Metabolic And Molecular Basis Of Embryo Signalling
Funder
National Health and Medical Research Council
Funding Amount
$409,836.00
Summary
Cells in the body are powered by mitochondria that essentially generate the energy required for development. This grant will determine how the environment affects the mitochondria in the developing embryo and determine the impacts to the embryo and pregnancy if a mitochondria is partially shut down.
Improving Oocyte Mitochondrial DNA Copy Number To Enhance Female Reproductive Capacity.
Funder
National Health and Medical Research Council
Funding Amount
$670,867.00
Summary
Eggs with too few copies of mitochondrial DNA either fail to fertilise or arrest during early development. By supplementing eggs with mitochondrial DNA, we have been able to enhance embryo quality and gene expression profiles. By breeding the offspring derived from eggs given mitochondrial supplementation, we will determine if they and their progeny meet normal developmental milestones, regulate the transmission of mitochondrial DNA appropriately, and are healthy and fertile.
Targeted Disruption Of Lipoxygenase Enzymes To Prevent Oxidative Stress-mediated Pathologies In The Male Germline
Funder
National Health and Medical Research Council
Funding Amount
$408,768.00
Summary
An estimated 80 million individuals suffer from infertility globally with at least 50% of these cases due to defects in sperm function. Unfortunately, due to a severe lack of knowledge surrounding sperm biology and dysfunction, no successful curative or preventative measures have been established. My project will study why sperm cells die and investigate new ways to limit cellular stress so we can develop new therapeutic strategies to mitigate the growing problems in male reproductive health.
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.