The Physiological Role Of Calcitonin And Its Receptor In Bone Cell Metabolism.
Funder
National Health and Medical Research Council
Funding Amount
$496,446.00
Summary
Throughout adult life, bone tissue is continuously remodelled. The two main processes involved in bone remodelling, are bone formation and bone breakdown. Bone formation is controlled by cells known as osteoblasts and bone breakdown is controlled by cells known as osteoclasts. Under normal circumstances these two processes are tightly coupled. Excessive breakdown of bone, causes these two processes to become unbalanced and results in bone loss. This is the basis of many bone diseases such as ost ....Throughout adult life, bone tissue is continuously remodelled. The two main processes involved in bone remodelling, are bone formation and bone breakdown. Bone formation is controlled by cells known as osteoblasts and bone breakdown is controlled by cells known as osteoclasts. Under normal circumstances these two processes are tightly coupled. Excessive breakdown of bone, causes these two processes to become unbalanced and results in bone loss. This is the basis of many bone diseases such as osteoporosis, a condition in which the bones become fragile and therefore more susceptible to fracture. 1 in 2 women and 1 in 3 men aged 70 years and older suffer from osteoporosis in Australia. Despite this, the mechanisms which control osteoclast breakdown of bone are not well understood. Our laboratory is interested in how hormones affect osteoclast action. We plan to examine the role of the hormone calcitonin, an important inhibitor of osteoclastic bone breakdown. This will be achieved by studying transgenic mice in which the receptor, or target, for calcitonin is specifically removed from osteoclasts. This will allow us to precisely determine the role of calcitonin in osteoclast function. Data generated by our research group indicates that calcitonin is also involved in controlling bone formation, however, the way in which calcitonin acts on osteoblasts remains poorly understood. Therefore, studying our transgenic mice will also help clarify the role calcitonin plays in bone formation. Current treatment for osteoporosis involves the administration of drugs which inhibit bone breakdown. This project will increase our understanding of how calcitonin acts to regulate bone breakdown and bone formation and may assist in the design of new therapies for osteoporosis. We believe that this research is of great importance as osteoporosis is becoming more prevalent as the population ages.Read moreRead less
Role And Mechanism Of Connective Tissue Growth Factor In Diabetic Cardiomyopathy
Funder
National Health and Medical Research Council
Funding Amount
$382,820.00
Summary
Diabetic cardiomyopathy is a condition where the heart muscle is directly damaged by diabetes. It is being recognised as a prominent cause of both acute and chronic heart failure in diabetes. It is common and occurs in up to 60% of diabetic patients . At present however, no treatments are available to directly treat the cardiomyopathy. This condition can also occur in people with diabetes who have high blood pressure and-or coronary artery disease and may combine with these problems to worsen pa ....Diabetic cardiomyopathy is a condition where the heart muscle is directly damaged by diabetes. It is being recognised as a prominent cause of both acute and chronic heart failure in diabetes. It is common and occurs in up to 60% of diabetic patients . At present however, no treatments are available to directly treat the cardiomyopathy. This condition can also occur in people with diabetes who have high blood pressure and-or coronary artery disease and may combine with these problems to worsen patient outcomes. We have generated data in experimental diabetes in rodents that strongly implicates a heart growth factor in causing diabetic cardiomyopathy. This protein, called connective tissue growth factor (CTGF), is increased in diabetic cardiomyopathy, and is elevated by high glucose and other factors in diabetes. We have published data showing that CTGF causes tissue scarring like that which occurs in cardiomyopathy, by affecting signals in cells called fibroblasts. It increases the laying down of extracellular matrix (ECM) and also inhibits the degradation of ECM by the proteins that break down matrix, known as the MMPand PAI systems. Such accumulation of ECM is thought to be a major factor leading to abnormal muscle function in cardiomyopathy. We now plan to block CTGF in this diabetic heart model to determine if we can prevent diabetic cardiomyopathy. We have generated two methods to inhibit CTGF in the animal model. Echocardiography (a heart ultrasound test), and molecular analysis of the heart tissue will determine if we can prevent the otherwise adverse functional and structural changes of diabetes in the heart. We will also study our baboon model of diabetes to determine if diabetic cardiomyopathy with increased heart CTGF is present in the primates. Cell culture studies from rat heart fibroblasts and myocytes will determine how CTGF has the effect on cells to cause cardiomyopathy and how we might further prevent this condition developing in diabetes.Read moreRead less
