Understanding Human Dysmorphology Through Analysis Of ENU Mutant Mice
Funder
National Health and Medical Research Council
Funding Amount
$602,501.00
Summary
Birth defects are common and have an enormous impact on both the individual and their family. Birth defects are by definition the products of abnormal development of the embryo. Our research is aimed at identifying the normal mechanisms that usually prevail during development and the disturbances to those mechanisms that result in birth defects. These findings will lead to improved diagnostic, therapeutic and preventative options for families affected by birth defects
Rapid Identification And Characterisation Of Genes Involved In Skeletal Development
Funder
National Health and Medical Research Council
Funding Amount
$550,536.00
Summary
Birth defects are common and have an enormous impact on both the individual and their family. Birth defects are by definition the products of abnormal development of the embryo. Our research is aimed at identifying the normal mechanisms that usually prevail during development and the disturbances to those mechanisms that result in birth defects. These findings will lead to improved diagnostic, therapeutic and preventative options for families affected by birth defects
Developmental Functions Of A Novel Zinc-finger Protein
Funder
National Health and Medical Research Council
Funding Amount
$666,812.00
Summary
Diseases of the respiratory track and the immune system represent major public health burdens, from the common cold and lung cancer, to increased risk of infections and auto-immune diseases. We have identified a new gene that is essential for lung development, and required for normal development of antibody-producing immune cells. Here we want to define the mechanism by which this gene functions, in order to better understand how lungs and immune cells develop.
The Role Of Hypoxia In The Developmental Programming Of The Kidney
Funder
National Health and Medical Research Council
Funding Amount
$651,276.00
Summary
We aim to understand how inadequate oxygen supply to the fetus during pregnancy can affect development of the kidney. Many babies do not get enough oxygen whilst developing in the womb. This can be due to a poorly formed placenta or the mother smoking. This can interfere with normal growth and formation of the kidney. Our knowledge may help babies get the best start to life.
MEASURING AND MODELLING VISUAL CORTICAL PLASTICITY
Funder
National Health and Medical Research Council
Funding Amount
$612,693.00
Summary
We are the product of both our genes and our environment. Scientists have already shown that the physical structure of our brain can be changed by our experiences. But how much can it be changed? Our experiments will address this question for a particular case: how far our visual experiences can affect the structure of the part of our brain that processes visual images. This will help us understand the delicate balance between our genes and our environment in shaping who we are.
The Primary Cilium In Hedgehog Signalling And Disease
Funder
National Health and Medical Research Council
Funding Amount
$583,312.00
Summary
Every mammalian cell has a single protrusion called the primary cilium. Recent studies in mice and humans have highlighted the importance of the primary cilium in disease states affecting the limb, kidney, skeleton, brain, eyes, ears and lungs, as well as obesity and diabetes. We have isolated a novel mouse with a defect in the machinery required for correct functioning of the primary cilium. This mouse has widespread abnormalities and will be used to elucidate the role of cilia in disease.
