Male fertility requires sufficient production of healthy sperm in the testis. We discovered that cells in the adult testis communicate via the Hedgehog (Hh) signalling pathway as sperm develop. We propose to use a highly specific drug to inhibit Hh activity in order to delineate the precise steps in sperm production affected by Hh signalling. We will study the importance Hh in maintenance of spermatogonial stem cells and create mouse models to learn how it is controlled.
Understanding Epigenetic Modification During Oogenesis For Novel Treatments Of Female Infertility
Funder
National Health and Medical Research Council
Funding Amount
$314,644.00
Summary
Infertility affects about 10% of Australian women and the success rates of current infertility treatments are low due to our poor knowledge of eggs development. The numbers of obese and older women trying to conceive are increasing; fertility treatments are even less effective for them. I have generated mouse models to elucidate the pathways regulating egg development. I will study for alterations in these pathways in the mouse models which perfectly mimic the obesity and aging in women.
Activin And Androgen Crosstalk During Testis Development Programs Adult Fertility
Funder
National Health and Medical Research Council
Funding Amount
$700,740.00
Summary
Fertility in men is determined by how the testis grows during fetal and juvenile life. We recently discovered that the Sertoli cells which nurse developing sperm are highly sensitive to cross-talk between testosterone and the growth factor activin during puberty. This project studies how this cross-talk is controlled to understand how altered hormone actions in boys, including exposure to harmful endocrine disrupting chemicals, reduces adult fertility.
The Role Of Stem-progenitor Cells In Regeneration Of Mouse Endometrium.
Funder
National Health and Medical Research Council
Funding Amount
$311,938.00
Summary
The endometrium (lining of the uterus) undergoes breakdown and re-growth each month as part of the menstrual cycle. This restorative process is not well understood. For the first time stem cells have been identified within human endometrium that are likely to be responsible for its remarkable regeneration. The aim of this project is to identify stem cells within the mouse endometrium, to use as a model to understand how the endometrium restores each month after menstruation.
Differentiation Of Murine Embryonic Stem Cells To The Female Germ Line
Funder
National Health and Medical Research Council
Funding Amount
$57,342.00
Summary
In this project we aim to establish techniques to obtain viable and developmentally competent eggs from embryonic stem (ES) cells for studies on the molecular and cellular mechanisms of sex cell production. We expect to achieve ES cell derived eggs with similar fertilization and developmental potential as eggs developed naturally. Sterility resulting from cancer treatments and from genetic and non-genetic malformations can benefit from this ES cell therapy.
Male fertility requires sufficient production of healthy sperm in the testis. This project builds on our discovery that testicular cells communicate via the wnt family of proteins during sperm development, and that interruption of their activities reduces fertility in mice. We propose to use mouse models to study the precise steps in sperm production affected by Wnt signalling and how it works.
Determing Whether Breast Stem Cells Mediate The Risk Of Developing Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$433,894.00
Summary
Whilst the outcomes for women with breast cancer have improved significantly, the incidence of breast cancer continues to increase. Research needs to focus on prevention now to try to stop the increase. Apart from age, our reproductive behaviour is the largest risk factor for breast cancer. If a woman does not bear children, or has them after 35 years of age, she is at 25-50% increased risk of breast cancer. We would like to determine whether the breast stem cells play a role in this and why.
Growth Factors And Regulatory Genes Controlling Male Spermatogonial Proliferation And Differentiation.
Funder
National Health and Medical Research Council
Funding Amount
$354,536.00
Summary
In newborn and prepubertal boys the testis contains germ cells which are at a premature stage of development and very suseptible to degeneration especially if the testes fail to descend to the scrotum. The molecules which are responsible for the health of these germ cells have been unknown and only recently the way has been opened for direct study of these factors. This has been made possible by a new assay, developed in our labarotory, in which we can grow these germ cells under defined conditi ....In newborn and prepubertal boys the testis contains germ cells which are at a premature stage of development and very suseptible to degeneration especially if the testes fail to descend to the scrotum. The molecules which are responsible for the health of these germ cells have been unknown and only recently the way has been opened for direct study of these factors. This has been made possible by a new assay, developed in our labarotory, in which we can grow these germ cells under defined conditions. This step forward has highlighted some areas of knowledge which need further research such as identification of the processes which stimulate gonocytes to grow and divide. We need to test growth factors, somatic cell factors and also isolate new genes which are associated with germ cells and their growth. This knowledge will have outcomes in two major areas. First, the new findings could be applied to treatment of infertility resulting from undescended testes in which a stimulus could be given to make the germ cells grow again. Second, work in developing longer term culture of germ cells coupled with introduction of mutations will enable us to make mutant mice with a specific gene abnormality, similar to transgenic or gene knockout mice. This technological development would prove less expensive and time consuming with more reproducible and direct outcomes. Mutant mouse technology is a powerful tool to determine the effects of individual genes in the whole animal (mouse).Read moreRead less