How is the blood cell population size controlled? Macrophage-like cells are an ancient animal blood cell lineage critically important for development, immunity, and homeostasis. This fellowship seeks to reveal the genes and control mechanisms used by animals to achieve an optimally-sized army of these cells - to contain threats for survival upon infection, heal following acute stress exposures, or for development, ongoing maintenance, and repair of wear and tear. By marrying the genetic tractabi ....How is the blood cell population size controlled? Macrophage-like cells are an ancient animal blood cell lineage critically important for development, immunity, and homeostasis. This fellowship seeks to reveal the genes and control mechanisms used by animals to achieve an optimally-sized army of these cells - to contain threats for survival upon infection, heal following acute stress exposures, or for development, ongoing maintenance, and repair of wear and tear. By marrying the genetic tractability of the model organism Drosophila and its simple, yet conserved blood cell system, this project will yield new insights into the mechanisms that govern the animal blood cell population. This will benefit our fundamental understanding of how animals maximise their health throughout life.Read moreRead less
Using mouse genetics to understand skin development and cell biology. During embryonic development the skin forms a protective barrier which permits life outside the womb and provides a window into the biology of cells. This project aims to use the skin to identify and characterise genes necessary for embryonic development and maintenance, the development of diseases and to explore their broader roles in other organs.
The transcriptional control of lymphatic vessel development. Lymphatic vessels are a vital, but often overlooked, component of the cardiovascular system. These specialised vessels return tissue fluid to the bloodstream, absorb dietary lipids and transport cells of the immune system throughout the body. Defects in the growth and development of lymphatic vessels result in disorders including lymphedema, obesity, inflammatory diseases and cancer. This project aims to define how transcription factor ....The transcriptional control of lymphatic vessel development. Lymphatic vessels are a vital, but often overlooked, component of the cardiovascular system. These specialised vessels return tissue fluid to the bloodstream, absorb dietary lipids and transport cells of the immune system throughout the body. Defects in the growth and development of lymphatic vessels result in disorders including lymphedema, obesity, inflammatory diseases and cancer. This project aims to define how transcription factors program lymphatic vessel identity and control the development of lymphatic vessel valves. This knowledge will provide new insight into the fundamental mechanisms by which the lymphatic vasculature is constructed during development.Read moreRead less
Genetic control of tissue growth in animals. This project aims to understand how the animal body grows. This project expects to generate new knowledge and understanding of the genetic programs that govern the size and shape of animal tissues, through use of cutting-edge genome editing approaches in laboratory animals. Expected outcomes of this project include the production of genetically engineered animals with altered tissue growth, development of new theories for how tissue growth is normal ....Genetic control of tissue growth in animals. This project aims to understand how the animal body grows. This project expects to generate new knowledge and understanding of the genetic programs that govern the size and shape of animal tissues, through use of cutting-edge genome editing approaches in laboratory animals. Expected outcomes of this project include the production of genetically engineered animals with altered tissue growth, development of new theories for how tissue growth is normally controlled and how it can be manipulated industrially. This should provide significant benefits, impacting stem cell biology (improving stem cell production), tissue engineering (improving growth of artificial tissues), veterinary science and agriculture (improving productivity).Read moreRead less
Understanding gonadal development and disease using a unique model system, the avian embryo. This project will provide information on normal and abnormal gonadal development during embryonic life. The study will aid in the diagnosis and management of humans born with disorders of sexual development and will be useful for sex ratio manipulation in the poultry industry.
Genetic control of germline progenitor cell heterogeneity and fate. Tissue maintenance in adults is dependent on resident stem cells, defined by self-renewal and differentiation capabilities. It is apparent that stem cell populations are heterogeneous, being composed of subpopulations with distinct properties. The functional significance of these subsets and mechanisms that control their divergent characteristics are unclear. Using germline stem cells from mice as a model, stem cell subsets have ....Genetic control of germline progenitor cell heterogeneity and fate. Tissue maintenance in adults is dependent on resident stem cells, defined by self-renewal and differentiation capabilities. It is apparent that stem cell populations are heterogeneous, being composed of subpopulations with distinct properties. The functional significance of these subsets and mechanisms that control their divergent characteristics are unclear. Using germline stem cells from mice as a model, stem cell subsets have been identified based on differential expression of the pluripotency gene Pou5f1. This project aims to define functional characteristics of these subpopulations and to dissect transcription factor networks controlling their development. This promises important insights into understandings of adult stem cell regulation.Read moreRead less
The birth and death of mammalian sex chromosomes. This project aims to unravel the molecular mechanisms that underlie the transition from autosome to sex chromosome and progressive sex chromosome differentiation in mammals. Monotremes are the only mammalian species with a sex chromosome system that consists of ten sex chromosomes in platypus and nine in echidna. This project will analyse the genetic and epigenetic composition and organisation of the monotreme autosomes that evolved into sex chro ....The birth and death of mammalian sex chromosomes. This project aims to unravel the molecular mechanisms that underlie the transition from autosome to sex chromosome and progressive sex chromosome differentiation in mammals. Monotremes are the only mammalian species with a sex chromosome system that consists of ten sex chromosomes in platypus and nine in echidna. This project will analyse the genetic and epigenetic composition and organisation of the monotreme autosomes that evolved into sex chromosomes in other mammals and compare individual platypus and echidna sex chromosomes to discover how sex chromosomes come to be, differentiate and ultimately are replaced by new sex chromosomes.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
Discovering sex determining genes in a reptile with genetic and environmental sex determination. Reptile sex determination is particularly fascinating because it is triggered either by genes on sex chromosomes or by the nest temperature. This project will identify and characterise candidate sex determining genes in a model reptile to understand how genes control sexual differentiation and how they interact with temperature.
Genetic analysis of lymphatic vascular development. This project investigates the fundamental molecular components that regulate lymphatic vascular system development in the zebrafish embryo. Lymphatic vessels play critical roles in vascular diseases and cancer metastasis. This study will identify and examine key new molecules that will further our basic understanding of lymphatic development.