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Kruppel-like factors and the methylome. This project aims to test the hypothesis that the KLF/SP family of transcription factors work in part via dynamic interactions with methylated cytosine nucleotides in DNA. This is fundamental to their function as pioneer factors in reprograming and their ability to co-ordinate differentiation and organogenesis. Conversely, dynamic changes in methylation status engage or disengage new regulatory elements in the genome via recruitment of KLF/SP family protei ....Kruppel-like factors and the methylome. This project aims to test the hypothesis that the KLF/SP family of transcription factors work in part via dynamic interactions with methylated cytosine nucleotides in DNA. This is fundamental to their function as pioneer factors in reprograming and their ability to co-ordinate differentiation and organogenesis. Conversely, dynamic changes in methylation status engage or disengage new regulatory elements in the genome via recruitment of KLF/SP family proteins as specific effectors. This project will address a new paradigm in genetics that is likely to underpin development.Read moreRead less
A multi-model approach to characterise conserved regulators of lymphatic vascular development. Lymphatic vessels are important in a number of diseases affecting Australia. There is a significant gap in our basic knowledge of how lymphatic vessels form. This study will characterise key genes that control lymphatic development, providing a base of knowledge contributing to the promotion and maintenance of good health in Australia.
Evolution of nervous system patterning processes: characterisation of homologs of key Drosophila regulatory genes from the coral Acropora. Defining the common mechanisms of nervous system development is one of the major goals of modern biology, but is presently being addressed largely by comparisons between a few very advanced (and therefore specialised) animals. Comparative data from a lower animal is urgently needed, and will clarify many aspects of nervous system evolution and development. Th ....Evolution of nervous system patterning processes: characterisation of homologs of key Drosophila regulatory genes from the coral Acropora. Defining the common mechanisms of nervous system development is one of the major goals of modern biology, but is presently being addressed largely by comparisons between a few very advanced (and therefore specialised) animals. Comparative data from a lower animal is urgently needed, and will clarify many aspects of nervous system evolution and development. The pioneering work carried out on Acropora in this laboratory suggests that it is perhaps the best choice currently available for this purpose. This project will use Acropora to address fundamental questions about the evolution of nervous system developmental processes.Read moreRead less
Deciphering the genetic architecture of human complex traits. This project aims to develop statistical methods to integrate data from genetic studies of complex traits such as stature and cognition. Molecular phenotypes such as gene expression in large samples will be used to predict target genes and regulatory elements of those traits. Understanding the genetic basis of human complex traits is critical to longstanding questions in human and evolutionary biology. The project will also detect sig ....Deciphering the genetic architecture of human complex traits. This project aims to develop statistical methods to integrate data from genetic studies of complex traits such as stature and cognition. Molecular phenotypes such as gene expression in large samples will be used to predict target genes and regulatory elements of those traits. Understanding the genetic basis of human complex traits is critical to longstanding questions in human and evolutionary biology. The project will also detect signatures of natural selection in shaping the genetic variation in complex traits. The project will provide better understanding of complex traits in global populations and the history of human evolution, and will develop methods applicable in plant and animal contexts.Read moreRead less
Molecular definition of cellular states in the vascular endothelium. The endothelium is the main cell type forming blood vessels and spans across multiple cell states from stem/progenitor to a variety of terminally differentiated cells. How each of these cell states are defined at the molecular level is not known preventing the optimal formation and integration of blood vessels in bioengineered tissues. Using innovative single cell gene expression and chromatin accessibility studies combined wit ....Molecular definition of cellular states in the vascular endothelium. The endothelium is the main cell type forming blood vessels and spans across multiple cell states from stem/progenitor to a variety of terminally differentiated cells. How each of these cell states are defined at the molecular level is not known preventing the optimal formation and integration of blood vessels in bioengineered tissues. Using innovative single cell gene expression and chromatin accessibility studies combined with innovative analysis, we propose to define and validate each cell state at the molecular level.
This new knowledge would greatly enhance our ability to control the transition between cell states leading to a more widespread use of endothelial cells in bioengineering of tissues globally for many applications.
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The characterization of tiny Ribonucleic acids in animal epigenetics. Epigenetics, the inheritance of traits not encoded in deoxyribonucleic acid (DNA), is not well understood in animals. This project will investigate two classes of Ribonucleic acid (RNA) that may form part of an animal-specific epigenetic regulatory system. This study could revolutionize our understanding of animal genetics.
