Uncovering microRNA decay regulation in mammalian cells. MicroRNAs (miRNAs) constitute a novel mechanism used by cells to regulate gene expression, however, very little is known about the mechanisms affecting miRNA accumulation. Characterisation of the kinetics of miRNA turnover is of paramount importance to establish the reliability of miRNAs as novel biomarkers. This project aims to characterise miRNA stability in mammalian cells, investigate mechanisms of turnover and establish their importan ....Uncovering microRNA decay regulation in mammalian cells. MicroRNAs (miRNAs) constitute a novel mechanism used by cells to regulate gene expression, however, very little is known about the mechanisms affecting miRNA accumulation. Characterisation of the kinetics of miRNA turnover is of paramount importance to establish the reliability of miRNAs as novel biomarkers. This project aims to characterise miRNA stability in mammalian cells, investigate mechanisms of turnover and establish their importance on the regulatory function of miRNAs. Such information is critical in the future development of targeted therapeutics.Read moreRead less
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
Discovery Early Career Researcher Award - Grant ID: DE190100085
Funder
Australian Research Council
Funding Amount
$414,864.00
Summary
Elucidating a novel mechanism for coping with harmful mutations. This project aims to improve our understanding of the complex regulatory mechanisms that increase genetic and phenotypic robustness. Survival of organisms depends on their ability to cope with genetic variation. A novel process of genetic compensation has recently been identified, producing a normal phenotype in a homozygous mutant, that would be expected to have deleterious effects. This project will reveal how compensation is ach ....Elucidating a novel mechanism for coping with harmful mutations. This project aims to improve our understanding of the complex regulatory mechanisms that increase genetic and phenotypic robustness. Survival of organisms depends on their ability to cope with genetic variation. A novel process of genetic compensation has recently been identified, producing a normal phenotype in a homozygous mutant, that would be expected to have deleterious effects. This project will reveal how compensation is achieved by examining the molecular pathways that are activated following genetic mutation. This project is expected to strengthen Australian reputation in evolutionary genetics, and in turn enhance our understanding of how organisms adapt to changing environments.Read moreRead less
Genetic variation of single cell transcriptional heterogeneity in HiPSCs. This project aims to investigate whether induced pluripotent stem cells (iPSC) can be used to study the functions of genetic variants associated with human phenotypes and cell fate decisions. The project will utilise technology to produce single cell RNA sequence data for 100,000s of cells. By sequencing individual cells, the genetic control of cellular heterogeneity both within and between cells can be identified, and in ....Genetic variation of single cell transcriptional heterogeneity in HiPSCs. This project aims to investigate whether induced pluripotent stem cells (iPSC) can be used to study the functions of genetic variants associated with human phenotypes and cell fate decisions. The project will utilise technology to produce single cell RNA sequence data for 100,000s of cells. By sequencing individual cells, the genetic control of cellular heterogeneity both within and between cells can be identified, and in doing so, will provide significant benefit by revealing the potential for iPSC to be used for functional translation of human genomics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100434
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Estrogen-mediated regulation of gene expression via transcriptional and translational control: complementary, synergistic or opposing responses? Hormones dictate cellular behaviour by activating pre-programmed responses. The sex hormone estrogen affects cell fate by regulating the gene expression, but it is unknown to which extent this response occurs via activation of genes or control of already transcribed gene. The project will investigate how the cell integrates the complex estrogen signals.
