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.
Male-female Sperm Signalling - A Novel Pathway For Peri-conceptual Health?
Funder
National Health and Medical Research Council
Funding Amount
$674,920.00
Summary
This project will investigate a new biological process in reproduction, whereby sperm delivered to the cervix at coitus transmit signalling molecules called microRNAs that influence the female immune response, to increase the chances of conception and pregnancy. We will define the molecular details of this signalling pathway in mouse models, and then determine whether human sperm have a comparable function in ‘priming’ the female body to conceive.
The Characterisation Of An Essential Regulator Of Pre-mRNA Splicing Required For Germ Cell Function And Male Fertility
Funder
National Health and Medical Research Council
Funding Amount
$1,116,739.00
Summary
The male germ line is a fantastic system within which to define processes of fundamental importance to cell biology and health broadly. Within this grant we will define the role of a poorly described RNA splicing factor in all of stem cell function (spermatogonia), meiosis (spermatocytes) and in the remarkable metamorphosis underlying spermatid maturation. This will be done using a range of phenotypic characterizations, CHIP and RNA Seq technologies and gene sequencing.
Modulation Of MicroRNA Activity In The Testis: A New Paradigm For Male Fertility?
Funder
National Health and Medical Research Council
Funding Amount
$419,170.00
Summary
Sperm production in the testis is driven by the reproductive hormones, follicle-stimulating hormone (FSH) and testosterone. In this grant, we will investigate how a new class of molecules, called microRNAs, act to transmit the signals from FSH and testosterone to the cellular machinery of the testis, particularly at junctions between cells. This information has the potential to impact on our understanding of the causes of male infertility.
Reappraisal Of The Mechanisms Underlying Implantation Success Or Failure
Funder
National Health and Medical Research Council
Funding Amount
$750,755.00
Summary
Infertility affects 1:6 Australian couples; these seek help. However, for each IVF cycle, there is only ~18.5% chance of a live birth, significantly due to failure of embryo implantation. We discovered nano-vesicles in the uterine cavity, that are released from the womb lining and taken up by the pre-implantation embryo to improve its implantation potential. We will determine how this extracellular environment can enhance implantation success and circumvent/management of infertility.
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.
Re-energising The Preimplantation Embryo To Extend Lifetime Health
Funder
National Health and Medical Research Council
Funding Amount
$1,156,936.00
Summary
Diseases of aging are associated with shortening at the ends of chromosomes called telomeres. The length of an individual’s telomeres is established during embryo development, and in situations where embryo development is compromised such as with maternal obesity the normal process of telomere lengthening may not occur. We will determine how such disruptions in embryo telomere lengthening contribute to poor health in adulthood and test ways to restore the natural process.
Modulation Of Telomere Length And Subtelomeric DNA Methylation In Response To Oxidative Stress In The Male Germ Line; Implications For Tumorigenesis In The Offspring
Funder
National Health and Medical Research Council
Funding Amount
$310,684.00
Summary
This research project is designed to elucidate how the quality of a father’s spermatozoa can impact upon the health and wellbeing of his children. We hypothesize that factors, such as infertility, heavy smoking or age create a state of oxidative stress in the testes and that this stress influences the genetic structure of spermatozoa in such a way that the incidence of spontaneous mutations and susceptibility-to-cancer are significantly elevated in the offspring.
Inflammatory Cytokines As Causal Agents In Peri-conception Programming Of Offspring Health
Funder
National Health and Medical Research Council
Funding Amount
$604,046.00
Summary
Events at conception set the trajectory of fetal developmental that will determine health of children after birth and in later life. Susceptibility to obesity and metabolic conditions is established at this very early time. This project will define the molecular signals affecting the embryo in the event of maternal or paternal infection, diet and stress. The results will help us devise health advice for intending parents to improve child health and help prevent onset of metabolic disorders.
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.