
$530,094.00
Summary
Influenza virus is a leading cause of respiratory infection and death worldwide. Infection of humans is initiated when the virus contacts cells lining the respiratory tract. Infection of epithelial cells leads to virus amplification whereas infection of immune cells results in virus destruction. Despite extensive research efforts, it is not clear how the virus infects these cells. This project aims to identify receptors on human cells used by influenza virus to attach to and infect immune cells.
The occcurence of herpes simplex virus (HSV) in the general population is very high (up to 60%). In Central Africa, co-infection of HSV and HIV may increase HIV transmission in more than 40% of cases. HSV enters the human body via the skin before entering the termini of nerve cell processes. It is transported along these processes to the body of the nerve cell. HSV lies dormant within these nerve cell bodies near the spinal cord in most people. Intermittently the virus reactivates and is transpo ....The occcurence of herpes simplex virus (HSV) in the general population is very high (up to 60%). In Central Africa, co-infection of HSV and HIV may increase HIV transmission in more than 40% of cases. HSV enters the human body via the skin before entering the termini of nerve cell processes. It is transported along these processes to the body of the nerve cell. HSV lies dormant within these nerve cell bodies near the spinal cord in most people. Intermittently the virus reactivates and is transported back down the nerve cell processes to the skin where it causes blisters-ulcers or is shed without causing symptoms. The aim of this project is to determine how HSV is assembled within cells at the molecular level. This will lead to identification of crucial molecular interactions required for viral assembly. Such information on viral assembly will allow development of inhibitors of this process which may be candidates for use as antivirals for control of recurrent herpes simplex. These antiviral agents will be able to target key viral molecular interactions in essentially all types of cells in the body and act against other herpesviruses in general.Read moreRead less
Functional Roles Of The Tegument Proteins Of Herpes Simplex Virus Type 1
Funder
National Health and Medical Research Council
Funding Amount
$461,597.00
Summary
The occurrence of herpes simplex virus (HSV) in the general population is very high (up to 60%). HSV enters the human body via the skin before entering nerve cells where it lies dormant in most people. Intermittently the virus reactivates and usually forms blisters at the skin when it sheds. The aim of this project is to define a molecular interaction network at the protein level during the course of infection of a host cell. This information will provide new targets for design of antivirals.
Chikungunya Virus Disease; The Role Of Proteases And Their Receptors
Funder
National Health and Medical Research Council
Funding Amount
$682,716.00
Summary
Chikungunya virus (CHIKV) is a mosquito borne virus related to the Australian Ross River virus. The arthritic disease caused by these viruses is often poorly managed by current treatments. We have recently identified several proteins call proteases that circulate in the blood of infected people and promote arthritis. If successful the grant will provide new treatment options for these (and perhaps other) diseases using recently developed drugs that inhibit the activity of these proteases.
Identification Of Host Factors That Restrict Influenza Virus Replication In Macrophages
Funder
National Health and Medical Research Council
Funding Amount
$566,446.00
Summary
Influenza virus infects different cells in the airways, including immune cells (macrophages) and non-immune cells (epithelial cells). Epithelial cell infection results in virus amplification and release whereas macrophage infection leads to virus destruction. This project will identify cellular factors expressed by macrophages that block virus amplification and release. Identification of novel antiviral factors is an important step towards developing strategies to reduce influenza disease.