Biological Function Of The Chemokine Receptor 6 Expression On B Cells
Funder
National Health and Medical Research Council
Funding Amount
$241,500.00
Summary
The correct movement of cells is important for the defence of the body against micro-organisms. White blood cells have to arrive quickly at the site of an infection and information about this infection has to be spread. White blood cells that navigate the body are using molecules on their surface termed as receptors which help them to detect the scent of their target. One of these receptors is located on white blood cells that produce antibodies and enables these cells to migrate to appropriate ....The correct movement of cells is important for the defence of the body against micro-organisms. White blood cells have to arrive quickly at the site of an infection and information about this infection has to be spread. White blood cells that navigate the body are using molecules on their surface termed as receptors which help them to detect the scent of their target. One of these receptors is located on white blood cells that produce antibodies and enables these cells to migrate to appropriate tissues . We want to know more about the biological role of this receptor and its functions during the immune response to pathogens. It would be of significant importance to understand the impact of these cell surface receptors in detail because this could open the possibility to new therapies of infectious diseases and chronic inflammation.Read moreRead less
The In Vivo And In Vitro Biology Of The Novel Intracellular Ion Channel CLIC1 (NCC27)
Funder
National Health and Medical Research Council
Funding Amount
$432,750.00
Summary
Ion channels are complex proteins that regulate the transports of salts, and essential cell function. We have recently cloned a new ion channel, CLIC1, unique in its location on the nuclear membrane as well as other sites. The function of this channel is uncertain, although we have suggested its association with cell growth and inflammation. We propose to investigate the function of CLIC1, dominantly based on gene knockout animals, in which the CLIC1 gene has been deleted.
The Mechanisms Of The Anabolic Actions Of Androgens In Bone.
Funder
National Health and Medical Research Council
Funding Amount
$470,960.00
Summary
Androgens (male sex hormones) are one of the few agents that increase bone formation. Androgens act by binding to a specific protein, the androgen receptor (AR). To understand exactly how androgens increase bone formation, we will study mice in which the AR is inactivated only in bone forming cells at specific stages of their development. Understanding the way in which androgens act on bone to increase size and strength will be of great benefit in the design of new treatments for osteoporosis.
The Role Of Androgens In Osteoblast Development And Bone Metabolism.
Funder
National Health and Medical Research Council
Funding Amount
$487,500.00
Summary
Maintenance of the skeleton involves the processes of bone formation by cells known as osteoblasts and bone breakdown by cells known as osteoclasts. When these processes become unbalanced, bone loss results, which is the basis of osteoporosis. The reduced bone mass found in osteoporosis leads to an increased susceptibility to bone fracture. 1 in 2 women and 1 in 3 men over the age of 60 will suffer a fracture due to osteoporosis. The increasing incidence of osteoporotic fractures has lead to ren ....Maintenance of the skeleton involves the processes of bone formation by cells known as osteoblasts and bone breakdown by cells known as osteoclasts. When these processes become unbalanced, bone loss results, which is the basis of osteoporosis. The reduced bone mass found in osteoporosis leads to an increased susceptibility to bone fracture. 1 in 2 women and 1 in 3 men over the age of 60 will suffer a fracture due to osteoporosis. The increasing incidence of osteoporotic fractures has lead to renewed efforts to understand the actions of hormones on bone. Androgens, the male sex hormones, have beneficial effects on skeletal growth and bone maintenance in both males and females by stimulating osteoblasts. It is believed that androgens act by binding to a specific protein known as the androgen receptor (AR), which is only found in androgen-responsive cells. Although it is well documented in human and animal models that androgens stimulate osteoblasts to increase the formation of bone, the way in which they act on osteoblasts remains poorly understood. The aim of this project is to investigate the effects of androgens at different stages of the developing osteoblast. This will be achieved by making transgenic mice in which the androgen receptor has been inactivated only in osteoblasts at specific stages of their development. We hypothesise that the inactivation of the androgen receptor will have dramatic effects on the development and function of osteoblasts. This project will help clarify the role androgens play in bone formation and will give fundamental insights into the basic biology of bone in both normal and disease processes. As androgens are one of the few agents that act to increase bone formation, understanding the way in which they act is important for the treatment of osteoporosis in males and females. We believe that this research is of great importance as osteoporosis becomes more prevalent in our aging population.Read moreRead less
The Role Of Cannabis In An Nrg1 Animal Model Of Genetic Vulnerability To Schizophrenia
Funder
National Health and Medical Research Council
Funding Amount
$455,323.00
Summary
The link between psychosis and cannabis use has been discussed for decades. As the majority of users do not develop schizophrenia, it seems that other risk factors are necessary to trigger psychosis. Adolescence may be a time of particular vulnerability to the effects of cannabis use. We aim to use an animal model for schizophrenia to clarify cannabis' impact on the development of schizophrenia when interacting with the risk factors genetic vulnerability and age of onset of cannabis use.
Epilepsy is an important human disease because it causes physical trauma and sudden death in addition to immense social and economic hardship. The genetic basis of a number of epilepsy syndromes has been identified but the precise mechanism whereby mutations produce seizures is unknown. Several mutations in the alpha4 neuronal nicotinic receptor (a4 nAChR) gene have been identified in Autosomal Dominant Nocturnal Frontal Lobe Epilepsy (ADNFLE). This is a rare form of inherited epilepsy character ....Epilepsy is an important human disease because it causes physical trauma and sudden death in addition to immense social and economic hardship. The genetic basis of a number of epilepsy syndromes has been identified but the precise mechanism whereby mutations produce seizures is unknown. Several mutations in the alpha4 neuronal nicotinic receptor (a4 nAChR) gene have been identified in Autosomal Dominant Nocturnal Frontal Lobe Epilepsy (ADNFLE). This is a rare form of inherited epilepsy characterized by the presence of seizures during light sleep. In vitro studies using the human mutated DNA (i.e. DNA containing the genetic defect) have suggested that this mutation results in reduced activity of the receptor. Therefore a mouse in which this gene is destroyed would be relevant in understanding the human disease. We have generated an a4 nAChR knockout (KO) mouse and plan to use the mouse to test the idea that loss of function of the a4 nAChR in vivo is associated with enhanced seizure activity. The KO mice do not have unprovoked seizures but appear to have an increased number of major motor seizures in response to pentylenetetrazole, an agent which is known to cause seizures by blocking the effects of the brain inhibitory molecule GABA. Interestingly, a4 nAChRs are known to control the release of GABA. We therefore propose that our knockout mice have seizures because they tend to under produce GABA. We will also make and analyse a mouse line with the same genetic mutation as patients with ADNFLE. The experiments are aimed at understanding the way that seizures are generated and spread in the brain in these rare forms of epilepsy. The hope is that understanding these mechanisms will help us better understand and therefore treat common forms of epilepsy.Read moreRead less
This study aims to elucidate central pathways which can be manipulated to drive the storage of excess energy away from fat and instead directing it into the production of bone mass. Having identified leptin-responsive NPY neurons as important in the control of energy partitioning, we will focus on manipulating these neurons in the hypothalamus using innovative technology to alter body composition. This research has the potential to result in novel treatments for obesity and osteoporosis.