Roles Of The Nuclear Growth Hormone Receptor In Cell Proliferation And Survival
Funder
National Health and Medical Research Council
Funding Amount
$429,387.00
Summary
We have discovered that the cell surface receptor for growth hormone travels to the cell nucleus in dividing cells, including cancer cells. Given the role of growth hormone in promoting growth postnatally, we seek to uncover how the nuclear receptor promotes proliferation directly, and by gene splicing. We have identified strong candidates for its direct actions through proteomics, and a DNA binding site for the receptor. Here we will investigate its role in proliferation, gene splicing and DNA ....We have discovered that the cell surface receptor for growth hormone travels to the cell nucleus in dividing cells, including cancer cells. Given the role of growth hormone in promoting growth postnatally, we seek to uncover how the nuclear receptor promotes proliferation directly, and by gene splicing. We have identified strong candidates for its direct actions through proteomics, and a DNA binding site for the receptor. Here we will investigate its role in proliferation, gene splicing and DNA strand break repair after cell irradiation.Read moreRead less
Determinants Of Tissue- And Ligand-Specific Responses At The Mineralocorticoid Receptor
Funder
National Health and Medical Research Council
Funding Amount
$668,485.00
Summary
The steroid hormone aldosterone controls salt balance and hence, blood pressure. It also has been shown to have a significant role in cardiac failure. Although drugs that block the aldosterone receptor are beneficial in the treatment of heart failure, they are limited by potassium retention in the kidney. In order to develop tissue-specific blockers of the aldosterone receptor, it is necessary to identify mechanisms by which the receptor can be activated and/or blocked in specific tissues.
Mineralocorticoid Receptor Blockade: Mechanisms Of Selectivity
Funder
National Health and Medical Research Council
Funding Amount
$540,270.00
Summary
The steroid hormone aldosterone controls salt balance and hence, blood pressure. It also has been shown to have a significant role in cardiac failure. Although drugs that block the aldosterone receptor are beneficial in the treatment of heart failure, they are limited by potassium retention in the kidney. In order to develop tissue-specific blockers of the aldosterone receptor, it is necessary to identify mechanisms by which the receptor can be activated and/or blocked in specific tissues.
ERRgamma And Skeletal Muscle: Insights Into Lipid Utilization And Catabolism
Funder
National Health and Medical Research Council
Funding Amount
$357,936.00
Summary
The significance of Nuclear hormone receptors (NRs) in disease is underscored by the range of pharmacopoeia for the treatment of NR-associated disorders (e.g 16% of the top 100 drugs target NRs). ERRgamma receptors are abundantly expressed in skeletal muscle, a major mass periperal tissue that acconts for ~40% of total body weight, and energy expenditure. Muscle is the major site of glucose metabolism and, fatty acid oxidation. Consequently, it has a significant role in insulin sensitivity, the ....The significance of Nuclear hormone receptors (NRs) in disease is underscored by the range of pharmacopoeia for the treatment of NR-associated disorders (e.g 16% of the top 100 drugs target NRs). ERRgamma receptors are abundantly expressed in skeletal muscle, a major mass periperal tissue that acconts for ~40% of total body weight, and energy expenditure. Muscle is the major site of glucose metabolism and, fatty acid oxidation. Consequently, it has a significant role in insulin sensitivity, the blood lipid profile, lipid metabolism and obesity. Understanding the functional role of the orphan ERR receptors in skeletal muscle in the context of inflammation, lipid and energy homeostasis is of paramount importance in further understanding the mechanistic basis of dyslipidemia, chronic inflammation, insulin sensitivity, diabetes and obesity. Identification of novel ERRgamma targets that regulate metabolism in a major mass peripheral tissue, and positively influence the risk factors for cardiovascular disease, provides platforms for potential therapeutic intervention. Cardiovascular disease is the foremost cause of global mortality, and was responsible for >15 million deaths in 2003.Read moreRead less
NR1 Nuclear Hormone Receptors, And Skeletal Muscle Metabolism: Insights Into Dyslipidemia And Metabolic Disease.
Funder
National Health and Medical Research Council
Funding Amount
$582,547.00
Summary
The significance of Nuclear hormone receptors (NRs) in disease is underscored by the range of pharmacopoeia for the treatment of NR-associated disorders (e.g 16% of the top 100 drugs target NRs). Orphan NR1 receptors are abundantly expressed in skeletal muscle, a major mass peripheral tissue that accounts for ~40% of total body weight, and energy expenditure. Muscle is the major site of glucose metabolism and, fatty acid oxidation. Furthermore, it is an important regulator of cholesterol homeost ....The significance of Nuclear hormone receptors (NRs) in disease is underscored by the range of pharmacopoeia for the treatment of NR-associated disorders (e.g 16% of the top 100 drugs target NRs). Orphan NR1 receptors are abundantly expressed in skeletal muscle, a major mass peripheral tissue that accounts for ~40% of total body weight, and energy expenditure. Muscle is the major site of glucose metabolism and, fatty acid oxidation. Furthermore, it is an important regulator of cholesterol homeostasis and HDL levels. Consequently, it has a significant role in insulin sensitivity, the blood lipid profile, lipid metabolism and obesity. Understanding the functional role of the orphan NR1 receptors in skeletal muscle in the context of inflammation, lipid and energy homeostasis is of paramount importance in further understanding the mechanistic basis of dyslipidemia, chronic inflammation, insulin sensitivity, diabetes and obesity. Identification of novel NR1 targets that regulate metabolism in a major mass peripheral tissue, and positively influence the risk factors for cardiovascular disease, provides platforms for potential therapeutic intervention. Cardiovascular disease is the foremost cause of global mortality, and was responsible for >15 million deaths in 2003.Read moreRead less
Steroid hormones, such as estrogen and androgens, act in the body by locking onto a family of proteins (nuclear receptors) that bind directly to the DNA to regulate genes. The mechanisms underlying this process are complex and involve recruitment of additional molecules or coactivators to improve efficiency. Recently a novel coactivator was identified, termed SRA, which exerts its effects as an RNA, rather than as a protein. SRA is aberrantly expressed in breast cancer, raising the possibility t ....Steroid hormones, such as estrogen and androgens, act in the body by locking onto a family of proteins (nuclear receptors) that bind directly to the DNA to regulate genes. The mechanisms underlying this process are complex and involve recruitment of additional molecules or coactivators to improve efficiency. Recently a novel coactivator was identified, termed SRA, which exerts its effects as an RNA, rather than as a protein. SRA is aberrantly expressed in breast cancer, raising the possibility that it plays an important role in breast cancer cell proliferation. To better understand how estrogen signals in breast cancer and identify proteins that bind to SRA in cancer cells, we established a collaboration with the O'Malley group at Baylor College of Medicine in Texas (who discovered SRA). We have identified several novel SRA-binding proteins, each of which plays an important role to regulate estrogen and androgen action. Up to this point, we have used a model that has enabled proof of principle studies in the same cancer cells from which SRA was discovered (non-breast or prostate cancer). However, we now need to carefully study the role of these proteins in cancer cells relevant to breast and prostate cancer. Thus, we plan to investigate how these proteins interact with SRA, how they influence nuclear receptor activity and breast and prostate cancer cell proliferation, examine their role in activating other pathways of cell growth in cancer cells, assay the levels of each protein in a series of human breast cancer specimens and solve the physcial 3-D structure of these proteins complexed to the SRA RNA. This work will provide novel insight into several key areas of hormone action in breast and prostate cancer. We hope to identify new markers that can be used for improved diagnosis and for prognosis, and provide structural information for the development of novel therapeutics.Read moreRead less