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.
A man's reproductive health and fertility is affected by processes that occur long before adulthood. The testis and sperm precursor cells first form in the fetus and then grow until the time of puberty, when the upper limit for sperm production is set. This project studies how one key signaling molecule, activin, helps establish normal testicular architecture and drives maturation of sperm precursor cells, and how it contributes to aberrent function in men with testicular cancer.
Role Of Snail Family Proteins In Male Fertility And Testicular Cancer
Funder
National Health and Medical Research Council
Funding Amount
$586,076.00
Summary
Male fertility requires production of healthy sperm in the testis. This project builds on our discoveries that testicular cells regulate gene activity via the Snail family of proteins during sperm development, and that interruption of their activities reduces fertility in mice and fruitflies. Snail proteins are also active in cancer cells. We propose to study the precise steps in sperm production affected by Snail proteins and how they affect the progression of testicular cancer.
I seek the knowledge required to improve prevention, diagnosis and therapy for men with testicular pathologies by studying what controls early sperm development. My research will delineate how cellular signalling molecules lay the foundation for adult fertility, using animal studies, cell culture and clinical samples. Testis samples from testicular cancer patients will be used to test interventions that may kill tumour cells or offer a therapeutic option to men with impaired spermatogenesis.
Persistent Chlyamdial Infection In The Testes : Development Of A Successful Vaccine Strategy For Males
Funder
National Health and Medical Research Council
Funding Amount
$652,019.00
Summary
Males are a reservoir of infection and novel vaccine approaches to control Chlamydia infections in young men are needed urgently. This study will be essential for the development of interventions to control infection and will inform strategies for manipulating the immune system within the male reproductive tract that may be applied to other sexually transmitted pathogens. The studies will benefit the health and welfare of the Australian people under National Research Priority 2, promoting and ma ....Males are a reservoir of infection and novel vaccine approaches to control Chlamydia infections in young men are needed urgently. This study will be essential for the development of interventions to control infection and will inform strategies for manipulating the immune system within the male reproductive tract that may be applied to other sexually transmitted pathogens. The studies will benefit the health and welfare of the Australian people under National Research Priority 2, promoting and maintaining good health and a healthy start to life.Read moreRead less
I am a clinician-scientist with a focus on basic and translational research in male reproductive physiology and health disorders, notably infertility, contraception and androgen action.
6% of Australian men are infertile. Of these cases 50% are thought to be genetic in origin. Within this project we will replicate high-confidence genetic variants associated with human male infertility in the mouse. Doing so will allow the assignment of definitive genotype-phenotype correlations and the formulation of high confidence advice for clinicians and patients. It will also provide a means to define the mechanism of action and the tools for future pro-fertility treatments.
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.