Nuclear Retention-and-release Of RNA: A Naturally-occurring Mechanism For Controlling Gene Expression
Funder
National Health and Medical Research Council
Funding Amount
$428,753.00
Summary
The deliberate retention of messenger RNA in the nucleus is a newly-discovered biological mechanism used by cells to control which genes are made into proteins, and when. This is a fundamental process in health and disease. The project will employ cutting edge molecular and cellular techniques to discover the principles underpinning nuclear retention. These insights will allow the development of new methods to spatially and temporally control gene expression in diverse gene therapy applications.
Molecular Insights Into Long Noncoding RNA-protein Complexes: Important Gene Regulators In Cancer
Funder
National Health and Medical Research Council
Funding Amount
$388,927.00
Summary
Cancer cells turn good genes off and bad ones on: but how do they do this? Recent breakthroughs suggest that noncoding RNA, produced from so-called ‘junk’ DNA, is important. One such noncoding RNA forms paraspeckles, a novel component of the cell machinery. Here, we will pick apart the way paraspeckles are organised and function, to develop them as a prototype for designing anti-cancer treatments against noncoding RNAs.
Structural domains of beta-tubulin and their role in microtubule dynamics and transport. This study aims to obtain a fundamental understanding of how the structural domains of the cytoskeletal protein beta-tubulin are involved in microtubule structures during cell division and vesicular transport. Using gene-editing technology and coupling this with cell biological approaches and high-resolution cell imaging will enable detailed analysis of the role of beta-tubulin domains in these important cel ....Structural domains of beta-tubulin and their role in microtubule dynamics and transport. This study aims to obtain a fundamental understanding of how the structural domains of the cytoskeletal protein beta-tubulin are involved in microtubule structures during cell division and vesicular transport. Using gene-editing technology and coupling this with cell biological approaches and high-resolution cell imaging will enable detailed analysis of the role of beta-tubulin domains in these important cellular processes. The outcomes will include fundamental new knowledge in cell biology and lead to the development of unique biological models that can be used to understand disease.Read moreRead less
Post-GWAS Functional Characterisation Of Breast Cancer Susceptibility Loci
Funder
National Health and Medical Research Council
Funding Amount
$764,632.00
Summary
Recent studies have identified regions within the human genome in which DNA sequence variations are associated with an increased risk of breast cancer. Several of these regions do not contain any known genes, suggesting that regulatory DNA sequences are responsible for the associated risk. The aim of this proposal is to identify and characterise these DNA sequences. Understanding how sequences variations in these regions contribute to breast cancer will provide novel avenues for therapy.
H2A.Z Acetylation: Deregulation Of Enhancer Activity And 3D Chromatin In Prostate Cancer
Funder
National Health and Medical Research Council
Funding Amount
$859,350.00
Summary
DNA is not linear but packaged in the cell nucleus in a three-dimensional (3D) structure in such a way that distal regulatory regions can interact to control gene expression. Our new data suggests that a chemical modification of the histone variant H2A.Z plays a critical role in the formation of the 3D chromatin structure. This project is aimed to dissect the role of H2A.Z in prescribing 3D structure, which will provide a more precise understanding of gene deregulation in cancer.
Identifying Novel Long-noncoding RNAs Involved In The Development Of Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$785,204.00
Summary
Recent studies have identified regions within the human genome in which DNA sequence variations are associated with an increased risk of breast cancer. The aim of this proposal is to identify and characterise these non-coding genes that are modulate breast cancer risk. Understanding how sequences variations that alter these novel genes contribute to breast cancer will provide novel avenues for therapy.
High-Throughout Identification And Targeting Of New Breast Cancer Genes.
Funder
National Health and Medical Research Council
Funding Amount
$640,210.00
Summary
Recent studies have identified DNA sequence variations within the human genome that are associated with an increased risk or can influence the outcome of breast cancer. This research program will identify the key genes affecting cancer development and assess their contribution to cancer growth. I will then use this knowledge to assess their suitability for drug development. Understanding how our DNA contributes to breast cancer will provide new avenues for prevention or treatment.
Clinical Classification Of Regulatory Variants In Breast Cancer Susceptibility Genes
Funder
National Health and Medical Research Council
Funding Amount
$536,966.00
Summary
Variations in our genes can confer a risk of diseases including breast cancer. Determining the clinical significance of these variations is a major and increasing challenge for genetic counselors and clinicians. This project will evaluate the clinical significance of variants in the control regions of breast cancer susceptibility genes. This research will inform the development of guidelines for interpreting such variants in a clinical setting.
Functional Analysis Of Breast Cancer Susceptibility Regions
Funder
National Health and Medical Research Council
Funding Amount
$790,588.00
Summary
Recent studies have identified regions within the human genome in which DNA sequence variations are associated with an increased risk of breast cancer. Several of these regions do not contain any known genes, suggesting that regulatory DNA sequences are responsible for the associated risk. The aim of this proposal is to identify and characterise these DNA sequences. Understanding how sequences variations in these regions contribute to breast cancer will provide novel avenues for therapy.