Splice Correction As A Treatment For Rare Diseases
Funder
National Health and Medical Research Council
Funding Amount
$824,316.00
Summary
We propose that a strategy of bringing effective and personalised treatments to amenable patients with rare genetic diseases, though ambitious, is readily achievable and opportune. Importantly, a consensus approach will facilitate expediting potentially curative treatments for many patients with rare diseases that would be unlikely to be commercially viable if considered individually.
A Transgenic Approach To Rationale Drug Design In Plasmodium Falciparum
Funder
National Health and Medical Research Council
Funding Amount
$420,872.00
Summary
Malaria is a disease caused by parasites of the genus Plasmodium. It is responsible for more than 2 million deaths per year predominately in Sub-Saharan Africa. Many of the currently used drugs to combat this disease are failing through drug resistance in the parasite population. New and novel drugs are urgently required. This project uses state of the art techniques to identify and validate new and novel targets within the parasite that can be used for rational drug design
Optimization Of Splice Switching Therapies To Treat Duchenne Muscular Dystrophy
Funder
National Health and Medical Research Council
Funding Amount
$448,827.00
Summary
Duchenne muscular dystrophy, the most common and serious form of childhood muscle wasting, is caused by mutations in the dystrophin gene that block synthesis of the normal product. Antisense oligomers have been used in clinical trials to remove the disease-causing part of the message and rescue expression. Clinical trials have demonstrated proof-of-concept, although individual responses varied. This application seeks to improve the therapeutic potential of these compounds.
Plasmids are additional mini-chromosomes carried by many bacteria. They carry information that enables their hosts to prosper in otherwise hostile environments. Plasmids spread rapidly between bacteria, efficiently disseminating plasmid-borne information throughout bacterial populations. Many plasmids carry information that increases the virulence of their host. The emergence of multi-drug resistant bacteria and the rapid spread of the information enabling bacteria to withstand most antibiotics ....Plasmids are additional mini-chromosomes carried by many bacteria. They carry information that enables their hosts to prosper in otherwise hostile environments. Plasmids spread rapidly between bacteria, efficiently disseminating plasmid-borne information throughout bacterial populations. Many plasmids carry information that increases the virulence of their host. The emergence of multi-drug resistant bacteria and the rapid spread of the information enabling bacteria to withstand most antibiotics available today, were mediated by plasmids. Plasmids also carry information that ensures their own survival. Consequently, their hosts retain the plasmids even when it is no longer beneficial for them to do so. For example, plasmids mediating resistance to antibiotics are not lost when bacterial hosts are grown in the absence of those antibiotics. That is because plasmids have control systems, which ensure both that replication of the plasmid keeps pace with that of its host, and that the plasmid does not produce so many copies of itself that it overwhelms its host or places it at a competitive disadvantage amongst other bacteria. This project examines the intricate regulatory system that enables two groups of antibiotic-resistance plasmids to ensure that, on average, each plasmid molecule is replicated once per bacterial cell cycle. This system uses a tertiary RNA structure as a molecular switch, an antisense RNA as the regulator of this switch, and a protein that interacts with DNA sequences on the plasmid and with a bacterial protein, to initiate replication. Information gained from studies of plasmid systems is essential to the development of treatments for the elimination of antibiotic-resistance and virulence-contributing plasmids from populations of pathogenic bacteria. Antisense RNAs are not only a powerful research tool, but are also being developed for therapeutic use. Understanding how these RNAs interact with their targets will increase their effectiveness.Read moreRead less
C-JUN TARGETING STRATEGIES AS NOVEL CARDIOPROTECTIVE AGENTS IN ISCHAEMIA-REPERFUSION INJURY
Funder
National Health and Medical Research Council
Funding Amount
$361,148.00
Summary
Acute myocardial infarction (AMI) and its sequelae are an increasing problem in terms of morbidity, mortality and healthcare costs in Australia and the industrialised world; in the USA this is estimated annually at 900,000 and 225,000 patients and US$60 billion, respectively. Current treatment for AMI includes mechanical (percutaneous coronary intervention) or thrombolytic therapy; however, these approaches are directed primarily at epicardial arteries rather than the myocardium and are, therefo ....Acute myocardial infarction (AMI) and its sequelae are an increasing problem in terms of morbidity, mortality and healthcare costs in Australia and the industrialised world; in the USA this is estimated annually at 900,000 and 225,000 patients and US$60 billion, respectively. Current treatment for AMI includes mechanical (percutaneous coronary intervention) or thrombolytic therapy; however, these approaches are directed primarily at epicardial arteries rather than the myocardium and are, therefore, suboptimal. Strategies aimed at directly protecting cardiomyocytes from ischaemia-reperfusion injury, reducing leukocyte recruitment and myocardial cell death, would complement current approaches restoring epicardial artery flow and are keenly sought. This project will demonstrate the capacity of two separate gene-silencing strategies (DNAzymes and siRNA to suppress the expression of the immediate-early gene, c-Jun in cardiomyocytes and reduce infarct size, left ventricular dysfunction, apoptosis, inflammation, production of reactive oxygen species, angiogenesis and fibrosis in the injured rat myocardium. It will also shed light on the molecular mechanisms underlying c-Jun-mediated myocardial inflammation. As such, these studies will provide important proof of principle evidence for these small molecule nucleic acid agents as potential therapeutic tools as cardioprotective agents in ischaemia-reperfusion injury.Read moreRead less
