I am a reproductive biologist working to define key mechanisms for sperm development and function; and by extension the causes of human male infertility.
The Structural Basis Of The Interaction Of Insulin-like Peptide 3, A Key Regulator Of Fertility, With Its Receptor.
Funder
National Health and Medical Research Council
Funding Amount
$555,693.00
Summary
The hormone, insulin-like peptide 3, has recently been shown to act directly on male and female germ cells to cause their maturation. It has considerable promise as a therapeutic agent for the regulation of fertility. Drugs based on the peptide may be used to assist in cases of infertility, and drugs that block its action have great potential as male and female contraceptives. Towards these goals, our project aims to understand how this peptide exerts its unique biological effects.
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.
Hormonal Control Of Serotli Cell Maturation And Function
Funder
National Health and Medical Research Council
Funding Amount
$512,898.00
Summary
This project will determine the key roles of androgen in the Sertoli cell, a unique highly specialised cell that provides essential nutritional and structural support for sperm production. Androgen acts via the androgen receptor (AR), which is vital for initiating and maintaining sperm development. In current NHMRC-funded research we successfully established new mouse models designed to study AR, in particular its regulation of gene expression, in the Sertoli cell. We revealed that genomic AR ac ....This project will determine the key roles of androgen in the Sertoli cell, a unique highly specialised cell that provides essential nutritional and structural support for sperm production. Androgen acts via the androgen receptor (AR), which is vital for initiating and maintaining sperm development. In current NHMRC-funded research we successfully established new mouse models designed to study AR, in particular its regulation of gene expression, in the Sertoli cell. We revealed that genomic AR activity within Sertoli cells is essential for 'induction' of complete sperm development. Ongoing work will develop unique 'inducible' transgenic models that will allow, for the first time, selective analysis of Sertoli AR in both 'developing' and 'adult' testes. Our innovative models will allow AR function to be switched on or off at any stage of development, providing unique opportunity to determine the key AR-regulated factors and pathways controlling induction, maintenance or restoration of sperm production. In past NHMRC research we created a novel transgenic model to study another major reproductive hormone, FSH. Using the hormone-deficient background of 'hpg' mice, we found that androgen and FSH act synergistically in the developing 'meiotic' germ cells that form sperm. Using the latest microarray gene technology we generated datasets of androgen-regulated genes with or without FSH activity, which combined with our unique transgenic AR and FSH models, will be used to identify key pathways, including those enhanced by androgen-FSH synergism, in the early testicular response. Our research will provide new knowledge of the precise roles and pathways of testicular AR actions, to ultimately identify key genetic and regulatory factors as targets for significantly improved therapy for male infertility, gonadal tumours, or contraception.Read moreRead less
The Sertoli Cell: Master Regulator Of Hormone-induced Spermatogenic Development
Funder
National Health and Medical Research Council
Funding Amount
$563,536.00
Summary
This project will determine the key roles of major hormones (testosterone, follicle-stimulating hormone, Vitamin A) in Sertoli cells, unique highly specialised cells found in the testis that provide essential nutritional and structural support for sperm production. This research will provide new understanding of the biological pathways controlling sperm development, leading to new molecular targets for infertility or cancer treatment or diagnosis, or new contraceptive strategies for men.
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
A New Model Of Asthenospermia And A Candidate Gene For Multiple Ciliopathies
Funder
National Health and Medical Research Council
Funding Amount
$629,039.00
Summary
Though the analysis of a unique mouse strain (Mot1) we have identified a previously unknown cause of male infertility and lung disease. We hypothesis that the Mot1 line is a model of human primary cilia dyskinesia and that the Mot1 protein is involved in cilia function. Within this project we will define the consequences of a loss of Mot1 protein function, we will define its binding partners and we will screen for mutations in the corresponding human gene.
Approximately 1 in 25 men in the western world are infertile, and while environmental and genetic factors are recognized to contribute to disease, there is currently a poor understanding of the basic mechanisms regulating male fertility. Our long term goal is to identify and study key molecules involved in sperm production. Understanding the role of these molecules will provide insight into the causes of male infertility. Ultimately, these studies will assist to develop new treatments for male r ....Approximately 1 in 25 men in the western world are infertile, and while environmental and genetic factors are recognized to contribute to disease, there is currently a poor understanding of the basic mechanisms regulating male fertility. Our long term goal is to identify and study key molecules involved in sperm production. Understanding the role of these molecules will provide insight into the causes of male infertility. Ultimately, these studies will assist to develop new treatments for male reproductive disorders. Conversely, there is a huge need for additional male based contraceptives. Increased understanding of male fertility and identification of proteins exclusively involved in sperm production provides the opportunity to develop new contraceptive treatments.Read moreRead less
The Role Of MiRNAs In The Regulation Of Sperm Maturation
Funder
National Health and Medical Research Council
Funding Amount
$396,157.00
Summary
Male infertility is an extremely common condition affecting 1 in 20 Australian men. One of the major reasons for this pathology is that the spermatozoa have lost their ability to recognize the egg, a function that is acquired during epididymal maturation. In this project we shall investigate the regulation of epididymal sperm maturation and thus provide new and powerful insights into the causes of male infertility, with practical implications for diagnosis and treatment of this condition.