The basis of recognition and disposal of dysfunctional proteins by clusterin. When proteins become damaged they can precipitate. A blood protein called clusterin prevents precipitation of damaged proteins. Clusterin does this by forming complexes with the damaged proteins. Clusterin is the first blood protein known to do this. We will discover which parts of clusterin are responsible for this activity. We will also discover whether cells can take up and dispose of the complexes of clusterin and ....The basis of recognition and disposal of dysfunctional proteins by clusterin. When proteins become damaged they can precipitate. A blood protein called clusterin prevents precipitation of damaged proteins. Clusterin does this by forming complexes with the damaged proteins. Clusterin is the first blood protein known to do this. We will discover which parts of clusterin are responsible for this activity. We will also discover whether cells can take up and dispose of the complexes of clusterin and damaged proteins. This work is important because some diseases (eg, Alzheimers disease) involve the toxic effects of abnormal protein precipitation. Understanding how clusterin works may help in developing better treatments for these diseases.Read moreRead less
Electrophysiological and Anatomical Characterization of the Coronary Sinus Musculature and its Relationship to the Atria. This series of experiments will characterise the normal coronary sinus musculature and its connectivity to the atria of the heart and establish their electrical relationships. The underlying characteristics of the muscular connections will also be evaluated with a view to possible future manipulations of the system. Understanding normal heart impulse propagation is paramount ....Electrophysiological and Anatomical Characterization of the Coronary Sinus Musculature and its Relationship to the Atria. This series of experiments will characterise the normal coronary sinus musculature and its connectivity to the atria of the heart and establish their electrical relationships. The underlying characteristics of the muscular connections will also be evaluated with a view to possible future manipulations of the system. Understanding normal heart impulse propagation is paramount before we can understand and develop treatments for dealing with heart problems. This information will facilitate the development of techniques to treat and prevent heart rhythm disorders that are a common cause of morbidity in the community.Read moreRead less
Molecular mechanisms regulating Ca2+ channels formed by Orai and STIM proteins. Store-operated calcium channels play a central role in the functions of all animal cells. They participate in generating the cellular responses to hormones, antigens, growth factors and other physiological stimuli. The aims of this project are to elucidate cellular mechanisms that regulate interaction between the molecular components of store-operated calcium channel, Orai and STIM. Using techniques of electrophysiol ....Molecular mechanisms regulating Ca2+ channels formed by Orai and STIM proteins. Store-operated calcium channels play a central role in the functions of all animal cells. They participate in generating the cellular responses to hormones, antigens, growth factors and other physiological stimuli. The aims of this project are to elucidate cellular mechanisms that regulate interaction between the molecular components of store-operated calcium channel, Orai and STIM. Using techniques of electrophysiology and molecular biology we expect to answer a fundamental question how STIM and Orai proteins interact to form functional store-operated calcium channels, and how the expression of STIM and Orai is regulated.Read moreRead less
Understanding the vesicle release mechanisms that regulate peripheral serotonin levels. The purpose of this project is to understand how serotonin is released into the circulation from specialised cells within the gut. As circulating serotonin controls multiple biological systems within the gut and throughout the body, the outcomes of this project will further understandings of the systems controlling essential bodily functions.
Novel regulation of TRP channels by oxygen-dependent hydroxylation. Factor inhibiting HIF-1 (FIH-1) is an oxygen-sensing asparaginyl hydroxylase. A bioinformatic search identified specific transient receptor potential (TRP) ion channels as likely substrates. The hypothesis is that TRP channels are regulated by hypoxia, mediated through a novel mechanism of oxygen-dependent hydroxylation by FIH. The aim of this project is to investigate how hydroxylation by FIH mediates the hypoxic regulation of ....Novel regulation of TRP channels by oxygen-dependent hydroxylation. Factor inhibiting HIF-1 (FIH-1) is an oxygen-sensing asparaginyl hydroxylase. A bioinformatic search identified specific transient receptor potential (TRP) ion channels as likely substrates. The hypothesis is that TRP channels are regulated by hypoxia, mediated through a novel mechanism of oxygen-dependent hydroxylation by FIH. The aim of this project is to investigate how hydroxylation by FIH mediates the hypoxic regulation of TRP channels. Preliminary data show that the first candidate, TRPV3, is activated in hypoxia, is hydroxylated by FIH, and hydroxylation mediates changes in activity. Ion channels are important for the physiological response to hypoxia, and this project aims to define a novel mechanism for this response, with relevance to mammalian physiology.Read moreRead less