Discovery Early Career Researcher Award - Grant ID: DE190100116
Funder
Australian Research Council
Funding Amount
$415,737.00
Summary
Cell types and cell states revealed by single-cell regulatory networks. This project aims to use single-cell gene regulation networks to predict cell types. Computational approaches are needed to recapitulate how the over 37 trillion cells program the shared genome sequence in a human body to create astoundingly diverse forms and functions. This project integrates millions of high-resolution single-cell gene expression profiles with large-scale population regulatory data to systematically recons ....Cell types and cell states revealed by single-cell regulatory networks. This project aims to use single-cell gene regulation networks to predict cell types. Computational approaches are needed to recapitulate how the over 37 trillion cells program the shared genome sequence in a human body to create astoundingly diverse forms and functions. This project integrates millions of high-resolution single-cell gene expression profiles with large-scale population regulatory data to systematically reconstruct gene regulatory networks. These networks are the molecular basis for understanding human cells. This projects outcomes intend to include the first reference single-cell regulatory database and novel methods and software to predict individual cells. This project will contribute to advancing Australia's capabilities in single-cell, precision medicine, and big biological data analysis leading to significant scientific, societal and commercial benefits.Read moreRead less
Understanding protein-nucleic-acid interaction networks in cold-adapted archaea. The aim of this project is to learn how microorganisms can function effectively in naturally cold environments. Results will determine how important cellular processes occur when microorganisms grow in the cold, and hence why they are able to maintain a natural balance in ecosystems such as Antarctica.
Application Of Next Generation Sequencing To Address Clinical Problems In Cancer
Funder
National Health and Medical Research Council
Funding Amount
$463,652.00
Summary
Cancer is the cause of 1 in 8 deaths worldwide. Cancer occurs due to errors or mutations in the DNA of normal cells. The mutations may cause the cells to grow incorrectly and become cancer. I will identify the mutations or errors in tumour cells. This will tell us: i) How the tumour started and continued to grow ii) How to treat the tumour cells to kill the cancer The work will involve a variety of cancer types including mesothelioma, melanoma, oesophageal, pancreatic and breast cancer.
Silencing the X chromosome: why and how. The project aims to understand why we have X chromosome inactivation, and examine the fundamental molecular mechanisms of how it is achieved. The project will explore RNA-mediated epigenetic modification of whole chromosomes with innovative molecular methods in placental mammals, and also iconic Australian mammals, to transform our understanding of X chromosome inactivation. Further understanding whole chromosome silencing, will inform future research int ....Silencing the X chromosome: why and how. The project aims to understand why we have X chromosome inactivation, and examine the fundamental molecular mechanisms of how it is achieved. The project will explore RNA-mediated epigenetic modification of whole chromosomes with innovative molecular methods in placental mammals, and also iconic Australian mammals, to transform our understanding of X chromosome inactivation. Further understanding whole chromosome silencing, will inform future research into potential therapies for chromosomal trisomies.Read moreRead less
LINEs Of Mutagenesis, Selection And Evolution In Ovarian Cancer And Chemoresistance
Funder
National Health and Medical Research Council
Funding Amount
$425,048.00
Summary
L1 elements are powerful mutagens encoded within the human genome that becomes active in epithelial tumours. I will define the broad effects of L1 elements on the evolution of chemoresistance, focusing on ovarian cancer as a model system. Ovarian cancer is characterised by a poor 5 year survival rate of ~40% with most tumours developing resistance. Understanding the impacts of L1 on this evolution will inform the development and selection of more effective treatments for ovarian cancer.
An Indigenous Australian Reference Genome: Indigenous Inclusion In The Benefits Of Genomic Medicine
Funder
National Health and Medical Research Council
Funding Amount
$1,428,508.00
Summary
This project will establish an Indigenous Australian reference genome (the NCIGrg) within the National Centre for Indigenous Genomics (NCIG) using advanced genome sequencing technologies and data analytics and evaluate its research and clinical utility. The NCIGrg will be cornerstone of future genomic research and its clinical application in Indigenous communities. It will underpin NCIG’s commitment to ensuring that Indigenous Australians are included in the benefits of genomic medicine.
Evaluation of Bacillus amyloliquefaciens H57 as a probiotic in livestock using animal nutrition studies and metagenomics. To improve animal production, gene sequencing will unravel how microbial communities in the rumen of sheep and cattle and the gastro intestinal tract of poultry respond to feed quality and probiotic bacteria. The animal nutrition trials will also measure weight gain and feed utilisation efficiency, particularly for nitrogen, protein and energy.
Characterising The Molecular Basis Of Cystic Kidney Diseases Using Kidney Organoids Created By Directed Differentiation Of Patient-derived, Induced Pluripotent Stem Cells.
Funder
National Health and Medical Research Council
Funding Amount
$122,714.00
Summary
Inherited genetic mutations cause almost half of chronic kidney diseases in children. In most cases we do not know what the mutation is or how it causes kidney disease. In this study we will turn skin cells from children with kidney disease into stem cells and then use these to make a mini-kidney in a dish. This will act as a model of kidney disease allowing us to understand what the problem is at the level of changes within the cells. This may result in new ways of treating kidney disease.
Genomics of temperature response in plants. Climate change is predicted to have negative impacts on Australian agriculture. This project will use genomic tools to uncover biological mechanisms for plant response to temperature that will help design crop varieties that are more tolerant to higher temperatures.
The role of non-coding RNAs in T cell development. The goal of this project is to discover the genes responsible for the development of a healthy immune system. To achieve this goal, a battery of next generation genomics technologies are being applied for the discovery of new genes and to study their function.