Old genes learning new tricks: characterising regulatory changes driving increased heart complexity during vertebrate evolution. The heart has dramatically increased in morphological complexity during vertebrate evolution but the molecular basis driving these major changes remains unknown. Using comparative genomics approaches, this project will explore changes in the regulation of genes involved in heart formation that lead to changes in cardiac structure. It will elucidate for the first time t ....Old genes learning new tricks: characterising regulatory changes driving increased heart complexity during vertebrate evolution. The heart has dramatically increased in morphological complexity during vertebrate evolution but the molecular basis driving these major changes remains unknown. Using comparative genomics approaches, this project will explore changes in the regulation of genes involved in heart formation that lead to changes in cardiac structure. It will elucidate for the first time the cardiac regulatory repertoire in zebrafish and will compare it with that of fly and mouse using cutting-edge bioinformatics pipelines. This work will unravel cardiac-specific regulatory modifications that give rise to evolutionary changes. On a broader scale, it will shed new light on the role of regulatory innovations over gene innovations in the emergence of new traits.Read moreRead less
Developing the Dunnart as a Model Species for Marsupial Research. The project aims to develop a marsupial model capable of genome manipulations to take our understanding of marsupial biology to the next level. In doing so, the project would produce the first comprehensive transcriptome data defining early cell lineage specification in a marsupial. Combined with similar data from mouse and human, it would enable us to examine diversity in early mammals. In addition, it would identify cohorts of g ....Developing the Dunnart as a Model Species for Marsupial Research. The project aims to develop a marsupial model capable of genome manipulations to take our understanding of marsupial biology to the next level. In doing so, the project would produce the first comprehensive transcriptome data defining early cell lineage specification in a marsupial. Combined with similar data from mouse and human, it would enable us to examine diversity in early mammals. In addition, it would identify cohorts of genes with fundamental roles in differentiation of the earliest cell lineages: trophoblast, pluriblast and hypoblast. The project may identify maternally localised transcripts with a marsupial-specific role in trophoblast–pluriblast specification, giving new insights into the fundamental pathways maintaining pluripotency in mammals and the evolution of the mammalian genome.Read moreRead less
Genome-wide Analysis Of Gene Regulatory Networks In Heart Development And Congenital Heart Disease
Funder
National Health and Medical Research Council
Funding Amount
$1,263,954.00
Summary
Despite advances in surgical methods and hospital critical care, congenital heart disease (CHD) remains the leading cause of non-infectious death in children in the first year of life. Severe CHD requires multiple surgeries and a lifetime of emotional and financial burden. In this proposal we will use new molecular and genetic approaches to ask how the network of genes that normally participates in heart development is controlled by regulatory factors, and how the network is disturbed in CHD.
Probing The Cardiac Gene Regulatory Network In Development And Congenital Heart Disease
Funder
National Health and Medical Research Council
Funding Amount
$518,118.00
Summary
In Australia, congenital heart disease (CHD) is the biggest killer of children under 5 years. Defects range from small holes to severe malformations requiring multiple surgeries and an uncertain future. Our appreciation of CHD mechanism is limited. Using cutting-edge technologies in genomics, biophysics and structural biology, we will study the mechanisms that lead to CHD at unprecedented resolution. Our project will progress the concept of personalized diagnosis and treatment of CHD.
