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A Structural And Functional Basis For The Regulation Of Gene Expression By Nuclear Retention Of RNA
Funder
National Health and Medical Research Council
Funding Amount
$504,097.00
Summary
The nuclear retention mechanism is a novel way used by cells to control which genes are made into proteins - a fundamental process for all diseases, particularly cancers. This project will employ cutting edge structural and proteomic techniques to determine the molecular details underpinning nuclear retention. These insights will be important for the development of new tissue-restricted gene therapy applications and drugs targeting the cancers that rely on this mechanism.
Two Recently Identified Calcium Transporters In Lactation And During Mammary Epithelial Cell Apoptosis.
Funder
National Health and Medical Research Council
Funding Amount
$465,115.00
Summary
The transport of calcium into milk is a key event in human health. In addition to its importance in neonatal nutrition, the way breast cells regulate calcium also has implications in breast cancer, as well as the modification of proteins important in immunity, and the activity of biopharmaceuticals. This grant will determine how two specific calcium transporters regulate calcium levels in the breast and their respective roles in cellular processes important in normal function and in disease.
Genome Wide Investigations Of Mycobacterium Tuberculosis To Reveal Processes Of Pathogenesis
Funder
National Health and Medical Research Council
Funding Amount
$396,341.00
Summary
Tuberculosis remains a global health burden of staggering proportions. Around 1 in 3 people are infected with Mycobacteria tuberculosis, the organism responsible for the disease, which kills 2 million people annually. The emergence of strains now resistant to almost all of our front line drugs has placed extra pressure on researchers who are attempting to develop new protective vaccines and the critical antibiotics required to eradicate the disease. Furthermore the current global HIV pandemic is ....Tuberculosis remains a global health burden of staggering proportions. Around 1 in 3 people are infected with Mycobacteria tuberculosis, the organism responsible for the disease, which kills 2 million people annually. The emergence of strains now resistant to almost all of our front line drugs has placed extra pressure on researchers who are attempting to develop new protective vaccines and the critical antibiotics required to eradicate the disease. Furthermore the current global HIV pandemic is making the situation far worse as HIV kills the very cells of the body that protect us from tuberculosis. This research project will fill the significant gaps in our knowledge of M. tuberculosis infection, specifically identify the genes of the organism which allow it to invade and spread throughout the body. M. tuberculosis infection consists of 3 characteristic stages, i.e. colonisation, spread and long term survival in specialised structures called granulomas. It is from these granulomas that the bacterium can emerge after long periods of inactivity to cause clinical tuberculosis. Using a mouse model of infection I will define the genes needed by the bacterium to survive at these 3 key stages of disease thereby providing for a better knowledge base from which to design new vaccine strategies and to create effective drugs.Read moreRead less
SPRY Domain-containing SOCS Box (SSB) Protein Interaction With Par-4: Structure And Biochemical Implications
Funder
National Health and Medical Research Council
Funding Amount
$529,565.00
Summary
The suppressor of cytokine signalling (SOCS) proteins, are intracellular molecules that negatively regulate hormone and growth factor action, and whose functional importance has been borne out in many physiological studies. The SOCS box is a small part of the SOCS proteins that is believed to facilitate degradation of SOCS target proteins. The SPRY domain-containing SOCS box protein-2 (SSB-2) is one of four proteins within the greater SOCS family (SSB-1 to -4), which have a SOCS box and a centra ....The suppressor of cytokine signalling (SOCS) proteins, are intracellular molecules that negatively regulate hormone and growth factor action, and whose functional importance has been borne out in many physiological studies. The SOCS box is a small part of the SOCS proteins that is believed to facilitate degradation of SOCS target proteins. The SPRY domain-containing SOCS box protein-2 (SSB-2) is one of four proteins within the greater SOCS family (SSB-1 to -4), which have a SOCS box and a central SPRY domain. The SPRY domain mediates interaction with other proteins within the cell. Over 