The control of chromosome division during female meiosis. Mammalian eggs are stored life-long and finally mature in the hours before ovulation. This project examines how the chromosomes in the egg are separated properly so as to produce a mature egg capable of being fertilized by a sperm. Often in eggs chromosome division is imprecisely executed, and this project will help us understand why this occurs.
Understanding Mitotic Telomere Deprotection. This project aims to study telomeres, the DNA and protein structures that protect chromosome ends. During cell division, cells under stress intentionally uncap their telomeres. This project expects to generate new knowledge that challenges the conventional notion of telomeres as static elements, showing instead that telomeres can be dynamic signalling hubs. Expected outcomes of this project include an understanding of the genetic, proteomic, and signa ....Understanding Mitotic Telomere Deprotection. This project aims to study telomeres, the DNA and protein structures that protect chromosome ends. During cell division, cells under stress intentionally uncap their telomeres. This project expects to generate new knowledge that challenges the conventional notion of telomeres as static elements, showing instead that telomeres can be dynamic signalling hubs. Expected outcomes of this project include an understanding of the genetic, proteomic, and signalling pathways involved in this novel phenomenon. This should provide significant benefits to our fundamental understanding of biological processes that protect human genomes and provide a valuable dataset for research on telomere biology, DNA repair, and genome stability.Read moreRead less
Understanding telomere privilege in pluripotent stem cells. We recently identified that fundamental mechanisms which protect chromosome ends (i.e. “telomeres”) are not conserved between somatic and embryo-derived stem cells. This discovery is without precedent and challenges the dogmatic expectation that cellular functions promoting genome stability are conserved in stem cells. We term the unexpected protective capacity of pluripotent chromosome ends “telomere privilege”. Here we will uncover th ....Understanding telomere privilege in pluripotent stem cells. We recently identified that fundamental mechanisms which protect chromosome ends (i.e. “telomeres”) are not conserved between somatic and embryo-derived stem cells. This discovery is without precedent and challenges the dogmatic expectation that cellular functions promoting genome stability are conserved in stem cells. We term the unexpected protective capacity of pluripotent chromosome ends “telomere privilege”. Here we will uncover the molecular, genomic, and proteomic regulators or telomere privilege; determine the breath of telomere privilege in stem cell lineages; elucidate the functional significance of telomere privilege; and exploit telomere privilege to study fundamental biology related to telomeres and the DNA damage response.Read moreRead less
Integration of Cellular Gene Regulation Processes. This research program aims to identify specific transcriptional regulatory networks in yeast, to determine how some of these networks interact with each other and within these networks to identify the roles of genes whose functions are currently unknown. It will identify systems regulating genes concerned with one-carbon metabolism, cellular responses to oxidative stress and developmental changes associated with meiosis. It will provide a fra ....Integration of Cellular Gene Regulation Processes. This research program aims to identify specific transcriptional regulatory networks in yeast, to determine how some of these networks interact with each other and within these networks to identify the roles of genes whose functions are currently unknown. It will identify systems regulating genes concerned with one-carbon metabolism, cellular responses to oxidative stress and developmental changes associated with meiosis. It will provide a framework to test regulatory network models and to analyse the molecular basis of interactions between control systems. This research will eventually provide the ability to predict how cells respond to drugs and other environmental stimuli.Read moreRead less
Head and face development: dissecting tissue-specific gene function. The outcome of our investigation of the early development will inform us of the ways and means for the embryo to assemble the essential building blocks of the body, and insights into the developmental origin of birth defects. This knowledge will benefit the biomedical research community, the education sector and the general public by enabling the formulation of new hypotheses, enriching the curriculum, and providing an evidenc ....Head and face development: dissecting tissue-specific gene function. The outcome of our investigation of the early development will inform us of the ways and means for the embryo to assemble the essential building blocks of the body, and insights into the developmental origin of birth defects. This knowledge will benefit the biomedical research community, the education sector and the general public by enabling the formulation of new hypotheses, enriching the curriculum, and providing an evidence-based understanding of the genetic basis of congenital malformations for delivering informative counselling. The technical expertise gained from this project will enhance the nation's research capability through the sharing of skills and knowledge with other research teams in the academia and the industry. Read moreRead less