Defining The Genetic Causes Of The Abnormal Vertebral Segmentation Syndrome, Spondylocostal Dysostosis
Funder
National Health and Medical Research Council
Funding Amount
$476,523.00
Summary
There are many birth defects that cause vertebral malformations along the spinal column. These occur as the embryo develops in utero, during the formation of structures known as somites. Somites also form the ribs, muscle, tendons and dermis. We are studying an example of this type of birth defect called spondylocostal dysostosis (SCD). We have shown that mutations in three different genes cause some cases of this inherited disease in humans. These genes are called DLL3, MESP2 and LFNG. However, ....There are many birth defects that cause vertebral malformations along the spinal column. These occur as the embryo develops in utero, during the formation of structures known as somites. Somites also form the ribs, muscle, tendons and dermis. We are studying an example of this type of birth defect called spondylocostal dysostosis (SCD). We have shown that mutations in three different genes cause some cases of this inherited disease in humans. These genes are called DLL3, MESP2 and LFNG. However, 80% of SCD patients do not have a mutation in any of these genes. Thus we need to discover how these other cases occur. This project uses two strategies in parallel. Firstly, we will analyse large families that have a history of SCD, and use this information to find causative gene mutations. However, a significant proportion of cases occur without family history. To find out what genes are involved in these cases is more difficult. We have created a mutant mouse by specifically deleting the DLL3 gene. This mouse has very similar vertebral malformations to SCD. We will compare embryos from normal and mutant mice to find genes that do not operate normally in the mutant. These genes are candidates for causing SCD, and thus we will screen these genes in human patients for mutations. However, simply finding a change in a candidate gene does not necessarily mean that this is the cause of SCD. To prove this, we have developed several tests to determine if the mutation alters the normal function of the protein encoded by the mutated gene. This work will greatly benefit the future genetic assessment of SCD patients. In addition, by studying our mouse model of SCD, we will gain a greater understanding of how DLL3 functions. This knowledge may be useful in developing stem cell-based therapies that involve the production of specific cell types.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
The Embryological And Molecular Basis Of Zic2 Involvement In Holoprosencephaly
Funder
National Health and Medical Research Council
Funding Amount
$624,145.00
Summary
The brain is the most complex organ in the human body and diseases or disorders of the brain can become evident at any stage of life. Generally such problems have profound consequnces for the affected individuals and their families. One of the most common problems of brain development that is evident either at birth or within the first years of life is called holoprosencephaly (HPE). This condition affects the midline of the brain and the face and can lead to delay in mental, motor and language ....The brain is the most complex organ in the human body and diseases or disorders of the brain can become evident at any stage of life. Generally such problems have profound consequnces for the affected individuals and their families. One of the most common problems of brain development that is evident either at birth or within the first years of life is called holoprosencephaly (HPE). This condition affects the midline of the brain and the face and can lead to delay in mental, motor and language development, seizures, and obvious facial abnormalities. In its most severe form only one eye develops in the middle of the face, a condition known as cyclopia and a large majority of the severely affected children will die late in gestation or at birth. This condition can be inherited, but because the genetic lesions that cause this problem affect different people differently, people can carry the causative genetic change(s) without knowing it. We need to identify and study the genetic lesions that contribute to this condition in order to begin to understand how we can stop these mutations affecting the developing foetus. Because it is difficult to study embryonic development in humans we have generated a mouse model of this condition. In the mouse model just one gene (called Zic2) is altered and embryos that have two copies of this alteration develop the most severe form of cyclopia and die in the second half of gestation. This means that the normal role of this gene is to stop us developing HPE. We will use this mouse model to see just when and how the Zic2 gene prevents HPE. In addition, we will look to see what other genes Zic2 interacts with by breeding mice that carry the mutation in Zic2 with mice that carry a mutation in a second gene that can also cause HPE. These experiments are very important because if we understand how Zic2 and other genes protect us from HPE we can begin to design strategies to decrease the risk of a child developing this condition.Read moreRead less
Hedgehog Signalling In Limb And Craniofacial Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$494,544.00
Summary
Anomalies of the face and limbs are amongst the most common features of human birth defects, and their frequent association suggests that the same genes are involved in governing the development of the limbs and face during embryogenesis. We have used a genomics-based approach to identify genes involved in limb development based on their alteration in a mouse model which develops extra fingers and toes. Defects in this mouse result from changes in Gli3, a gene which is known to be important in b ....Anomalies of the face and limbs are amongst the most common features of human birth defects, and their frequent association suggests that the same genes are involved in governing the development of the limbs and face during embryogenesis. We have used a genomics-based approach to identify genes involved in limb development based on their alteration in a mouse model which develops extra fingers and toes. Defects in this mouse result from changes in Gli3, a gene which is known to be important in both limb and face development. Based on the organs in which our genes of interest are active, we believe that they will also play key roles in embryonic development of the limbs, face and other organs. We now plan to investigate the regulation of a subset of these genes based on analysis in mouse models of limb and face development. In addition, we have chosen to further analyse the function of a completely novel gene we have identified which our preliminary studies suggest may play a role in the normal development of the lip and palate. These studies have the potential to shed light on the processes governing how organs develop, as well as on the molecular basis of common birth defects such as polydactyly (extra fingers and toes) and cleft palate.Read moreRead less