Epigenetic Regulation Of Cell Lineage Differentiation In The Early Embryo
Funder
National Health and Medical Research Council
Funding Amount
$440,983.00
Summary
Exposure of embryos to a range of stresses can increase the predisposition to chronic diseases of adulthood. Stressing embryos at critical stages of development cause errors in reorganization of the nucleus that are required for normal gene expression. These errors are propagated into adulthood. This project will map the normal processes of nuclear reorganization and define how stress to the embryo changes this process, allowing an understanding of the causes of some important chronic diseases.
HtrA4-induced Endothelial Dysfunction In Early-onset Preeclampsia
Funder
National Health and Medical Research Council
Funding Amount
$86,073.00
Summary
Preeclampsia (PE), a life-threatening disorder of pregnancy, is characterized by a sudden increase in blood pressure in association with wide-spread endothelial dysfunction. Placenta-derived factors are believed to cause PE development. Our recent studies have identified that HtrA4, a placenta-specific serine protease may contribute to endothelial dysfunction. This study will investigate the mechanisms of HtrA4-induced endothelial dysfunction.
Epigenetic Reprogramming Within The Pluripotent Lineage Of The Early Embryo
Funder
National Health and Medical Research Council
Funding Amount
$663,050.00
Summary
Cells of the early embryo have the remarkable capacity to form all of the different tissues and organs in the body. This property requires re-organisation of the embryo’s genetic material in a manner analogous to re-booting a computer. This project will define the properties of this rebooting process. This information will allow much better strategies for building spare parts for regenerative medicine and provide the information required to reduce the incidence of inborn defects.
Advancing maternal age is associated with the progressive loss of fertility, increased miscarriage and a greater risk of bearing children with birth defects. These adverse reproductive outcomes result, in part, from the loss of egg quality with age. We aim to identify and characterise genes involved in the age-related decline in egg quality. The long-term goal of this research is to develop novel strategies to improve fertility outcomes for women who chose to delay pregnancy until later in life.
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
The Role Of Transcription Factors In Regulating The First Round Of Gene Expression In The Early Embryo.
Funder
National Health and Medical Research Council
Funding Amount
$348,931.00
Summary
Assisted reproductive technologies result in a high incidence of multiple births. This is and adverse outcome that requires correction. It stems from the common transfer of several embryos due to the low chance of an individual embryo made by IVF resulting in a baby. This project will determine the normal pattern of gene expression in the embryo and define: (1) how it is adversely changed as a consequence of IVF; and (2) the extent that these changes are a cause of the low embryo viability.
Mechanisms Of P53 Induced Embryopathy After In Vitro Fertilisation.
Funder
National Health and Medical Research Council
Funding Amount
$483,737.00
Summary
Assisted reproductive technologies (ART) cause many embryos not to survive to birth. We have shown that IVF causes increased expression of protein normally involved in stopping cells from dividing. This is a major cause of embryo death after IVF. This project will determine how this protein acts to cause embryonic death and assess strategies to prevent it.
A BubR1-centred Network For Non-invasively Measuring Human Oocyte Quality
Funder
National Health and Medical Research Council
Funding Amount
$532,207.00
Summary
Oocyte quality is the most important determinant of pregnancy outcome. Selecting the best oocytes for fertility treatments like IVF would therefore greatly improve success rates and reduce costs. We have identified master oocyte regulators and have applied novel digital technology to measure these regulators in a single oocyte. This project will apply this expertise to develop new approaches for evaluating an oocyte’s potential thereby informing its suitability for use in fertility treatment.