Discovery Early Career Researcher Award - Grant ID: DE150100652
Funder
Australian Research Council
Funding Amount
$345,000.00
Summary
Regulation of organ size and stem cell hierarchy in the developing kidney. Transient stem/progenitor cell populations play essential roles in establishing organ systems. The balance between self-renewal and differentiation in the nephron progenitor population plays a major, but poorly understood, role in regulating kidney development. Factors produced by undifferentiated progenitors promote organ expansion, whereas differentiation of these cells builds functional capacity. What is not clear is h ....Regulation of organ size and stem cell hierarchy in the developing kidney. Transient stem/progenitor cell populations play essential roles in establishing organ systems. The balance between self-renewal and differentiation in the nephron progenitor population plays a major, but poorly understood, role in regulating kidney development. Factors produced by undifferentiated progenitors promote organ expansion, whereas differentiation of these cells builds functional capacity. What is not clear is how the balance between self-renewal and differentiation is regulated in these cells, nor how the control of this fate decision impacts on optimal organ development. This project aims to dissect the molecular identity, regulation, and influence of this stem cell population on kidney development.Read moreRead less
Characterising inheritance patterns of whole genome DNA methylation. This project aims to characterise epigenetic diversity and inheritance patterns in whole genome sequencing data from a unique human population. The project will employ the well-characterised Norfolk Island genetic isolate, cost-effective whole genome bisulphite sequencing technologies and advanced bioinformatics pipelines and statistical models. It will involve cross-discipline collaboration between human geneticists, epigeneti ....Characterising inheritance patterns of whole genome DNA methylation. This project aims to characterise epigenetic diversity and inheritance patterns in whole genome sequencing data from a unique human population. The project will employ the well-characterised Norfolk Island genetic isolate, cost-effective whole genome bisulphite sequencing technologies and advanced bioinformatics pipelines and statistical models. It will involve cross-discipline collaboration between human geneticists, epigeneticists, statistical geneticists and bioinformaticians. This project will advance our understanding of the interaction of genetics and epigenetics and their relationship to diversity and inheritance in humans.Read moreRead less
Origin of multicellularity in animals: identification and analysis of intercellular signalling pathways in a basal metazoan, the demosponge Reniera. The Reniera genome project is a multi-million dollar collaboration between JGI (US-DOE) and Australian scientists that will see the sequencing of the first Australian marine animal by 2006. This project will significantly advance our understanding of the origins of animals and contribute to the reconstruction of creatures that lived over 600 million ....Origin of multicellularity in animals: identification and analysis of intercellular signalling pathways in a basal metazoan, the demosponge Reniera. The Reniera genome project is a multi-million dollar collaboration between JGI (US-DOE) and Australian scientists that will see the sequencing of the first Australian marine animal by 2006. This project will significantly advance our understanding of the origins of animals and contribute to the reconstruction of creatures that lived over 600 million years ago. A major outcome of this reconstruction will be a fundamental understanding of how cells communicate with each other during the process of development to give rise to the diversity of cell types within multicellular animals. This study will also shed light on what happens when cell communication goes astray, as observed in a range of human malignancies, including cancer. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100036
Funder
Australian Research Council
Funding Amount
$465,803.00
Summary
Tracing the epigenetic life-history of cells. Each cell of the human body contains identical genetic information that is activated in different ways to form varied cell types. This research aims to develop novel single-cell genomic technologies to explain the origins of different cell types. This project expects to discover the molecular mechanisms through which specialised cell types are formed, which has been difficult to decipher using existing methods. My novel approach will elucidate how a ....Tracing the epigenetic life-history of cells. Each cell of the human body contains identical genetic information that is activated in different ways to form varied cell types. This research aims to develop novel single-cell genomic technologies to explain the origins of different cell types. This project expects to discover the molecular mechanisms through which specialised cell types are formed, which has been difficult to decipher using existing methods. My novel approach will elucidate how a small population of seemingly homogenous cells can give rise to a myriad of types of cells. Tracing the life histories of cells across time should lead to broad applications including in developmental biology, neuroscience and immunology.Read moreRead less