Hormonal Influences In The Pathogenesis Of Ovarian Tumours
Funder
National Health and Medical Research Council
Funding Amount
$264,601.00
Summary
Ovarian cancer is one of the most common malignancies affecting the female reproductive system. We have found that two types of tumour of the ovary produce a hormone called inhibin; these tumours are also known to produce the steroid hormone estrogen. In these studies we are seeking to determine the genetic changes in the tumours that cause the production of these hormones. We suspect that these genetic changes are also the same changes which contribute to the development of the cancers. In orde ....Ovarian cancer is one of the most common malignancies affecting the female reproductive system. We have found that two types of tumour of the ovary produce a hormone called inhibin; these tumours are also known to produce the steroid hormone estrogen. In these studies we are seeking to determine the genetic changes in the tumours that cause the production of these hormones. We suspect that these genetic changes are also the same changes which contribute to the development of the cancers. In order to identify these genes we will draw on our knowledge of the genes that are important in the controlof growth and hormone secretion in normal ovarian cells. To assist this molecular analysis we will use two ovarian cell lines in culture that have many of the features of the primary tumours including inhibin secretion. We will also use new techniques to scan over 500 genes involved in tumours in general to see whether we detect any unusual or distinctive patterns in this sub-group of tumours. A genome wide scanning technique will be used to seek changes in the DNA of the tumours, inparticular loss of genetic material or amplification of regions. Identification of the genetic changes within these tumours should enable better systems of classification, enhance prognostication and provide specific targets for the development of appropriate treatment strategies.Read moreRead less
The Formation And Development Of The Ovarian Follicular Membrana Granulosa
Funder
National Health and Medical Research Council
Funding Amount
$351,575.00
Summary
In order for the ovary to be able to release eggs and produce hormones such as oestrogen, follicles must grow within the ovary. Each follicle contains one egg and when the follicle is large and filled with fluid it can rupture, releasing the fluid and egg in the process of ovulation. A key part of the structure of the follicle is a non-cellular layer called the basal lamina. This basal lamina encapsulates the inner cells, the egg and the fluid in the follicle. Each women has millions of follicle ....In order for the ovary to be able to release eggs and produce hormones such as oestrogen, follicles must grow within the ovary. Each follicle contains one egg and when the follicle is large and filled with fluid it can rupture, releasing the fluid and egg in the process of ovulation. A key part of the structure of the follicle is a non-cellular layer called the basal lamina. This basal lamina encapsulates the inner cells, the egg and the fluid in the follicle. Each women has millions of follicles prior to her birth, ten of thousands in her reproductive years, and none at the menopause. Since she only ovulates about 500 in her lifetime most follicles die in the process of growing to ovulatory size. This project will examine the structure of the follicle wall and the cells that make up that wall. How these cells replicate during follicle growth has never been discovered. This research has important implications for the many women who have polycystic ovarian disease, whose follicles fail to grow to full size. We will be examining these ovaries directly. The research also has importance in the next phase of IVF developments.Read moreRead less
Studies Of The Dynamic Changes In The Ovarian Follicular Basal Lamina
Funder
National Health and Medical Research Council
Funding Amount
$305,557.00
Summary
In order for the ovary to be able to release eggs and produce hormones such as oestrogen, follicles must grow within the ovary. Each follicle contains one egg and when the follicle is large and filled with fluid it can rupture, releasing the fluid and egg in the process of ovulation. A key part of the structure of the follicle is a non-cellular layer called the basal lamina. This basal lamina encapsulates the inner cells, the egg and the fluid in the follicle. Each women has millions of follicle ....In order for the ovary to be able to release eggs and produce hormones such as oestrogen, follicles must grow within the ovary. Each follicle contains one egg and when the follicle is large and filled with fluid it can rupture, releasing the fluid and egg in the process of ovulation. A key part of the structure of the follicle is a non-cellular layer called the basal lamina. This basal lamina encapsulates the inner cells, the egg and the fluid in the follicle. Each women has millions of follicles prior to her birth, ten of thousands in her reproductive years, and none at the menopause. Since she only ovulates about 500 in her lifetime most follicles die during the process of growing to ovulatory size. This project will examine the follicular basal lamina in order to determine its role during follicle growth and development, and when follicles die. This has important implications for the many women who have polycystic ovarian disease, whose follicles fail to grow to full size. We will be examining these ovaries directly. The research also has importance in the next phase of IVF developments.Read moreRead less
This is a study of the biological system of epigenetics. Every cell in our body has the same genetics, or library of information contained in the form of DNA sequence. Epigenetics is the system that controls how this DNA is used in a particular situation, or what books are opened and read. During embryonic development, cells know what they want to become, e.g., a muscle cell, and, once they take on an identity, remember that they are when they duplicate themselves during growth. Epigenetics does ....This is a study of the biological system of epigenetics. Every cell in our body has the same genetics, or library of information contained in the form of DNA sequence. Epigenetics is the system that controls how this DNA is used in a particular situation, or what books are opened and read. During embryonic development, cells know what they want to become, e.g., a muscle cell, and, once they take on an identity, remember that they are when they duplicate themselves during growth. Epigenetics does not achieve this through changing genetics the library always stays intact. Rather, it acts by using proteins or chemicals to make DNA functional in one way, or another. Genomic imprinting is a special type of epigenetics. While an embryo has received identical genetic information from each of its parents, the epigenetic information received from each parent was not entirely the same. Some genes which behave differently according to what parent they came from. For example, a gene that makes a growth factor protein is active only if received from the father. If received from the mother, it is inactive, and makes no protein. Genes behaving in this way are known as imprinted genes. We are trying to discover what epigenetic mechanisms are behind this behaviour of imprinted genes. One way we are approaching this problem is to study germ cells the cells giving rise to eggs and sperm. These cells are unusual in that their imprinted genes behave in the same way regardless of whether they were received from the mother or father, i.e., like any other gene. If we can understand why this is the case, we will be better able to understand why imprinted genes behave the way they do in the rest of the cells of the body. Broadly, the mechanisms we uncover should further our understanding of germ cell development, gene expression, and disease. Perturbations in the epigenetic profile are likely causes of human disease, including cancer.Read moreRead less
