From Endoderm To Gut: Regulation Of Lineage Allocation And Morphogenesis In The Murine Embryo
Funder
National Health and Medical Research Council
Funding Amount
$439,500.00
Summary
One of the most critical steps in early development is the generation of the full complement of cell types required to build the embryo. A thorough understanding of the mechanisms underlying this is vital for the development of methods for directing the differentiation of stem cells for use in regenerative medicine. The objective of our research is to understand the cellular and molecular mechanisms underlying the assignment of cells to particular fates and the establishment of the body plan of ....One of the most critical steps in early development is the generation of the full complement of cell types required to build the embryo. A thorough understanding of the mechanisms underlying this is vital for the development of methods for directing the differentiation of stem cells for use in regenerative medicine. The objective of our research is to understand the cellular and molecular mechanisms underlying the assignment of cells to particular fates and the establishment of the body plan of the embryo. The endodermal cell layer forms the lining of the embryonic gut which gives rise to the entire gastrointestinal tract, the respiratory tract and other structures including the liver and the pancreas during organogenesis. This investigation focuses on the questions of how the pluripotent progenitor cells are allocated to the endodermal lineage and how the embryonic gut is patterned during early development of the mouse embryo. Analysis of endoderm development will provide insights into the roles of the allocation of progenitor cells to tissue lineages, cell movement, and diversification and maturation of functional cell types. These processes are universally relevant to the formation of all types of organ primordia in the embryo. Understanding the complexity of tissue interactions and the interplay of molecular mechanisms of cell lineage choice and differentiation in the embryo is a major challenge. However, knowledge of the processes that drive tissue differentiation in the embryo is absolutely crucial for enhancing our ability to direct cell and tissue differentiation for the realization of cell-based technologies in biomedicine.Read moreRead less
A Fluorescent Zebrafish Model Of Endodermal Cell Migration.
Funder
National Health and Medical Research Council
Funding Amount
$535,333.00
Summary
The most catastrophic event in cancer progression is when individual cancer cells move to other areas of the body and develop into secondary tumours. This very complex process shows striking similarities to cell movements during embryogenesis. In this project, we use a model system, the zebrafish, to analyse how cells move during embryogenesis. We will determine the genes required for cell movements in the zebrafish embryo, so we can find the corresponding genes in human cancers.
Disorders of sexual development (DSDs) are surprisingly common, and often result in infertility, genital abnormalities, gender mis-assignment and long-term psychological trauma. In this Program we will pool our expertise in human molecular genetics, mouse developmental biology and protein chemistry to identify genes important for sex determination and development of the gonads, and discover how they contribute to DSD, in order to improve clinical care to patients with DSD.
Understanding And Preventing Adverse Developmental Effects Of Perinatal Infection/inflammation
Funder
National Health and Medical Research Council
Funding Amount
$621,458.00
Summary
Exposure of babies to infection or inflammation within the womb is common and is associated with preterm delivery and illness in newborns. The biggest problem for these babies is lung disease due to inflammation of the lungs before birth and/or in response to lung injury after birth. We are investigating how inflammation alters lung development, and working on developing a novel cell therapy to prevent life-threatening newborn lung disease.
Molecular Genetics Of Sex Determination And Gonad Development
Funder
National Health and Medical Research Council
Funding Amount
$4,580,898.00
Summary
Intersex disorders - ranging in severity from hypospadias (misplacement of the urethral opening) to complete sex reversal - are surprisingly common, with estimates as high as 4% of all live births. These disorders usually result in infertility, genital abnormalities, gender mis-assignment and long-term psychological trauma. The cause of these problems is most often the failure of the delicate network of gene regulation that is responsible for proper development of testes or ovaries in the embryo ....Intersex disorders - ranging in severity from hypospadias (misplacement of the urethral opening) to complete sex reversal - are surprisingly common, with estimates as high as 4% of all live births. These disorders usually result in infertility, genital abnormalities, gender mis-assignment and long-term psychological trauma. The cause of these problems is most often the failure of the delicate network of gene regulation that is responsible for proper development of testes or ovaries in the embryo. This research program will identify genes important for sex determination and development of the gonads, find out how these genes function and interact, and discover how they contribute to cases of aberrant sexual development in humans. Australia boasts three of the foremost international researchers in sex determination. Their contributions have been fundamental to the advancement of the field, including the identification and characterization of the master testis determining gene and other genes critical for sex determination. They now propose to pool their expertise in human molecular genetics, mouse developmental biology and protein chemistry to bring spectacular advances in our knowledge of human sexual development and its associated disorders. This information will be used to bring improved clinical care to patients withdisorders of sexual development.Read moreRead less
Modern Chemical Exposures In Utero And In Infancy, And Their Impact Upon Early Neurodevelopmental Outcomes In The Barwon Infant Study, An Unselected Birth Cohort Study
Funder
National Health and Medical Research Council
Funding Amount
$138,353.00
Summary
I am a paediatric doctor interested in the effects of modern industrial chemicals on children’s development. Even in the womb babies are exposed to industrial chemicals and we know some, like lead, are harmful to developing brains. I am interested in other chemicals that are now suspected to affect development, including the polybrominated diphenyl esters (PBDEs), and I intend to investigate this as part of the Barwon Infant Study, which follows 1250 children from before birth to 3 years.
Developing An In Vitro Model Of A Human Blastocyst
Funder
National Health and Medical Research Council
Funding Amount
$890,062.00
Summary
Using novel cellular and molecular technologies we propose to develop an artificial model of an early human blastocyst. This will allow us to study the first initial steps in human development without the use of real embryos. Such a model will not only help us decipher the first steps in human development, but we anticipate it will be essential to study how gene mutations and the environment affect this initial step in human development.
Characterisation Of Eurl, A Novel Gene Implicated In The Etiology Of Abnormal Brain Development And Intellectual Disability
Funder
National Health and Medical Research Council
Funding Amount
$597,541.00
Summary
Intellectual disability affects around one per cent of Australians, and can arise from genetic abnormalities during fetal life, such as through abnormal regulation of gene expression. We have identified a novel gene, known as eurl, which controls brain assembly as well as the ability of neurons to form functional connections within the brain. We will investigate how this novel gene controls brain development, and characterise eurl as a potential therapeutic target for learning and memory.