The Mechanism Of Spermatid Differentiation - A Link To Tumour Suppression
Funder
National Health and Medical Research Council
Funding Amount
$506,425.00
Summary
To discover novel regulators of male fertility, we have screened libraries of mutant mice generated by a chemical mutagen. This project aims to define the function of the mutated gene identified in a male-specific infertile mutant mouse line. The mutated gene has been proposed to play a role in regulating cell death and suppress lung tumour formation. Our data may reveal novel options for male infertility treatment and for the development of male contraception and lung cancer biomarkers.
Role Of Tumour Suppressor Genes In Early Embryopathy
Funder
National Health and Medical Research Council
Funding Amount
$408,000.00
Summary
Assisted reproductive technologies (ART, such as IVF and related techniques) are successful treatments for most forms of infertility. Much of this is due to the high mortality of the resulting embryos. Typically, 45-80% of embryos produced by ART do not survive the first week. The high mortality of the early embryo seems to be a general feature of ART but its causes and effectors are incompletely defined. It has been established that this high mortality is largely due to a marked retardation in ....Assisted reproductive technologies (ART, such as IVF and related techniques) are successful treatments for most forms of infertility. Much of this is due to the high mortality of the resulting embryos. Typically, 45-80% of embryos produced by ART do not survive the first week. The high mortality of the early embryo seems to be a general feature of ART but its causes and effectors are incompletely defined. It has been established that this high mortality is largely due to a marked retardation in the rate of cell cycle progression by embryo cells, and commonly is associated with a form of cell 'suicide', known as apoptosis. In non-embryonic cells a group of genes known as the tumour suppressor genes (TSGs) are responsible for slowing cell-cycle progression and are commonly involved in inducing apoptosis following cell stress. The role of TSGs in the early embryo is not well studied. We have recently shown that the most important of the TSGs, P53, is normally kept at very low levels in the early embryo but that ART causes up-regulation of its expression. This upregulation is a major cause of the embryopathy associated with ART in an animal model but that genetic mutations that prevent P53 expression favours increased embryo development and viability. This project will examine whether ART also causes up-regulation other important TSGs and whether this occurs in human embryos. We will examine the hypothesis that ART increases the survival of embryos with mutations to the P53 gene (creating a postive genetic selection pressure in favour of these mutations); and which aspects of ART cause this positive selection. The project will demonstarte whether changes in the ART procedures have the potential to mitigate against selection of embryos bearing deletrious mutations.Read moreRead less
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
I am a basic scientist with an interest in the cellular biology of the ovary, and the roles of the matrix between cells of the ovary in controlling fertility and hormone synthesis.
Katanin P80 Is A Key Regulator Of Microtubule Dynamics And Male Fertility.
Funder
National Health and Medical Research Council
Funding Amount
$603,756.00
Summary
Male fertility is a complex process requiring the co-ordinated activation of thousands of gene products. It is not surprising therefore that 1 in 15 Australian men are infertile. This project will explore an essential pathways for sperm production, specifically related to sperm shaping and motility. This work may ultimately have implications for the diagnosis and treatment of male infertility, but also for pathology in tissues will similar cellular structures.
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.