Ageing wild vertebrates from their DNA: an investigation using Humpback Whales as an example. The aim of this project is to estimate the age of individually identified humpback whales and the age structure of humpback whale populations using non-lethal, innovative molecular techniques. Populations of humpback whales in the Southern Hemisphere are slowly recovering from intensive whaling during the 20th century. This project is significant because it will provide the first comparative information ....Ageing wild vertebrates from their DNA: an investigation using Humpback Whales as an example. The aim of this project is to estimate the age of individually identified humpback whales and the age structure of humpback whale populations using non-lethal, innovative molecular techniques. Populations of humpback whales in the Southern Hemisphere are slowly recovering from intensive whaling during the 20th century. This project is significant because it will provide the first comparative information on the age structure of these populations, resulting in improved estimation of recovery and population dynamics of long-lived vertebrates. The results of this project will revolutionise research on ageing in whales and dolphins, providing an important alternative to lethal scientific whaling.Read moreRead less
Exploring the gene regulation networks governing mitochondrial biogenesis in Arabidopsis. Mitochondria, subcellular organelles that perform many functions indispensable to plant growth and productivity, are dynamic compartments whose protein complement changes dramatically during plant development and under stress. Yet, the cellular processes that regulate the production of these organelles are virtually unknown. By combining conventional approaches with an extremely powerful holistic method for ....Exploring the gene regulation networks governing mitochondrial biogenesis in Arabidopsis. Mitochondria, subcellular organelles that perform many functions indispensable to plant growth and productivity, are dynamic compartments whose protein complement changes dramatically during plant development and under stress. Yet, the cellular processes that regulate the production of these organelles are virtually unknown. By combining conventional approaches with an extremely powerful holistic method for simultaneously examining the expression patterns of every gene in the model plant Arabidopsis, this project will identify proteins that regulate mitochondrial biosynthesis and uncover the gene networks that these proteins control. The project outcomes will provide new opportunities for the rational manipulation of plant growth and productivity.Read moreRead less
The evolutionary transition from anaerobic to aerobic metabolism. This project aims to find out how life on Earth survived the revolutionary changes when cyanobacteria first released oxygen into the atmosphere. These events led to a transition from anoxic (oxygen-free) to oxic (oxygen-rich) conditions. A comparative genomic view across a series of photosynthetic organisms will be performed at the molecular level with ecological interpretation. Understanding of what metabolic changes occurred in ....The evolutionary transition from anaerobic to aerobic metabolism. This project aims to find out how life on Earth survived the revolutionary changes when cyanobacteria first released oxygen into the atmosphere. These events led to a transition from anoxic (oxygen-free) to oxic (oxygen-rich) conditions. A comparative genomic view across a series of photosynthetic organisms will be performed at the molecular level with ecological interpretation. Understanding of what metabolic changes occurred in response to the shifts in the environment will have wide implications for predicting the evolutionary events that are still occurring today, such as rapidly changing climatic conditions. This fundamental research will enhance Australia's profile in this field.Read moreRead less
Controlling the first step of differentiation of embryonic cells. This project aims to improve understanding of how diverse cell types are generated for building the body plan of the embryo. The first step of embryonic cell lineage differentiation takes place at early gastrulation when the multipotent embryonic cells acquire the attributes of specific tissue lineages. This project intends to elucidate how inductive signals and gene function are integrated to drive the lineage choice of the naïve ....Controlling the first step of differentiation of embryonic cells. This project aims to improve understanding of how diverse cell types are generated for building the body plan of the embryo. The first step of embryonic cell lineage differentiation takes place at early gastrulation when the multipotent embryonic cells acquire the attributes of specific tissue lineages. This project intends to elucidate how inductive signals and gene function are integrated to drive the lineage choice of the naïve cells, by tracking the impact of the activity of signalling pathways and gene regulation on cell differentiation. This may deliver insights into the temporal hierarchy and functional attributes of the molecular switches that control stem cell differentiation. Expected outcomes may have applications in tissue engineering.Read moreRead less