Defining The Role Of IGF-1 As A Novel Angiocrine Factor In The Development And Treament Of Common Craniofacial Disorders
Funder
National Health and Medical Research Council
Funding Amount
$573,848.00
Summary
1 in 1000 children are born with a small jaw, which requires invasive surgery for treatment. We identified that defects in blood vessel development in the jaw underlie some cases of these craniofacial defects. We found that factors secreted from the major artery in the jaw can promote jaw growth, and our research proposal aims to identify what exactly these factors are. These factors have the potential to be used to therapeutically treat children with a small jaw to help it grow correctly.
Functional Screening Of Novel Genes In Craniofacial Development
Funder
National Health and Medical Research Council
Funding Amount
$540,075.00
Summary
Our faces are central to our ability to communicate, feed, breath and interact with each other. Birth defects that impact on the normal development of the face are common and affect not only the child but have a dramatic impact on the child's family as well. The genetic causes of most facial birth defects are unknown. This project will develop a method for determining how development of the face is controlled and will help identify genes that are responsible for facial birth defects.
A Novel Gene Family Implicated In Neural Crest And Craniofacial Malformation
Funder
National Health and Medical Research Council
Funding Amount
$695,016.00
Summary
We have identified a new type of receptor that when defective causes facial clefting in animal models. We are using our unique laboratory and clinical resources to understand how these birth defects occur and to investigate the molecular signalling events that are controlled by this olfactory receptor. These studies will pave the way to designing pharmaceuticals that may eventually ameliorate or even stop this major group of birth defects.
Birth defects can have devastating consequences for individuals and their families, and improving our ability to diagnose and screen for these disorders has implications for treatment and reproductive options. We are using the mouse as a model to discover genes important in a new class of birth defects caused by dysfunction of a hair-like cellular projection known as the cilium.
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.
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
The Identification Of Genes Involved In Mammalian Craniofacial Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$408,055.00
Summary
Birth defects arising from abnormal development of the embryo are a major cause of infant mortality and childhood disabilities. On average 3-4% of liveborn babies have a major congenital abnormality, and of the 15-20% of pregnancies which spontaneously abort, many are due to chromosomal or other developmental anomalies. A common feature of many developmental disorders is dysmorphology of the face, suggesting that genes important in patterning the face are also important in the development of oth ....Birth defects arising from abnormal development of the embryo are a major cause of infant mortality and childhood disabilities. On average 3-4% of liveborn babies have a major congenital abnormality, and of the 15-20% of pregnancies which spontaneously abort, many are due to chromosomal or other developmental anomalies. A common feature of many developmental disorders is dysmorphology of the face, suggesting that genes important in patterning the face are also important in the development of other organ systems. During development of the embryo many of the features of the face derive from a series of swellings termed the pharyngeal arches. The complex processes which determine how the face develops are in a large part controlled by the co-ordinated expression of a large number of genes in the first two of the five pharyngeal arch pairs. While we know some of the genes involved in these processes, the precise mechanisms of craniofacial development are relatively poorly understood. In this project we propose a large scale approach to identifying genes involved in development of the mammalian face and to further delineating their role in development and human disease. This approach takes advantage of state of the art genomic technologies available at the IMB and through existing collaborations overseas. In collaboration with Dr Bento Soares (University of Iowa) we have constructed a library containing all of the genes which are expressed in the first two pairs of pharyngeal arches in the developing mouse embryo. Using an approach designed to eliminate all those genes which are expressed in all or most tissues of the body and play a general role in the body's metabolism, we will select for those genes which play a specific and important role in embryonic development. We will then isolate the human counterparts of these genes and more thoroughly investigate their role in embryonic development and disease.Read moreRead less