Genomic Characterisation Of Asbestos Related Lung Cancer
Funder
National Health and Medical Research Council
Funding Amount
$88,099.00
Summary
Lung cancer causes more deaths in Australia than any other cancer. Smoking is the main cause, but people exposed to asbestos are also at risk, and it can be difficult to know whether a case is due to tobacco, asbestos or both. We will study lung cancer genes in people with asbestos exposure to find whether asbestos lung cancer has a specific pattern of abnormal genes (signature). If so, this could help people entitled to compensation, and also point to new treatments for asbestos lung cancer
Investigation Of The Anticancer Action And Cytotoxic-synergism Of Matrix Metalloproteinase Inhibition.
Funder
National Health and Medical Research Council
Funding Amount
$272,036.00
Summary
In virtually all cases, death from solid tumors (including breast cancer) results from invasion and metastasis. The exciting recent pre-clinical observations that a new class of anticancer agents (which primarily target tumour invasion and metastasis) operate synergistically with a number of standard chemotherapy cytotoxics (such as those already used to treat breast cancer) suggests a new and significant additional therapeutic potential for both agents. The basis of this synergism is completely ....In virtually all cases, death from solid tumors (including breast cancer) results from invasion and metastasis. The exciting recent pre-clinical observations that a new class of anticancer agents (which primarily target tumour invasion and metastasis) operate synergistically with a number of standard chemotherapy cytotoxics (such as those already used to treat breast cancer) suggests a new and significant additional therapeutic potential for both agents. The basis of this synergism is completely unknown however, and it is our contention that this mechanism needs to be explored at the molecular level in order to identify which combinations will have most potential in the clinic. This proposal aims to characterize synergistic combinations in an animal model of breast cancer progression, and to determine the specific molecular mechanism of the process. Each phase of the proposed study is a worthwhile undertaking in itself, and while it makes primary use of a breast cancer growth and metastasis system, the information revealed should be relevant to many tumour types. This information can be used to formulate new therapeutic strategies for the treatment of solid tumours and their metastasis in patients.Read moreRead less
Translational Control Of Gene Expression And The Choice Between Cell Death And Proliferation
Funder
National Health and Medical Research Council
Funding Amount
$378,000.00
Summary
Proteins carry out most enzymatic and structural functions in a cell. Thus, the kinds of protein molecules that are found in a given cell determine its characteristics and cells respond to changes in their environment by adjusting the abundance of some or many proteins in their collection. The instructions for the assembly of proteins are encoded in the genes and this information is expressed via intermediary molecules called messenger (m)RNA. Both, transcription of the genes into mRNA molecules ....Proteins carry out most enzymatic and structural functions in a cell. Thus, the kinds of protein molecules that are found in a given cell determine its characteristics and cells respond to changes in their environment by adjusting the abundance of some or many proteins in their collection. The instructions for the assembly of proteins are encoded in the genes and this information is expressed via intermediary molecules called messenger (m)RNA. Both, transcription of the genes into mRNA molecules and their subsequent translation by the ribosomes into protein are tightly controlled steps in the gene expression pathway. Erroneous gene expression is a major factor in human disease and dysregulation of translation is linked to a growing spectrum of illnesses such as cancer and cardiovascular disease, viral infection, and less frequent hereditary syndromes. The project proposed here is prompted by emerging evidence for a role of translational regulation in controlling the balance between cell death and survival. Tipping this balance has disastrous consequences for an organism as evidenced by its involvement in many major disorders (e. g. stroke, heart failure, neurodegeneration, AIDS, cancer, autoimmunity). Our aim is to test the hypothesis that a putative translational regulator termed p97-DAP5-NAT1, and a specialised mechanism of translation initiation by internal ribosome entry are important for the maintenance of this balance. To investigate this, we will employ DNA chips, a novel tool from Genomics research that allows the measurement of the levels of thousands of mRNA molecules in a single experiment. It is conceivable that knowledge of these special mechanisms of translation will lead to novel targets for therapeutic intervention, and this work will contribute some of the experimental tools to explore these avenues in the future.Read moreRead less
I am a molecular biologist determining the mechanisms of eukaryotic mRNA translation and its regulation by RNA-binding proteins and noncoding RNA. In collaborative work I extend these basic science objectives into the medical research areas of cardiology