300 proteins are known to contain a SPRY domain. We recently determined the first atomic structure of a SPRY domain as part of SSB-2, using nuclear magnetic resonance (NMR) spectroscopy. We further identified Par-4 (prostate apoptosis response-4) as a novel and direct protein binding partner for SSB-1, -2 and -4, but not SSB-3. Extensive mutational analysis subsequently identified a series of SSB-2 mutants that were unable to bind Par-4 but retained structural integrity. Cancer cells develop through a series of genetic events and escape programmed cell death or apoptosis, continuing to grow inappropriately. Par-4 was originally discovered as a gene up-regulated in prostate cancer cells undergoing apoptosis and primarily appears to sensitise cancer cells to apoptotic stimuli. This proposal aims to further investigate SSB-Par-4 binding. The 3D structure of the complex will be determined and biochemical consequences of this interaction characterised. If SSB proteins regulate Par-4 levels, then chemical disruption of SSB-Par-4 binding could potentially result in an increase in Par-4 protein levels, making cancer cells more susceptible to killing by cytotoxic drugs.Read moreRead less
Throughout our lives cells must die and be replenished. One way multicellular organisms remove unwanted cells is through a process called programmed cell death. This process eliminates redundant, damaged or infected cells by a program of cell suicide. We are studying the underlying molecular mechanisms of this cell suicide in order to design new pharmaceuticals to treat illnesses caused by a disruption in programmed cell death. The fine balance between living and dying cells must be maintained a ....Throughout our lives cells must die and be replenished. One way multicellular organisms remove unwanted cells is through a process called programmed cell death. This process eliminates redundant, damaged or infected cells by a program of cell suicide. We are studying the underlying molecular mechanisms of this cell suicide in order to design new pharmaceuticals to treat illnesses caused by a disruption in programmed cell death. The fine balance between living and dying cells must be maintained and if this balance is lost then disease may result. A reduced level of cell death may result in cancers while too many dying can contribute to degenerative diseases such as Alzheimer's disease and stroke. Currently many of these diseases do not have effective treatments. We will determine the three-dimensional structures of key proteins involved in programmed cell death and use this information to design drugs that can interfere with the molecular processes involved in signalling cell death. Such drugs may prove useful new therapies in a wide range of diseases caused by a breakdown in the biochemical paths to cell death.Read moreRead less
Nucleic Acid Synthesis And Cell Division In Model Pathogenic Bacteria
Funder
National Health and Medical Research Council
Funding Amount
$781,345.00
Summary
The rise of antibiotic resistance, particularly in hospitals, over recent years represents a huge financial burden on the health system, in addition to the personal costs to the patient infected. Over the last 60 years, we have become accustomed to the availability of antibiotics that can effectively treat most, if not all, bacterial infections. Today, this is not the case, and some bacteria in hospitals are resistant to all therapeutically useful antibiotics. The costs of drug development are v ....The rise of antibiotic resistance, particularly in hospitals, over recent years represents a huge financial burden on the health system, in addition to the personal costs to the patient infected. Over the last 60 years, we have become accustomed to the availability of antibiotics that can effectively treat most, if not all, bacterial infections. Today, this is not the case, and some bacteria in hospitals are resistant to all therapeutically useful antibiotics. The costs of drug development are very considerable; from the financial perspective of a pharmaceutical company, the de novo development of new antibiotics is not attractive because they are drugs that are only used for a short period. Recoupment of development costs takes a long time. As a result, very few new antibiotics are currently in development, and many of the newer ones are the result of academic efforts and subsequent formation of spin-out companies that develop new drugs through to phase 1 trials. The need for new, and effective, antibiotic therapies is pressing. We propose to identify and validate the use of key essential biological processes as targets for the development of new antimicrobial agents in two important hospital