Regulatory architecture of the trunk-to-tail transition. This project aims to elucidate gene regulatory mechanisms that control how the head-to-tail axis is laid down during embryonic development. The project capitalises on unique pluripotent stem cell resources and cutting-edge genomic technology developed by the team. This project expects to generate new knowledge in the area of developmental biology and gene regulation that is anticipated to have wider application to the understanding of evol ....Regulatory architecture of the trunk-to-tail transition. This project aims to elucidate gene regulatory mechanisms that control how the head-to-tail axis is laid down during embryonic development. The project capitalises on unique pluripotent stem cell resources and cutting-edge genomic technology developed by the team. This project expects to generate new knowledge in the area of developmental biology and gene regulation that is anticipated to have wider application to the understanding of evolutionary mechanisms and ultimately regenerative medicine.Read moreRead less
Deciphering the regulatory principles of metazoan development. This proposal aims to elucidate how regulatory elements in the genome, known as enhancers, determine the identity and function of animal tissues. Currently, it is believed that enhancers cannot be traced across evolutionarily distant animals. The project uses novel concepts, computational and molecular approaches to identify deeply conserved enhancers. It further dissects the mechanism of function by proteomics and high-throughput ge ....Deciphering the regulatory principles of metazoan development. This proposal aims to elucidate how regulatory elements in the genome, known as enhancers, determine the identity and function of animal tissues. Currently, it is believed that enhancers cannot be traced across evolutionarily distant animals. The project uses novel concepts, computational and molecular approaches to identify deeply conserved enhancers. It further dissects the mechanism of function by proteomics and high-throughput genomics. The expected outcomes will overturn our current view on enhancer evolution and reposition our understanding of how enhancers are functionally encoded in the genome. The work is an important contribution to understanding cellular complexity and species evolution with wide-ranging impact in genetics.Read moreRead less
Visualising genetic mosaicism during development. Genetic diversity is the variation in DNA sequence among individuals. We now know that there are also differences in the DNA sequences of cells within the same individual, known as genetic mosaicism. The aims of this proposal are 1) to develop a system to visualise genetic mosaicism 2) arising during embryonic development and 3) in the brain, driven by mobile DNA activity. The expected outcome of this proposal is an unprecedented understanding of ....Visualising genetic mosaicism during development. Genetic diversity is the variation in DNA sequence among individuals. We now know that there are also differences in the DNA sequences of cells within the same individual, known as genetic mosaicism. The aims of this proposal are 1) to develop a system to visualise genetic mosaicism 2) arising during embryonic development and 3) in the brain, driven by mobile DNA activity. The expected outcome of this proposal is an unprecedented understanding of the scope and consequences of mobile DNA-driven mosaicism. This work will have significant impacts in developmental genetics and neurogenetics, and has the benefit of introducing an innovative experimental system with the potential to spark international scientific collaboration and recognition.Read moreRead less
Early evolution of the endomesoderm gene regulatory network. This project aims to unravel the endomesoderm gene network’s evolutionary history by identifying its conserved components’ target genes in the calcareous sponge Sycon. Little is known about the evolutionary origin of the developmental gene regulatory networks active in the development of all Eumetazoans (animals with nerves and digestive systems). Sponges are key models to study the transition from protists to eumetazoans, and gene exp ....Early evolution of the endomesoderm gene regulatory network. This project aims to unravel the endomesoderm gene network’s evolutionary history by identifying its conserved components’ target genes in the calcareous sponge Sycon. Little is known about the evolutionary origin of the developmental gene regulatory networks active in the development of all Eumetazoans (animals with nerves and digestive systems). Sponges are key models to study the transition from protists to eumetazoans, and gene expression data supports homology between sponge and eumetazoan tissues and body plans. This project could illuminate the evolutionary history of the animal body plan.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100755
Funder
Australian Research Council
Funding Amount
$371,000.00
Summary
Evolution of genome architecture. The project aims to understand how changes to genome architecture over evolutionary time are linked to the diversity of animal morphology. Our genome sequence is arranged into higher order structures that enable coordinated gene expression. The appropriate expression of genes in time and space is necessary to produce the multitude of cell types that make up a multicellular organism. Yet, to date, genome topology is poorly explored, especially between species. Th ....Evolution of genome architecture. The project aims to understand how changes to genome architecture over evolutionary time are linked to the diversity of animal morphology. Our genome sequence is arranged into higher order structures that enable coordinated gene expression. The appropriate expression of genes in time and space is necessary to produce the multitude of cell types that make up a multicellular organism. Yet, to date, genome topology is poorly explored, especially between species. The project involves comparisons of the 3D structure of genomes in divergent species. These findings are expected to inform the underlying principles of gene regulation in animals and species evolution.Read moreRead less
Defining how molecular switches program cell identity during development. Aims: This project aims to investigate how molecular switches known as transcription factors, work together to turn genes on or off to program cell identity during development.
Significance: This project expects to generate new knowledge in the area of genetics and developmental biology using collaborative, cutting edge technologies.
Outcomes: Expected outcomes of this project include the identification of new genes impor ....Defining how molecular switches program cell identity during development. Aims: This project aims to investigate how molecular switches known as transcription factors, work together to turn genes on or off to program cell identity during development.
Significance: This project expects to generate new knowledge in the area of genetics and developmental biology using collaborative, cutting edge technologies.
Outcomes: Expected outcomes of this project include the identification of new genes important for programming the identity of cells that comprise our blood vessels, lymphatic vessels and circulating blood cells.
Benefits: Data generated will underpin the development of approaches to program/reprogram stem cells to produce mature cells for transplantation or tissue engineering purposes ex vivo.Read moreRead less