Genomic And Non-genomic Actions Of Androgens In Regulation Of Fat Mass And Metabolism
Funder
National Health and Medical Research Council
Funding Amount
$395,421.00
Summary
Men have lower amounts of body fat than women, but are more likely to deposit fat around the stomach and abdominal region than women. This increased abdominal fat in men significantly increases the risk of developing type 2 diabetes and heart disease. The differences between men and women suggest that there is hormonal control of fat development; however, little is known regarding how male sex hormones, androgens, control these processes. We will investigate how androgens control fat formation, ....Men have lower amounts of body fat than women, but are more likely to deposit fat around the stomach and abdominal region than women. This increased abdominal fat in men significantly increases the risk of developing type 2 diabetes and heart disease. The differences between men and women suggest that there is hormonal control of fat development; however, little is known regarding how male sex hormones, androgens, control these processes. We will investigate how androgens control fat formation, and the response of fat and muscle tissue to glucose and insulin, using mutant mouse strains. These mouse strains have a mutation in the androgen receptor, a protein which acts as a key-lock mechanism to allow tissues to respond to androgens. This mutation stops the androgen receptor from functioning, so these mice can be used to determine the function of androgens acting through the androgen receptor. We will study three strains of mutant mice: (i) in which the androgen receptor is non-functional in all tissues of the body; (ii) in which the androgen receptor is non-functional only in fat tissue, but normal in all other tissues; and (iii) in which the androgen receptor is non-functional only in skeletal muscle, but is normal in all other tissues. The aim of our research is to determine the effect of the mutations in these three different mouse lines on paramateres including the amount of fat formed, the site of fat deposition, the levels of lipids and insulin in the blood and their response to glucose. The androgen receptor is a master switch that turns on or off other genes. Therefore, we also aim to identify which genes are controlled by the androgen receptor in fat and muscle. This research will identify how androgens control fat development and function, and will identify genes that mediate these actions in fat and muscle. This will provide potential molecules that could be used therapeutically to treat obesity and prevent type 2 diabetes and heart disease.Read moreRead less
An obesity epidemic is evident in first world countries including Australia. Twenty seven percent of men aged 55-64 in this country are obese. Obesity results in increased mortality and morbidity from type 2 diabetes, cardiovascular disease, renal disease and endometrial cancer, among others. Given our flaccid lifestyles, it is imperative that the metabolic processes underlying obesity be fully understood, to allow development of suitable treatment modalities. This proposal seeks to establish an ....An obesity epidemic is evident in first world countries including Australia. Twenty seven percent of men aged 55-64 in this country are obese. Obesity results in increased mortality and morbidity from type 2 diabetes, cardiovascular disease, renal disease and endometrial cancer, among others. Given our flaccid lifestyles, it is imperative that the metabolic processes underlying obesity be fully understood, to allow development of suitable treatment modalities. This proposal seeks to establish an important new element in our understanding of the development of obesity, the transcription factor STAT5. With previous NHMRC support, we developed sophisticated genetically modified mice which lack defined signalling processes initiated by growth hormone, an anti-obesity agent. These studies showed a strong correlation between ability to activate STAT5 and resistance to obesity. There is fragmentary literature evidence to support our hypothesis, which could also explain some of leptins anti-obesity actions. Using mice which lack STAT5, we shall establish a role for STAT5 as an antiobesity agent. The actions of STAT5 are normally blocked by feedback inhibitors referred to as SOCS, discovered by Australians. We shall define which SOCS is the feedback regulator for obesity control, allowing us to develop specific anti-SOCS agents which will act as novel anti-obesity agents.Read moreRead less