pathogens. Staphylococcus aureus is a well known and established pathogen that is the number one cause of hospital acquired (nosocomial) infections. Acinetobacter sp. is a relatively new problem in nosocomial infections, but is growing in importance due to the startling rate at which it is able to acquire resistance to antibiotics. In both organisms, we intend to target essential protein-protein interactions involved in DNA replication (duplication of genetic material), transcription (production of a genetic message), and cell division. The targeting of protein-protein interactions, rather than the enzymic activity of a protein provides a novel and unexploited avenue for antibacterial development with great potential for success.Read moreRead less
HCMV Protein Kinase And DNA Polymerase Domains Involved In Antiviral Sensitivity, Viral Replication And Cell Tropism
Funder
National Health and Medical Research Council
Funding Amount
$269,250.00
Summary
Many individuals with compromised immune systems - such as those with HIV-AIDS, cancer and transplant recipients are at risk of disease from human cytomegalovirus (HCMV) infection. Currently the most effective therapies are suppression of virus replication by continuing administration of antiviral agents, principally ganciclovir (GCV), cidofovir (CDV) or foscarnet (phosphonoformic acid or PFA). The use of antivirals for increasingly longer durations in an enlarging population of patients with ir ....Many individuals with compromised immune systems - such as those with HIV-AIDS, cancer and transplant recipients are at risk of disease from human cytomegalovirus (HCMV) infection. Currently the most effective therapies are suppression of virus replication by continuing administration of antiviral agents, principally ganciclovir (GCV), cidofovir (CDV) or foscarnet (phosphonoformic acid or PFA). The use of antivirals for increasingly longer durations in an enlarging population of patients with irreversible chronic immunosuppression, has resulted in the emergence of increasing numbers of drug-resistant HCMV viruses in this group of individuals. In patients with AIDS, 7.6% of isolates in one study were shown to be GCV resistant and we have found similar levels (10.8%) in immunosuppressed Australians. Of the small number of antiviral agents with any useful activity against HCMV, GCV, and aciclovir (ACV) are nucleoside analogues. PFA is a pyrophosphate analogue that competitively inhibits pyrophosphate binding by HCMV DNA polymerase. These drugs are activated by a specific gene of HCMV (UL97 (Pk)) and a mouse virus (MCMV - M97Pk) that is very similar to HCMV. The drug then acts on a second gene encoding the DNA polymerase (HCMV UL54 DP or MCMV M54DP) to prevent viral growth. We are investigating the resistance genotypes and phenotypes in CMV resistant to 7 antiviral drugs including GCV, CDV and PFA. We have shown new resistant genotypes and are currently determining the protein-functional correlates of the genotypic changes, in order to increase understanding of the PK and DP genes, define the genetic causes of resistance, and to produce better targets for antiviral agents.Read moreRead less
Relaxin-3 Systems In Brain: Validation Of Neural Targets And Functional Roles
Funder
National Health and Medical Research Council
Funding Amount
$537,579.00
Summary
Our laboratory recently discovered the brain 'transmitter' called 'relaxin-3', and are researching how it affects brain activity and animal physiology and behaviour. Findings suggest that relaxin-3 can modulate memory, responses to stress and other complex behaviours. Identifying the various actions of relaxin-3 in the brain could provide potential new treatments for conditions such as anxiety-depression, cognitive deficits (dementia) and schizophrenia.
Many of the most serious diseases of Western societies including obesity, Type 2 diabetes, cancer growth and metastasis and cardiovascular disease have metabolic dimensions. The enzyme AMPK regulates cellular and whole body energy homeostasis by coordinating metabolic pathways to balance energy demand with nutrient supply. We are studying the structure and function of AMPK with the aim of better treating metabolic diseases.
Structural And Functional Analysis Of A Cancer-linked Co-regulator Complex
Funder
National Health and Medical Research Council
Funding Amount
$729,571.00
Summary
We seek to understand the mechanisms by which genes are switched on and off throughout our lifetime. A number of multi-component protein machines are involved in this process but their make-up and mechanism of action is not understood. We will investigate the structure and function of one of these machines that has been strongly linked to cancer.