The transcriptional co-repressor C-terminal Binding Protein (CtBP) in metabolic control. This project will provide insights into the genes that regulate the storage of fat. We will learn about basic biology but will also discover mechanisms that may be used to influence fat storage in human health. We will also consolidate Australia's expertise in the use of the genetic model organism, the worm C. elegans, and validate the findings in mammalian systems. Finally, the process of training young sci ....The transcriptional co-repressor C-terminal Binding Protein (CtBP) in metabolic control. This project will provide insights into the genes that regulate the storage of fat. We will learn about basic biology but will also discover mechanisms that may be used to influence fat storage in human health. We will also consolidate Australia's expertise in the use of the genetic model organism, the worm C. elegans, and validate the findings in mammalian systems. Finally, the process of training young scientists in these modern systems, will also equip future researchers to make additional contributions to Australia's research output.Read moreRead less
RNA splicing: factors and mechanisms. Most primary gene transcripts must have their noncoding intronic sequences spliced out before the mRNA can be translated. Moreover, alternative splicing enables cells to generate a far more proteins than there are genes in the nucleus. Based on our proven success with ZNF265 we will isolate novel RNA interactors and their partners, colocalize these in intranuclear compartments, and elucidate their effect on pre-mRNA splicing. This will provide timely spin-of ....RNA splicing: factors and mechanisms. Most primary gene transcripts must have their noncoding intronic sequences spliced out before the mRNA can be translated. Moreover, alternative splicing enables cells to generate a far more proteins than there are genes in the nucleus. Based on our proven success with ZNF265 we will isolate novel RNA interactors and their partners, colocalize these in intranuclear compartments, and elucidate their effect on pre-mRNA splicing. This will provide timely spin-offs to the Human genome Project and EST sequence information, where the finding of only approx. 30,000 genes in our genome highlights the important role of alternative splicing in generating the large proteome repertoire of cells. This will bring considerable benefits to science, society, and the biotech industry.Read moreRead less
Genetic dissection of a regulatory deubiquitlyation network. The potential impact of this work is widespread, because although it is known that ubiquitlyation has regulatory consequences in multicellular eukaryotes, individual networks have not been completely described in higher eukaryotes. Knowledge gained about fundamental processes in the A. nidulans model system is directly applicable to fungi used in biotechnology in the food, beverage, enzyme and pharmaceutical production industries, and ....Genetic dissection of a regulatory deubiquitlyation network. The potential impact of this work is widespread, because although it is known that ubiquitlyation has regulatory consequences in multicellular eukaryotes, individual networks have not been completely described in higher eukaryotes. Knowledge gained about fundamental processes in the A. nidulans model system is directly applicable to fungi used in biotechnology in the food, beverage, enzyme and pharmaceutical production industries, and to fungal pathogens. Since the fungal genes that form the basis of this project are conserved in higher eukaryotes including humans, the knowledge will be transferable to these systems. A further benefit that cannot be overstated is the research education and training opportunities provided.
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A new mechanism of gene regulation. This project will advance our knowledge of how genes are switched on and off, by focusing on a very common class of gene regulatory proteins known as zinc finger proteins. The results of this study will improve our understanding of the fundamental molecular events that underpin gene regulation and how we might control it in fields such as biotechnology and gene therapy.
New mechanisms of DNA recognition by zinc-finger domains. The work described in this proposal carries long-term benefits to the health of Australians. Many debilitating diseases, including many varieties of cancer, arise as a result of a breakdown in the normal regulation of gene transcription. It is only once we have a thorough understanding of transcriptional regulation in normal organisms that we will be in a position to devise effective therapies to deal with the disorders that result from a ....New mechanisms of DNA recognition by zinc-finger domains. The work described in this proposal carries long-term benefits to the health of Australians. Many debilitating diseases, including many varieties of cancer, arise as a result of a breakdown in the normal regulation of gene transcription. It is only once we have a thorough understanding of transcriptional regulation in normal organisms that we will be in a position to devise effective therapies to deal with the disorders that result from aberrant gene expression. Our proposed research program also provides the opportunity to train younger scientists in state-of-the-art molecular and structural biology, thus representing a significant national benefit. Read moreRead less