The Role Of TAP And MHC Class I Expression In The Response To Melanoma Immunotherapy Using Autolgous Dendritic Cells
Funder
National Health and Medical Research Council
Funding Amount
$337,811.00
Summary
Treatment for patients with malignant melanoma whose disease has spread, or metastasised, to sites distant from the original melanoma is usually unsuccessful. At this stage of the disease there is no known curative treatment with conventional surgery, radiation or chemotherapy. Occasionally, however, melanoma in its early stages is successfully dealt with by the natural response of the immune system. In these cases, the immune system generates cancer-controlling killer T lymphocytes that enter t ....Treatment for patients with malignant melanoma whose disease has spread, or metastasised, to sites distant from the original melanoma is usually unsuccessful. At this stage of the disease there is no known curative treatment with conventional surgery, radiation or chemotherapy. Occasionally, however, melanoma in its early stages is successfully dealt with by the natural response of the immune system. In these cases, the immune system generates cancer-controlling killer T lymphocytes that enter the melanoma and kill the tumour cells. Killer T lymphocytes are generated by the lymph glands when the immune system is presented with melanoma cell components, or antigens, by specialised cells known as dendritic cells. This project consists of a clinical trial that aims to boost the natural ability of the immune system to generate killer cells by growing dendritic cells from the blood, mixing them with melanoma antigens, and then inject the mixture. When injected into the skin, dendritic cells quickly move to lymph glands to generate killer T lymphocytes. T lymphocytes can find their way to melanoma deposits all over the body. The reasons for response or non-response to the vaccination will particularly be assessed in this project.Read moreRead less
The Roles Of EZH2 And FOXO1A In CNS-PNET Pathogenesis.
Funder
National Health and Medical Research Council
Funding Amount
$467,517.00
Summary
Although CNS-PNETs are the most common embryonal CNS tumours of childhood and cause significant mortality and morbidity, there is a very limited understanding of the pathogenesis of this aggressive disease. This situation is a major handicap to the development of more specific and effective therapies. While a better understanding of the fundamental pathology of CNS-PNETs will have immediate diagnostic implications, the elucidation of the biochemical pathways that are disrupted in these tumours w ....Although CNS-PNETs are the most common embryonal CNS tumours of childhood and cause significant mortality and morbidity, there is a very limited understanding of the pathogenesis of this aggressive disease. This situation is a major handicap to the development of more specific and effective therapies. While a better understanding of the fundamental pathology of CNS-PNETs will have immediate diagnostic implications, the elucidation of the biochemical pathways that are disrupted in these tumours will facilitate the design of new drugs that are specifically directed towards the critical proteins in these pathways. The identification of specific genes and-or pathways that are deregulated in CNS-PNET cells is essential for the development of safer, more directed, and more effective therapies that are urgently required for the treatment of those with this devastating disease.Read moreRead less
Why We Have Two Estrogen Receptors: The Role Of ERbeta In Folliculogenesis.
Funder
National Health and Medical Research Council
Funding Amount
$576,053.00
Summary
The female hormone estrogen acts via receptors ERalpha and ERbeta. Little is known about the genes and proteins regulated by ERbeta. Ovarian granulosa cells and granulosa cell tumours express ERbeta. By studying the biology of normal and malignant granulosa cells we hope to understand the role that ERbeta plays in granulosa cells. These studies will identify areas for the development of new therapeutics or treatment strategies for a range of female-specific conditions including ovarian cancer.
Development Of A Novel Therapy For The Treatment Of Epidermal Squamous Cell Carcinoma
Funder
National Health and Medical Research Council
Funding Amount
$432,750.00
Summary
Squamous cell carcinomas (SCC) are the most common life-threatening form of skin cancer in Australia. SCCs commonly arise in areas of the body that have been exposed to excessive amounts of UV irradiation. The cells of the skin from which SCCs are derived are called keratinocytes. UV irradiation causes lesions within these cells such that their growth and maturation are disrupted leading to deregulated growth and maturation and hence tumour formation. We have previously identified a protein, E2F ....Squamous cell carcinomas (SCC) are the most common life-threatening form of skin cancer in Australia. SCCs commonly arise in areas of the body that have been exposed to excessive amounts of UV irradiation. The cells of the skin from which SCCs are derived are called keratinocytes. UV irradiation causes lesions within these cells such that their growth and maturation are disrupted leading to deregulated growth and maturation and hence tumour formation. We have previously identified a protein, E2F, that is central to this process and whose inhibition leads to decreased cancer cell growth. During the course of these studies we noted that the deregulation of E2F could also lead to the disruption of keratinocyte maturation. This led us to propose that the inhibition of E2F in SCCs may result in both decreased cancer cell growth as well as the reinstatement of a normal maturation process. this would make E2F inhibitors a very attractive therapeutic for treating SCC. In the present study we aim to explore the ability and the mechanism by which E2F modulates keratinocyte proliferation and maturation. This will be done in vitro as well as in animal models of SCC. These studies will be required in order to take the E2F inhibitors into clinical trials.Read moreRead less
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