I am a developmental biologist who identifies and characterises genes required for normal embryonic development in mouse. I translate this information into the genetic diagnosis and developmental understanding of congenital malformations in humans.
Role Of Homeobox Gene Nkx2-5 In Heart Development And Congenital Heart Disease
Funder
National Health and Medical Research Council
Funding Amount
$227,340.00
Summary
This project seeks to define the developmental principles underlying chamber formation in the developing heart and how this becomes abnormal in inherited heart defects. The gene we study, Nkx2-5, encodes a protein which binds to DNA and regulates the expression of the genetic program for formation of the ventricles, the pumping chambers of the heart. We believe that Nkx2-5 is an Oexecutive regulator? of this program, controlling the timing and spatial expression of other regulators that then con ....This project seeks to define the developmental principles underlying chamber formation in the developing heart and how this becomes abnormal in inherited heart defects. The gene we study, Nkx2-5, encodes a protein which binds to DNA and regulates the expression of the genetic program for formation of the ventricles, the pumping chambers of the heart. We believe that Nkx2-5 is an Oexecutive regulator? of this program, controlling the timing and spatial expression of other regulators that then control expression of a host of genes required for muscle differentiation and the development of form (morphogenesis). Mutations in one copy of the human Nkx2-5 gene have recently been discovered to be associated with atrial septal defect, or Ohole in the heartO, a sometimes serious inherited defect in heart structure. Mouse embryos with a mutation in both copies of the gene have a much more serious defect in ventricle formation that is incompatible with life. The studies are designed to extend our understanding of the genetic regulation of chamber formation in the heart. We will firstly make a mouse model of the human disease using gene targeting technology, which allows us to make precise alteration in single genes in this animal. Secondly, we will apply new technology to the heart that will let us visualise molecular and cellular events at higher resolution. This technology, which uses fluorescent tags on cells and a laser to measure cell identity, has been used to great affect in the field of immunology, but can be adapted to the heart. We will use it to isolate and characterise the precious early cells that give rise to the heart in the embryo. It is in these cells that the human and mouse mutations have their first effects. Our studies have relevance to understanding and screening for human inherited heart abnormalities, and for understanding the general principles of heart formation that may reveal valuable ways to intervene in heart disease.Read moreRead less
Body Segment Identity Specification By The Transcription Regulator, Moz
Funder
National Health and Medical Research Council
Funding Amount
$366,301.00
Summary
One in 28 newborns have birth defects. Cleft palate and aortic arch defects are among the most common, always requiring surgery and often causing lethality. We propose to study a protein, Moz, which is essential for palate and aortic arch development. Moz (Monocytic leukaemia zinc finger protein) was first identified in human chromosomal abnormalities causing particularly aggressive forms of childhood and adult leukaemia. We have shown previously that Moz is essential for the formation of blood ....One in 28 newborns have birth defects. Cleft palate and aortic arch defects are among the most common, always requiring surgery and often causing lethality. We propose to study a protein, Moz, which is essential for palate and aortic arch development. Moz (Monocytic leukaemia zinc finger protein) was first identified in human chromosomal abnormalities causing particularly aggressive forms of childhood and adult leukaemia. We have shown previously that Moz is essential for the formation of blood stem cells. Moz can regulate the activity of genes, but which genes it regulates in vivo is unknown. In the absence of Moz, mice are born with a cleft palate, lack the thymus, where immune cells are instructed, and fail to form the lung blood circulation, so that they are unable to supply their blood with oxygen after birth. Moz deficiency also causes defects of the vertebrate column, such that individual vertebrae acquire the appearance of their neighbours. These symptoms are typical for a general defect in positional information of individual body segments with respect to their location along the body axis. We will investigate the molecular mechanisms that require Moz in patterning of the body axis. This project will characterize a genetic mechanism that is crucial for normal development of the palate, the aorta and the vertebrate column.Read moreRead less
Impact Of The Extraembryonic Tissues On Early Embryonic Development: Genetic Basis Of Abnormal Body Plan
Funder
National Health and Medical Research Council
Funding Amount
$316,326.00
Summary
An important milestone of early development is the attachment (or implantation) of the embryo to the wall of the womb through the action of a specialized population of cells known as the trophoblasts. The early conceptus comprises not only cells that make up the embryo but also those (called extraembryonic cells) that later forms the placenta, and the membranes that wrap around the developing fetus. The placenta and the membranes are indispensable for the normal fetal growth by providing the eff ....An important milestone of early development is the attachment (or implantation) of the embryo to the wall of the womb through the action of a specialized population of cells known as the trophoblasts. The early conceptus comprises not only cells that make up the embryo but also those (called extraembryonic cells) that later forms the placenta, and the membranes that wrap around the developing fetus. The placenta and the membranes are indispensable for the normal fetal growth by providing the effective nourishment and protection for the developing fetus. Recent studies in the mouse have revealed that normal development of the recently implanted conceptus depends on the reciprocal interaction of the embryonic and extraembryonic cells. Abnormal embryo may form if the non-embryonic cells do not differentiate normally, as seen in the situation when an X-chromosome is lost from the female embryo (as in 45X0 Turner syndrome) and in early conceptus that carries a gene mutation that affects the production of growth factors by the extraembryonic cells. Functional deficiency of the extraembryonic cells might be a cause for early pregnancy loss where the conceptus has successfully implanted but the embryo fails to form. The remarkable conservation of the molecular mechanism that controls mammalian development allows us to use the mouse embryo as a genetic model for human development. The proposed project is designed to examine in a laboratory mouse model the molecular and cellular factors that regulate the activity of the extraembryonic cells. Specifically, we focus on a gene known as Sox17, which may be involved with the differentiation of the extraembryonic cells. We will study the impact of the mutation of this gene on the development of the early embryo to test the hypothesis that the extraembryonic cells may fulfill an important function in ensuring normal embryo formation, in addition to the other roles of nourishment and mechanical protection of the fetus.Read moreRead less