How to build the head: A molecular mechanistic insight. This project aims to gain an insight into the functional output of the gene regulatory network and the molecular determinants that are critical for the formation of the head. Genome-wide sequencing technologies are employed to identify the ensemble of genes that are regulated by Lhx1. By a combination of bioinformatics analysis and a system biology approach, the project aims to build a model of the network of the interacting genes for head ....How to build the head: A molecular mechanistic insight. This project aims to gain an insight into the functional output of the gene regulatory network and the molecular determinants that are critical for the formation of the head. Genome-wide sequencing technologies are employed to identify the ensemble of genes that are regulated by Lhx1. By a combination of bioinformatics analysis and a system biology approach, the project aims to build a model of the network of the interacting genes for head development, and to characterise the function of selected components of this network to refine its architecture and define the dynamics of the network. The knowledge may improve our understanding of the molecular mechanism underpinning the naturally-occurring variation in the forms of major body parts, and of how genes and signals work cooperatively to build an embryo.Read moreRead less
3'UTR switching in eukaryotic cells. The project aims to uncover conserved features fundamental to the mechanism and function of post-transcriptional gene-expression control. RNA systems interface the executive functions of DNA and the worker functions of proteins. mRNA often dictates the level, timing and location of protein synthesis. This project will use RNA-sequencing and bespoke bioinformatics to probe global RNA-dynamics. Mixing yeast-genetics with RNA-technologies, it focuses on 3’ untra ....3'UTR switching in eukaryotic cells. The project aims to uncover conserved features fundamental to the mechanism and function of post-transcriptional gene-expression control. RNA systems interface the executive functions of DNA and the worker functions of proteins. mRNA often dictates the level, timing and location of protein synthesis. This project will use RNA-sequencing and bespoke bioinformatics to probe global RNA-dynamics. Mixing yeast-genetics with RNA-technologies, it focuses on 3’ untranslated region (UTR) dynamics in eukaryotic cell biology. This project expects to significantly advance the understanding of eukaryotic gene function and gene regulation, critical in an age of personalised genomic medicine.Read moreRead less
Molecular and cellular regulation of ovarian development. This project aims to understand cell fate decisions during ovarian development. While scientists understand the decision to differentiate into a male-specific cell type, they do not understand differentiation into female-specific cell types. This team has identified marker genes that distinguish between different female cell types in the developing ovary, and will analyse the molecular and cellular mechanisms that drive the development of ....Molecular and cellular regulation of ovarian development. This project aims to understand cell fate decisions during ovarian development. While scientists understand the decision to differentiate into a male-specific cell type, they do not understand differentiation into female-specific cell types. This team has identified marker genes that distinguish between different female cell types in the developing ovary, and will analyse the molecular and cellular mechanisms that drive the development of the ovary. This could provide a deeper understanding of how genes influence cell fate decisions during embryogenesis, and the technologies developed here will be widely applicable in biotechnological research.Read moreRead less
Chicken and ChIPs; genetic control of avian gonadal development. This project aims to improve our understanding of gonad formation at the genetic level, using unique approaches that exploit the chicken embryo as a model system. Gonad formation during embryonic life provides an excellent model for studying the genetic control of development. The project plans to use innovative methods to study novel and known gonad-determining genes. The project seeks to make a substantial contribution to our und ....Chicken and ChIPs; genetic control of avian gonadal development. This project aims to improve our understanding of gonad formation at the genetic level, using unique approaches that exploit the chicken embryo as a model system. Gonad formation during embryonic life provides an excellent model for studying the genetic control of development. The project plans to use innovative methods to study novel and known gonad-determining genes. The project seeks to make a substantial contribution to our understanding of cell fate decisions, sex determination and gonad development. It also potentially has application to the poultry industry by illuminating those genes and pathways that can be targeted to modulate sex determination in chickens, which is a goal of the industry.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101728
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
The regulation and evolution of posttranscriptional gene networks. The ability of cells to regulate gene expression is key for organism development, adaptation to new environments and evolutionary changes that shape the diversity of life on Earth. This project studies the RNA binding proteins called PUFs which are central for gene expression in diverse organisms. Using cutting-edge new generation systems biology approaches, this project will study how PUF proteins regulate genes to enable metabo ....The regulation and evolution of posttranscriptional gene networks. The ability of cells to regulate gene expression is key for organism development, adaptation to new environments and evolutionary changes that shape the diversity of life on Earth. This project studies the RNA binding proteins called PUFs which are central for gene expression in diverse organisms. Using cutting-edge new generation systems biology approaches, this project will study how PUF proteins regulate genes to enable metabolic adaptation, differentiation of cell types and the evolution of new gene expression outputs in distinct biological species. The outcomes will include new insights into the regulation and evolution of posttranscriptional gene networks. Read moreRead less