Fine Mapping And Characterisation Of Polymorphic Immunoregulatory Genes In The Central MHC
Funder
National Health and Medical Research Council
Funding Amount
$529,656.00
Summary
The major histocompatibility complex (MHC) is a group of genes that is usually inherited as a block. The group includes the HLA genes which can serve as markers for neighbouring genes that are less well characterised. For example, some variant forms (polymorphisms) of the HLA genes mark differences in susceptibility to diabetes, lupus and IgA deficiency. We propose that this may be caused by variations in the neighbouring uncharacterised genes affecting control of persistent inflammation of vari ....The major histocompatibility complex (MHC) is a group of genes that is usually inherited as a block. The group includes the HLA genes which can serve as markers for neighbouring genes that are less well characterised. For example, some variant forms (polymorphisms) of the HLA genes mark differences in susceptibility to diabetes, lupus and IgA deficiency. We propose that this may be caused by variations in the neighbouring uncharacterised genes affecting control of persistent inflammation of various target organs. Evidence so far suggests a gene in the central MHC may be responsible. In this project we will study DNA from patients who have unusual combinations of HLA and other MHC genes, to further define which part of the MHC contains the critical immunoregulatory genes. Most genes in the MHC have now been identified by the Human Genome Project, so we will be able to select the most promising candidates in the region of interest. We will then use DNA of known HLA types to determine if the candidate genes vary between individuals. The function of interesting genes will then be investigated by creating cell lines carrying part of the gene in the reverse (anti-sense) orientation. This generates a reverse messenger (m) RNA which binds the normal mRNA and prevents synthesis of the protein. We will then examine which responses of the resultant cell lines are abnormal (eg: production of inflammatory mediators or cytokines). Having elucidated the functions our genes, we will overexpress each version that occurs in patients in cultured cells and look for differences in function. In parallel with this work, we will use laboratory mice with known combinations of MHC genes to establish the effects of particular genes in a live animal.Read moreRead less
Plasmids are extra mini-chromosomes that are present in many bacteria. They carry information that enables their hosts to survive and prosper in hostile environments. Plasmids are able to spread rapidly between bacteria, ensuring that the information they carry is rapidly disseminated throughout bacterial populations. Many plasmids carry information that increases the virulence of their host bacteria, because it adds to their repertoire of toxins and other adjuncts to invasiveness and colonisati ....Plasmids are extra mini-chromosomes that are present in many bacteria. They carry information that enables their hosts to survive and prosper in hostile environments. Plasmids are able to spread rapidly between bacteria, ensuring that the information they carry is rapidly disseminated throughout bacterial populations. Many plasmids carry information that increases the virulence of their host bacteria, because it adds to their repertoire of toxins and other adjuncts to invasiveness and colonisation, or enables them to survive in the presence of antibiotics. The emergence of multi-drug resistant bacteria and the rapid spread of the ability of bacteria to withstand most antibiotics available to date were mediated by plasmids. Plasmids also carry information that ensures their own survival. The consequence of this is that their bacterial hosts retain the plasmids, even when it is no longer beneficial to do so. For example, plasmids carrying information for resistance to antibiotics are not lost when their bacterial hosts grow in the absence of antibiotics. This is because plasmids have control systems, which ensure that on the one hand, replication of the plasmid keeps pace with the replication of its host, and on the other hand that the plasmid does not produce so many copies of itself that it overwhelms its host. This project examines the intricate regulatory system that a group of antibiotic-resistance plasmids uses to ensure that on average each plasmid molecule is replicated once per bacterial cell cycle. This system uses an antisense RNA, a tertiary RNA structure (pseudoknot) that acts as a translational switch, and a protein that interacts with different sequences on the plasmid to initiate replication. Detailed knowledge of the processes underlying this complex system is required if we are to develop new treatments that will lead to elimination of antibiotic-resistance and virulence-contributing plasmids from populations of pathogenic bacteria.Read moreRead less