Glucose, Glucose Transporters And Blastocyst Formation In The Mouse
Funder
National Health and Medical Research Council
Funding Amount
$281,650.00
Summary
Embryo-based biotechnologies have the potential to improve human reproductive health, notably in treating infertility by In vitro fertilisation (IVF). They are also central to the future use of embryonic stem cells for human tissue replacement. This project investigates the molecular mechanisms controlling one of the earliest differentiations in the growth of the embryo. Using the mouse as an experimental model it will investigate the importance of several factors in the changes which set up the ....Embryo-based biotechnologies have the potential to improve human reproductive health, notably in treating infertility by In vitro fertilisation (IVF). They are also central to the future use of embryonic stem cells for human tissue replacement. This project investigates the molecular mechanisms controlling one of the earliest differentiations in the growth of the embryo. Using the mouse as an experimental model it will investigate the importance of several factors in the changes which set up the placenta and fetus as seperate tissues in the very early embryo. A key focus is the supply of glucose to the newly fertilised embryo and how important this glucose supply is for the survival of the embryo. Moreover there is great interest in the possibility that metabolic events in utero can contribute to the development of diseases in later life, notably, coronary heart diease, stroke, high blood pressure and non-insulin dependent diabetes. The results from these studies will contribute to our understanding of why some couples are infertile, lead to improved management of infertility by diet and invitro fertilisation procedures. It will also be of benefit in dietary advice to women with diabetes mellitus, seeking to have children. The adenoviral strategy for gene delivery into early mouse embryos may in the long term also find wide clinical application in the treatment of genetic defects at the very earliest stages in development and as such is of enormous potential benefit in the management of both animal and human reproduction.Read moreRead less
Exploring Non-canonical Roles For The Ribosomal RNA Genes Critical For Malignant Transformation And Cell Fate
Funder
National Health and Medical Research Council
Funding Amount
$1,972,669.00
Summary
Genes are encoded by linear DNA sequences, and whether they are expressed or silenced will depend on modifications and 3D interactions with other genomic regions. We aim to identify genes that interact with the a subnuclear body called the nucleolus during cancer development and differentiation. Understanding how these 3D genomic interactions are altered for the coordinated expression of a suite of genes may provide the basis for novel strategies to manipulate gene expression in disease.
This work will analyse how cells, the building blocks of tissues, are organized together to form functioning organs. It focuses on the adhesion molecules that allow cells to recognize one another, which cooperate with the internal skeleton of cells to link them together. We aim to understand how these cellular systems work normally and how they are targeted to disrupt tissue integrity in diseases like cancer and inflammation.
Cortactin: Molecular Regulation Of Cadherin Activity And Epithelial Morphogenesis.
Funder
National Health and Medical Research Council
Funding Amount
$239,250.00
Summary
Interactions between cells and their neighbouring cells control many important processes in the body. The adhesion molecule E-cadherin is a major protein that controls how cells interact with one another in many epithelial tissues (e.g. breast, lung, gut). These tissues are the source of many common diseases, particular cancer and inflammation. E-cadherin is essential for these tissues to form normally, and loss of E-cadherin function contributes to disease in these tissues (especially common ca ....Interactions between cells and their neighbouring cells control many important processes in the body. The adhesion molecule E-cadherin is a major protein that controls how cells interact with one another in many epithelial tissues (e.g. breast, lung, gut). These tissues are the source of many common diseases, particular cancer and inflammation. E-cadherin is essential for these tissues to form normally, and loss of E-cadherin function contributes to disease in these tissues (especially common cancers, such as breast and lung). Understanding how E-cadherin controls normal cell function in these tissues will therefore provide key insights into how disease arises. In this study we will investigate how a protein which binds to E-cadherin, cortactin, contributes to the biological effect of E-cadherin in supporting tissue architecture. Understanding the fundamental elements of how cortactin works with E-cadherin will provide invaluable information into how cells recognize one another in health, and fail to adequately recognize each other in common diseases.Read moreRead less