Head Development: Genetic Determinants And Tissue Potency
Funder
National Health and Medical Research Council
Funding Amount
$947,116.00
Summary
Congenital malformations involving major defects of brain (anencephalus and related anomalies) and facial structures (ear, face and neck) are encountered in 3.4 and 1.4 per 10000 births respectively (Congenital Malformations Australia 1981-1996, National Perinatal Statistics Unit) and they constitute a substantial clinical burden. It is believed that these major structural defects usually result from abnormal development in the first trimester, which coincides with the time frame for the formati ....Congenital malformations involving major defects of brain (anencephalus and related anomalies) and facial structures (ear, face and neck) are encountered in 3.4 and 1.4 per 10000 births respectively (Congenital Malformations Australia 1981-1996, National Perinatal Statistics Unit) and they constitute a substantial clinical burden. It is believed that these major structural defects usually result from abnormal development in the first trimester, which coincides with the time frame for the formation of the basic components of the embryonic head in the mouse. Knowledge of the formation of the head in the mouse model is therefore relevant to the understanding of related developmental processes in early human development. This project which involves the application of sophisticated embryological and molecular analyses on mouse embryos generated by transgenesis and genetic manipulation provides a detailed studies of craniofacial morphogenesis in a mammalian model for early human development. The micro-manipulation procedures, embryo culture, fluorescence microscopy and the in situ hybridization are routinely performed in our laboratory, and most of the mouse lines are well established in my laboratory. Experiments proposed for this project that focus on the embryological and molecular analysis of normal and mutant embryos should discover new information on the cellular and molecular mechanisms that regulate head development. The knowledge will also offer insight into the pathogenesis of similar craniofacial malformations in other mutant embryos.Read moreRead less
Signalling And Transcriptional Activity For Craniofacial Morphogenesis In An Experimental Genetic Mouse Model
Funder
National Health and Medical Research Council
Funding Amount
$74,755.00
Summary
Abnormalities in craniofacial development affect 2-1000 births in Australia. The aim of this project is to identify genes crucial for the development of the head and face. In particular the project focuses on the Twist1 gene. TWIST1 plays a key role in craniofacial development and individuals lacking functional Twist1display facial anomalies such as craniosynostosis and cleft palate. Dissecting the function of Twist1 is essential to identifying new avenues for the prevention of these defects.
Dissecting The Role Of Hedgehog Signalling In Chondrogenesis And Skeletal Disease
Funder
National Health and Medical Research Council
Funding Amount
$408,739.00
Summary
There are close to 400 inherited disorders that affect how the skeleton develops, as well as a range of injury and age-related skeletal defects. There is much interest in treating such abnormalities with artificial bone grown outside the body. In order to achieve this aim we must understand all of the processes involved in producing and maintaining bone within the body. We are using both mouse and cell culture models of skeletal development to increase our understanding of these processes.
Investigation Of Delta3 Function And Notch Signalling During Cell Fate Specification In Mouse And Human
Funder
National Health and Medical Research Council
Funding Amount
$221,717.00
Summary
This project seeks to understand how cells within the developing embryo are produced and how they are given a specific identity. These processes often require the cell to make a decision about what type of cell it will become. We are using the Delta3 gene, which is present in humans and in the mouse, as a tool for our investigations. Delta3 is expressed at the surface of the cell and Notch (its receptor) is present on the surface of neighbouring cells. Delta3 on one cell will bind to Notch on th ....This project seeks to understand how cells within the developing embryo are produced and how they are given a specific identity. These processes often require the cell to make a decision about what type of cell it will become. We are using the Delta3 gene, which is present in humans and in the mouse, as a tool for our investigations. Delta3 is expressed at the surface of the cell and Notch (its receptor) is present on the surface of neighbouring cells. Delta3 on one cell will bind to Notch on the neighbouring cell and activates Notch. When Notch is activated in a cell it pushes the cell to make its decision. This project aims to determine what exactly is the function of Delta3 in mammals and how at the level of the individual cell this protein exerts its effects. We have generated a mouse in which the Delta3 gene is no longer active and have observed that embryos do not develop normally. We will explore these defects (which affect the skeleton and the brain) in detail in order to define their origins. We will also use these abnormal mice to identify genes, which require the function of Delta3 for their normal activity. It is not only important to define the function of Delta3 in mammals but also to determine this protein functions. We wish to know how exactly Delta3 interacts with Notch. That is, which part of the Delta3 protein binds to which part of the Notch protein. We can address this by modifying the Delta3 protein in small (but revealing ways) and see if it can still bind the Notch receptor in a cell culture assay. Our studies have relevance to humans because recently it has been shown that Delta and Notch are associated with a human syndrome (spondylocostal dysostosis) in which individuals suffer from abnormal skeletons.Read moreRead less
The Role Of The MYST Family Lysine Acetyltransferase, Hbo1, In Development And In The Adult
Funder
National Health and Medical Research Council
Funding Amount
$403,368.00
Summary
This project will produce a detailed analysis of the function of Hbo1, a transcription factor, and determine its importance in regulating gene expression. All biological processes rely on accurate regulation of gene transcription and all diseases lead to changes in gene expression. This work will increase understanding of how gene expression is regulated and, ultimately, this knowledge will find wide application in the development of new treatment paradigms.